ASYMMETRIC INTERFERING RNA COMPOSITIONS THAT SILENCE K- RAS AND METHODS OF USES THEREOF

FIELD OF THE INVENTION

[0001] The invention generally relates to compositions for use in silencing K-Ras gene expression. More particularly, the invention relates to novel asymmetrical interfering RNA molecules as inhibitors of K-Ras expression, and to pharmaceutical compositions and uses thereof in the treatment of cancer or a related disorder in a mammal.

BACKGROUND OF THE INVENTION

[0002] Gene silencing through RNAi (RNA-interference) by use of small or short interfering RNA (siRNA) has emerged as a therapeutic tool. However, other than the prominent delivery issue, the development of RNAi-based drugs faces challenges of limited efficacy of siRNA, non-specific effects of siRNA such as interferon-like responses and sense- strand mediated off-target gene silencing, and the prohibitive or high cost associated with siRNA synthesis. The gene silencing efficacy by siRNA is limited to about 50% or less for majority of genes in mammalian cells. The manufacture of these molecules is expensive (much more expensive than manufacturing anti sense deoxynucleotides), inefficient, and requires chemical modification. Finally, the observation that the extracellular administration of synthetic siRNAs can trigger interferon-like responses has added a significant barrier for RNAi-based research and RNAi-based therapeutic development.

[0003] The protein K-Ras is a molecular switch that under normal conditions regulates cell growth and cell division. Mutations in this protein lead to the formation of tumors through continuous cell growth. About 30% of human cancers have a mutated Ras protein that is constitutively bound to GTP due to decreased GTPase activity and insensitivity to GAP action. Ras is also an important factor in many cancers in which it is not mutated but rather functionally activated through inappropriate activity of other signal transduction elements. Mutated K-Ras proteins are found in a large proportion of all tumour cells. K-Ras protein occupies a central position of interest. The identification of oncogenically mutated K- Ras in many human cancers led to major efforts to target this constitutively activated protein as a rational and selective treatment. Despite decades of active agent research, significant challenges still remain to develop therapeutic inhibitors of K-Ras. [0004] Hypermalignant cancer cells that are highly tumorigenic and metastatic have been isolated from cancer patients with a variety of tumor types and found to have high sternness properties, termed cancer stem cells (CSCs). These stemness-high cancer cells are hypothesized to be fundamentally responsible for cancer metastasis and relapse. A number of sternness genes, such as β-catenin, Nanog, Sox2, Oct3/4 have been implicated in cancer cell sternness. However, the role of oncogenes, such as K-Ras, in cancer cell sternness is not clear.

[0005] Accordingly, there exists a need to develop novel compositions and methods for selectively silencing K-Ras gene express or K-Ras activity in a subject diagnosed with cancer, with better efficacy and potency, rapid onset of action, better durability, and fewer adverse side effects.

SUMMARY OF THE INVENTION

[0006] To elucidate the role of K-Ras in the maintenance of cancer cell sternness, the present inventors employed asymmetric silencing RNA technology (aiRNA) which is able to silence target genes with high potency and precision. Moreover, aiRNA technology can be readily applied to CSCs. The present inventors made a surprising discovery that CSCs are not only addicted to activating mutations of K-Ras, or activation of the downstream regulators of the Ras pathway, but also that CSCs with amplified mutant K-Ras become highly sensitive to K-Ras silencing. Furthermore, the present inventors made a surprising discovery that the DNA copy numbers of the mutant K-Ras directly predicts sensitivity of cancer stem cells to K-Ras silencing, which suggests that amplified mutated K-Ras is required to the maintenance of the malignancy and cancer cell sternness, which may have significant implication for understanding the connection between oncogene and cancer cell sternness and for developing cancer stem cell inhibitors.

[0007] The present invention provides compositions and methods that use a class of small duplex RNA that can induce potent gene silencing in mammalian cells, which is termed herein asymmetrical interfering RNAs (aiRNA). aiRNA is described, for example, in PCT Publication No. WO 2009/029688, the contents of which are hereby incorporated by reference in their entirety. This class of RNAi-inducers is identified by the length asymmetry of the two RNA strands. This structural design is not only functionally potent in effecting gene silencing, but offers several advantages over the current state-of-art siRNAs. Among the advantages, aiRNA can have RNA duplex structure of much shorter length than the other siRNA, which should reduce the cost of synthesis and abrogate/reduce the length-dependent triggering of nonspecific interferon-like responses. In addition, the asymmetry of the aiRNA structure abrogates and/or otherwise reduces the sense-strand mediated off-target effects. Furthermore, aiRNA is more efficacious, potent, rapid-onset, and durable than siRNA in inducing gene silencing. AiRNA can be used in all areas that other siRNA or shRNA are being applied or contemplated to be used, including biology research, R&D research in biotechnology and pharmaceutical industry, and RNAi-based therapies.

[0008] The duplex RNA molecule comprises a first strand with a length from 18-23 nucleotides and a second strand with a length from 12-17 nucleotides, wherein the second strand is substantially complementary to the first strand, and forms a double-stranded region with the first strand, wherein the first strand has a 3 '-overhang from 1-9 nucleotides, and a 5'-overhang from 0-8 nucleotides, wherein said duplex RNA molecule is capable of effecting selective K-Ras gene silencing in a eukaryotic cell. In some embodiments, the first strand comprises a sequence being substantially complementary to a target K-Ras mRNA sequence. In a further embodiment, the first strand comprises a sequence being at least 70 percent complementary to a target K-Ras mRNA sequence. In another embodiment, the eukaryotic cell is a mammalian cell or an avian cell.

[0009] In some embodiments, the target K-Ras mRNA sequence is a human K-Ras target sequence. In some embodiments, the target K-Ras mRNA sequence is a human K-Ras target sequence selected from at least a portion of the sequence shown in GenBank Accession No. NM_004985 shown below as SEQ ID NO: 1 :

1 tcctaggcgg cggccgcggc ggcggaggca gcagcggcgg cggcagtggc ggcggcgaag 61 gtggcggcgg ctcggccagt actcccggcc cccgccattt cggactggga gcgagcgcgg 121 cgcaggcact gaaggcggcg gcggggccag aggctcagcg gctcccaggt gcgggagaga 181 ggcctgctga aaatgactga atataaactt gtggtagttg gagctggtgg cgtaggcaag 241 agtgccttga cgatacagct aattcagaat cattttgtgg acgaatatga tccaacaata 301 gaggattcct acaggaagca agtagtaatt gatggagaaa cctgtctctt ggatattctc 361 gacacagcag gtcaagagga gtacagtgca atgagggacc agtacatgag gactggggag 421 ggctttcttt gtgtatttgc cataaataat actaaatcat ttgaagatat tcaccattat 481 agagaacaaa ttaaaagagt taaggactct gaagatgtac ctatggtcct agtaggaaat 541 aaatgtgatt tgccttctag aacagtagac acaaaacagg ctcaggactt agcaagaagt 601 tatggaattc cttttattga aacatcagca aagacaagac agggtgttga tgatgccttc 661 tatacattag ttcgagaaat tcgaaaacat aaagaaaaga tgagcaaaga tggtaaaaag 721 aagaaaaaga agtcaaagac aaagtgtgta attatgtaaa tacaatttgt acttttttct 781 taaggcatac tagtacaagt ggtaattttt gtacattaca ctaaattatt agcatttgtt 841 ttagcattac ctaatttttt tcctgctcca tgcagactgt tagcttttac cttaaatgct 901 tattttaaaa tgacagtgga agtttttttt tcctctaagt gccagtattc ccagagtttt 961 ggtttttgaa ctagcaatgc ctgtgaaaaa gaaactgaat acctaagatt tctgtcttgg

1021 ggtttttggt gcatgcagtt gattacttct tatttttctt accaattgtg aatgttggtg

1081 tgaaacaaat taatgaagct tttgaatcat ccctattctg tgttttatct agtcacataa

1141 atggattaat tactaatttc agttgagacc ttctaattgg tttttactga aacattgagg

1201 gaacacaaat ttatgggctt cctgatgatg attcttctag gcatcatgtc ctatagtttg

1261 tcatccctga tgaatgtaaa gttacactgt tcacaaaggt tttgtctcct ttccactgct

1321 attagtcatg gtcactctcc ccaaaatatt atattttttc tataaaaaga aaaaaatgga

1381 aaaaaattac aaggcaatgg aaactattat aaggccattt ccttttcaca ttagataaat

1441 tactataaag actcctaata gcttttcctg ttaaggcaga cccagtatga aatggggatt

1501 attatagcaa ccattttggg gctatattta catgctacta aatttttata ataattgaaa

1561 agattttaac aagtataaaa aattctcata ggaattaaat gtagtctccc tgtgtcagac

1621 tgctctttca tagtataact ttaaatcttt tcttcaactt gagtctttga agatagtttt

1681 aattctgctt gtgacattaa aagattattt gggccagtta tagcttatta ggtgttgaag

1741 agaccaaggt tgcaaggcca ggccctgtgt gaacctttga gctttcatag agagtttcac

1801 agcatggact gtgtccccac ggtcatccag tgttgtcatg cattggttag tcaaaatggg

1861 gagggactag ggcagtttgg atagctcaac aagatacaat ctcactctgt ggtggtcctg

1921 ctgacaaatc aagagcattg cttttgtttc ttaagaaaac aaactctttt ttaaaaatta

1981 cttttaaata ttaactcaaa agttgagatt ttggggtggt ggtgtgccaa gacattaatt

2041 ttttttttaa acaatgaagt gaaaaagttt tacaatctct aggtttggct agttctctta

2101 acactggtta aattaacatt gcataaacac ttttcaagtc tgatccatat ttaataatgc

2161 tttaaaataa aaataaaaac aatccttttg ataaatttaa aatgttactt attttaaaat

2221 aaatgaagtg agatggcatg gtgaggtgaa agtatcactg gactaggaag aaggtgactt

2281 aggttctaga taggtgtctt ttaggactct gattttgagg acatcactta ctatccattt

2341 cttcatgtta aaagaagtca tctcaaactc ttagtttttt ttttttacaa ctatgtaatt

2401 tatattccat ttacataagg atacacttat ttgtcaagct cagcacaatc tgtaaatttt

2461 taacctatgt tacaccatct tcagtgccag tcttgggcaa aattgtgcaa gaggtgaagt

2521 ttatatttga atatccattc tcgttttagg actcttcttc catattagtg tcatcttgcc

2581 tccctacctt ccacatgccc catgacttga tgcagtttta atacttgtaa ttcccctaac

2641 cataagattt actgctgctg tggatatctc catgaagttt tcccactgag tcacatcaga

2701 aatgccctac atcttatttc ctcagggctc aagagaatct gacagatacc ataaagggat

2761 ttgacctaat cactaatttt caggtggtgg ctgatgcttt gaacatctct ttgctgccca

2821 atccattagc gacagtagga tttttcaaac ctggtatgaa tagacagaac cctatccagt

2881 ggaaggagaa tttaataaag atagtgctga aagaattcct taggtaatct ataactagga

2941 ctactcctgg taacagtaat acattccatt gttttagtaa ccagaaatct tcatgcaatg

3001 aaaaatactt taattcatga agcttacttt ttttttttgg tgtcagagtc tcgctcttgt

3061 cacccaggct ggaatgcagt ggcgccatct cagctcactg caacctccat ctcccaggtt

3121 caagcgattc tcgtgcctcg gcctcctgag tagctgggat tacaggcgtg tgccactaca

3181 ctcaactaat ttttgtattt ttaggagaga cggggtttca ccctgttggc caggctggtc

3241 tcgaactcct gacctcaagt gattcaccca ccttggcctc ataaacctgt tttgcagaac

3301 tcatttattc agcaaatatt tattgagtgc ctaccagatg ccagtcaccg cacaaggcac

3361 tgggtatatg gtatccccaa acaagagaca taatcccggt ccttaggtag tgctagtgtg 3421 gtctgtaata tcttactaag gcctttggta tacgacccag agataacacg atgcgtattt

3481 tagttttgca aagaaggggt ttggtctctg tgccagctct ataattgttt tgctacgatt

3541 ccactgaaac tcttcgatca agctacttta tgtaaatcac ttcattgttt taaaggaata

3601 aacttgatta tattgttttt ttatttggca taactgtgat tcttttagga caattactgt

3661 acacattaag gtgtatgtca gatattcata ttgacccaaa tgtgtaatat tccagttttc

3721 tctgcataag taattaaaat atacttaaaa attaatagtt ttatctgggt acaaataaac

3781 aggtgcctga actagttcac agacaaggaa acttctatgt aaaaatcact atgatttctg

3841 aattgctatg tgaaactaca gatctttgga acactgttta ggtagggtgt taagacttac

3901 acagtacctc gtttctacac agagaaagaa atggccatac ttcaggaact gcagtgctta

3961 tgaggggata tttaggcctc ttgaattttt gatgtagatg ggcatttttt taaggtagtg

4021 gttaattacc tttatgtgaa ctttgaatgg tttaacaaaa gatttgtttt tgtagagatt

4081 ttaaaggggg agaattctag aaataaatgt tacctaatta ttacagcctt aaagacaaaa

4141 atccttgttg aagttttttt aaaaaaagct aaattacata gacttaggca ttaacatgtt

4201 tgtggaagaa tatagcagac gtatattgta tcatttgagt gaatgttccc aagtaggcat

4261 tctaggctct atttaactga gtcacactgc ataggaattt agaacctaac ttttataggt

4321 tatcaaaact gttgtcacca ttgcacaatt ttgtcctaat atatacatag aaactttgtg

4381 gggcatgtta agttacagtt tgcacaagtt catctcattt gtattccatt gatttttttt

4441 ttcttctaaa cattttttct tcaaacagta tataactttt tttaggggat ttttttttag

4501 acagcaaaaa ctatctgaag atttccattt gtcaaaaagt aatgatttct tgataattgt

4561 gtagtaatgt tttttagaac ccagcagtta ccttaaagct gaatttatat ttagtaactt

4621 ctgtgttaat actggatagc atgaattctg cattgagaaa ctgaatagct gtcataaaat

4681 gaaactttct ttctaaagaa agatactcac atgagttctt gaagaatagt cataactaga

4741 ttaagatctg tgttttagtt taatagtttg aagtgcctgt ttgggataat gataggtaat

4801 ttagatgaat ttaggggaaa aaaaagttat ctgcagatat gttgagggcc catctctccc

4861 cccacacccc cacagagcta actgggttac agtgttttat ccgaaagttt ccaattccac

4921 tgtcttgtgt tttcatgttg aaaatacttt tgcatttttc ctttgagtgc caatttctta

4981 ctagtactat ttcttaatgt aacatgttta cctggaatgt attttaacta tttttgtata

5041 gtgtaaactg aaacatgcac attttgtaca ttgtgctttc ttttgtggga catatgcagt

5101 gtgatccagt tgttttccat catttggttg cgctgaccta ggaatgttgg tcatatcaaa

5161 cattaaaaat gaccactctt ttaattgaaa ttaactttta aatgtttata ggagtatgtg

5221 ctgtgaagtg atctaaaatt tgtaatattt ttgtcatgaa ctgtactact cctaattatt

5281 gtaatgtaat aaaaatagtt acagtgacta tgagtgtgta tttattcatg aaatttgaac

5341 tgtttgcccc gaaatggata tggaatactt tataagccat agacactata gtataccagt

5401 gaatctttta tgcagcttgt tagaagtatc ctttatttct aaaaggtgct gtggatatta

5461 tgtaaaggcg tgtttgctta aacttaaaac catatttaga agtagatgca aaacaaatct

5521 gcctttatga caaaaaaata ggataacatt atttatttat ttccttttat caaagaaggt

5581 aattgataca caacaggtga cttggtttta ggcccaaagg tagcagcagc aacattaata

5641 atggaaataa ttgaatagtt agttatgtat gttaatgcca gtcaccagca ggctatttca

5701 aggtcagaag taatgactcc atacatatta tttatttcta taactacatt taaatcatta

5761 ccagg (SEQ ID NO: 1) [0010] In some embodiments, the target K-Ras mRNA sequence is a target sequence shown in Table 1 below.

Table 1. Target K-Ras Sequences

Target Position in

K-Ras Target Targeted by aiRNA ID SEQ ID NM_004985

Sequence NO:

NO: Sequence

43 304 GAAGCAAGTAGTAATTGAT 42

44 1206 GCTTCCTGATGATGATTCT 43

45 3237 CCTGACCTCAAGTGATTCA 44

46 2567 GCCTCCCTACCTTCCACAT W45

47 1403 GCCATTTCCTTTTCACATT W46

48 4207 GACGTATATTGTATCATTT W47

49 1402 GGCCATTTCCTTTTCACAT W48

50 4075 GGGGGAGAATTCTAGAAAT W49

51 4234 GTTCCCAAGTAGGCATTCT 50

52 268 GGACGAATATGATCCAACA 51

53 304 GAAGCAAGTAGTAATTGAT 52

54 1206 GCTTCCTGATGATGATTCT 53

55 5247 GAACTGTACTACTCCTAAT 54

56 3237 CCTGACCTCAAGTGATTCA 55

57 3386 GTCCTTAGGTAGTGCTAGT 56

58 1601 GTGTCAGACTGCTCTTTCA 57

59 1607 GACTGCTCTTTCATAGTAT 58

60 1255 CCTGATGAATGTAAAGTTA 59

61 2124 CAAGTCTGATCCATATTTA 60

62 688 GATGAGCAAAGATGGTAAA 61

63 2497 CAAGAGGTGAAGTTTATAT 62

64 3870 GGTAGGGTGTTAAGACTTA 63

65 1226 CTAGGCATCATGTCCTATA 64

66 4226 GAGTGAATGTTCCCAAGTA 65

67 517 CCTAGTAGGAAATAAATGT 66

68 3774 GCCTGAACTAGTTCACAGA 67

69 2970 CCAGAAATCTTCATGCAAT 68

70 2646 GCTGTGGATATCTCCATGA 69

71 303 GGAAGCAAGTAGTAATTGA 70

72 4203 CAGACGTATATTGTATCAT 71

73 233 GCCTTGACGATACAGCTAA 72

74 2259 GAAGGTGACTTAGGTTCTA 73

75 2076 GGCTAGTTCTCTTAACACT 74

76 3660 GTGTATGTCAGATATTCAT 75

77 1760 GAACCTTTGAGCTTTCATA 76

78 3789 CAGACAAGGAAACTTCTAT 77

79 3541 CTTCGATCAAGCTACTTTA 78

80 4954 GAGTGCCAATTTCTTACTA 79

81 1909 GCTGACAAATCAAGAGCAT 80

82 2346 GTCATCTCAAACTCTTAGT 81

83 638 GATGATGCCTTCTATACAT 82

84 2840 CTGGTATGAATAGACAGAA 83

85 2673 CACTGAGTCACATCAGAAA 84

86 4320 GTTGTCACCATTGCACAAT 85

87 2422 GTCAAGCTCAGCACAATCT 86

88 1484 GGGATTATTATAGCAACCA 87 Target Position in

K-Ras Target Targeted by aiRNA ID SEQ ID NM_004985

Sequence NO:

NO: Sequence

89 2252 CTAGGAAGAAGGTGACTTA 88

90 493 GGACTCTGAAGATGTACCT 89

91 3135 CTGAGTAGCTGGGATTACA 90

92 4921 CATGAGTTCTTGAAGAATA 91

93 266 GTGGACGAATATGATCCAA 92

94 2647 CTGTGGATATCTCCATGAA 93

95 3791 GACAAGGAAACTTCTATGT 94

96 4197 GAATATAGCAGACGTATAT 95

97 3544 CGATCAAGCTACTTTATGT 96

98 2839 CCTGGTATGAATAGACAGA 97

99 2943 CAGTAATACATTCCATTGT 98

100 1758 GTGAACCTTTGAGCTTTCA 99

101 175 GCTGAAAATGACTGAATAT 101

102 176 CTGAAAATGACTGAATATA 102

103 178 GAAAATGACTGAATATAAA 103

104 240 CGATACAGCTAATTCAGAA 104

105 245 CAGCTAATTCAGAATCATT 105

106 247 GCTAATTCAGAATCATTTT 106

107 256 GAATCATTTTGTGGACGAA 107

108 271 CGAATATGATCCAACAATA 108

109 278 GATCCAACAATAGAGGATT 109

110 282 CAACAATAGAGGATTCCTA 110

111 292 GGATTCCTACAGGAAGCAA 111

112 297 CCTACAGGAAGCAAGTAGT 112

113 298 CTACAGGAAGCAAGTAGTA 113

114 301 CAGGAAGCAAGTAGTAATT 114

115 307 GCAAGTAGTAATTGATGGA 115

116 311 GTAGTAATTGATGGAGAAA 116

117 320 GATGGAGAAACCTGTCTCT 117

118 324 GAGAAACCTGTCTCTTGGA 118

119 326 GAAACCTGTCTCTTGGATA 119

120 333 GTCTCTTGGATATTCTCGA 120

121 335 CTCTTGGATATTCTCGACA 121

122 337 CTTGGATATTCTCGACACA 122

123 340 GGATATTCTCGACACAGCA 123

124 347 CTCGACACAGCAGGTCAAG 124

125 356 GCAGGTCAAGAGGAGTACA 125

126 362 CAAGAGGAGTACAGTGCAA 126

127 365 GAGGAGTACAGTGCAATGA 127

128 377 CAATGAGGGACCAGTACA 128

129 385 GGACCAGTACATGAGGACT 129

130 405 GGGAGGGCTTTCTTTGTGT 130

131 407 GAGGGCTTTCTTTGTGTAT 131

132 409 GGGCTTTCTTTGTGTATTT 132

133 416 CTTTGTGTATTTGCCATAA 133

134 422 GTATTTGCCATAAATAAT 134 Target Position in

K-Ras Target Targeted by aiRNA ID SEQ ID NM_004985

Sequence NO:

NO: Sequence

135 441 CTAAATCATTTGAAGATAT 135

136 452 GAAGATATTCACCATTATA 136

137 463 CCATTATAGAGAACAAATT 137

138 464 CATTATAGAGAACAAATTA 138

139 471 GAGAACAAATTAAAAGAGT 139

140 473 GAACAAATTAAAAGAGTTA 140

141 486 GAGTTAAGGACTCTGAAGA 141

142 488 GTTAAGGACTCTGAAGATG 142

143 493 GGACTCTGAAGATGTACCT 143

144 494 GACTCTGAAGATGTACCTA 144

145 498 CTGAAGATGTACCTATGGT 145

146 509 CCTATGGTCCTAGTAGGAA 146

147 510 CTATGGTCCTAGTAGGAAA 147

148 515 GTCCTAGTAGGAAATAAAT 148

149 521 GTAGGAAATAAATGTGATT 149

150 542 CCTTCTAGAACAGTAGACA 150

151 546 CTAGAACAGTAGACACAAA 151

152 549 GAACAGTAGACACAAAACA 152

153 561 CAAAACAGGCTCAGGACTT 153

154 566 CAGGCTCAGGACTTAGCAA 154

155 568 GGCTCAGGACTTAGCAAGA 155

156 572 CAGGACTTAGCAAGAAGTT 156

157 577 CTTAGCAAGAAGTTATGGA 157

158 581 GCAAGAAGTTATGGAATTC 158

159 585 GAAGTTATGGAATTCCTTT 159

160 588 GTTATGGAATTCCTTTTAT 160

161 593 GGAATTCCTTTTATTGAAA 161

162 608 GAAACATCAGCAAAGACAA 162

163 612 CATCAGCAAAGACAAGACA 163

164 618 GCAAAGACAAGACAGGGTG 164

165 619 CAAAGACAAGACAGGGTGT 165

166 622 GACAAGACAGGGTGTTGAT 166

167 624 CAAGACAGGGTGTTGATGA 167

168 629 CAGGGTGTTGATGATGCCT 168

169 632 GGTGTTGATGATGCCTTCT 169

170 633 GTGTTGATGATGCCTTCTA 170

171 635 GTTGATGATGCCTTCTATA 171

172 639 ATGATGCCTTCTATACATT 172

173 641 GATGCCTTCTATACATTAG 173

174 644 GCCTTCTATACATTAGTTC 174

175 646 CTTCTATACATTAGTTCGA 175

176 649 CTATACATTAGTTCGAGAA 176

177 662 CGAGAAATTCGAAAACATA 177

178 663 GAGAAATTCGAAAACATAA 178

179 671 CGAAAACATAAAGAAAAGA 179

180 672 GAAAACATAAAGAAAAGAT 180 Target Position in

K-Ras Target Targeted by aiRNA ID SEQ ID NM_004985

Sequence NO:

NO: Sequence

181 677 CATAAAGAAAAGATGAGCA 181

182 693 GCAAAGATGGTAAAAAGAA 182

183 694 CAAAGATGGTAAAAAGAAG 183

184 698 GATGGTAAAAAGAAGAAAA 184

185 701 GGTAAAAAGAAGAAAAAGA 185

186 702 GTAAAAAGAAGAAAAAGAA 186

187 709 GAAGAAAAAGAAGTCAAAG 187

188 712 GAAAAAGAAGTCAAAGACA 188

189 718 GAAGTCAAAGACAAAGTGT 189

190 721 GTCAAAGACAAAGTGTGTA 190

191 723 CAAAGACAAAGTGTGTAAT 191

192 727 GACAAAGTGTGTAATTATG 192

193 729 CAAAGTGTGTAATTATGTA 193

194 752 CAATTTGTACTTTTTTCTT 194

195 758 GTACTTTTTTCTTAAGGCA 195

196 761 CTTTTTTCTTAAGGCATAC 196

197 768 CTTAAGGCATACTAGTACA 197

198 775 CATACTAGTACAAGTGGTA 198

199 779 CTAGTACAAGTGGTAATTT 199

200 782 GTACAAGTGGTAATTTTTG 200

201 788 GTGGTAATTTTTGTACATT 201

202 791 GTAATTTTTGTACATTACA 202

203 800 GUACAUUACACUAAAUUAU 203

204 808 CATTACACTAAATTATTAG 204

205 810 CTAAATTATTAGCATTTGT 205

206 821 GCATTTGTTTTAGCATTAC 206

207 827 GTTTTAGCATTACCTAATT 207

208 851 CCTGCTCCATGCAGACTGT 208

209 852 CTGCTCCATGCAGACTGTT 209

210 854 GCTCCATGCAGACTGTTAG 210

211 857 CCATGCAGACTGTTAGCTT 211

212 862 GACTGTTAGCTTTTACCTTA 212

213 868 GUUAGCUUUUACCUUAAAU 213

214 872 GCUUUUACCUUAAAUGCUU 214

215 873 CUUUUACCUUAAAUGCUUA 215

216 911 GUUUUUUUUUCCUCUAAGU 216

217 931 CCAGUAUUCCCAGAGUUUU 217

218 941 CAGAGUUUUGGUUUUUGAA 218

219 943 GAGUUUUGGUUUUUGAACU 219

220 960 CUAGCAAUGCCUGUGAAAA 220

221 970 CUGUGAAAAAGAAACUGAA 221

222 972 GUGAAAAAGAAACUGAAUA 222

223 984 CUGAAUACCUAAGAUUUCU 223

224 986 GAAUACCUAAGAUUUCUGU 224

225 1025 CAGUUGAUUACUUCUUAUU 225

226 1027 GUUGAUUACUUCUUAUUUU 226 Target Position in

K-Ras Target Targeted by aiRNA ID SEQ ID NM_004985

Sequence NO:

NO: Sequence

227 1030 GAUUACUUCUUAUUUUUCU 227

228 1038 CUUAUUUUUCUUACCAAUU 228

229 1047 CUUACCAAUUGUGAAUGUU 229

230 1059 GAAUGUUGGUGUGAAACAA 230

231 1067 GUGUGAAACAAAUUAAUGA 231

232 1101 CCUAUUCUGUGUUUUAUCU 232

233 1102 CUAUUCUGUGUUUUAUCUA 233

234 1125 CAUAAAUGGAUUAAUUACU 234

235 1159 CUUCUAAUUGGUUUUUACU 235

236 1162 CUAAUUGGUUUUUACUGAA 236

237 1169 GUUUUUACUGAAACAUUGA 237

238 1230 GCAUCAUGUCCUAUAGUUU 238

239 1278 GUUCACAAAGGUUUUGUCU 239

240 1403 GCCAUUUCCUUUUCACAUU 240

241 1404 CCAUUUCCUUUUCACAUUA 241

242 855 CTCCATGCAGACTGTTAGC 242

243 858 CATGCAGACTGTTAGCTTT 243

244 861 GCAGACTGTTAGCTTTTAC 244

245 866 CTGTTAGCTTTTACCTTAA 245

246 879 CCTTAAATGCTTATTTTAA 246

247 901 GACAGTGGAAGTTTTTTTT 247

248 902 ACAGTGGAAGTTTTTTTTT 248

249 921 CCTCTAAGTGCCAGTATTC 249

250 924 CTAAGTGCCAGTATTCCCA 250

251 928 GTGCCAGTATTCCCAGAGT 251

252 930 GCCAGTATTCCCAGAGTTT 252

253 931 CCAGTATTCCCAGAGTTTT 253

254 932 CAGTATTCCCAGAGTTTTG 254

255 934 GTATTCCCAGAGTTTTGGT 255

256 939 CCCAGAGTTTTGGTTTTTG 256

257 940 CCAGAGTTTTGGTTTTTGA 257

258 942 AGAGTTTTGGTTTTTGAAC 258

259 945 GTTTTGGTTTTTGAACTAG 259

260 950 GGTTTTTGAACTAGCAATG 260

261 957 GAACTAGCAATGCCTGTGA 261

262 963 GCAATGCCTGTGAAAAAGA 262

263 964 CAATGCCTGTGAAAAAGAA 263

264 968 GCCTGTGAAAAAGAAACTG 264

265 969 CCTGTGAAAAAGAAACTGA 265

266 973 TGAAAAAGAAACTGAATAC 266

267 980 GAAACTGAATACCTAAGAT 267

268 1001 CTGTCTTGGGGTTTTTGGT 268

269 1003 GTCTTGGGGTTTTTGGTGC 269

270 1005 CTTGGGGTTTTTGGTGCAT 270

271 1010 GCATGCAGTGTTTTTGGTG 271

272 1011 GTTTTTGGTGCATGCAGTT 272 Target Position in

K-Ras Target Targeted by aiRNA ID SEQ ID NM_004985

Sequence NO:

NO: Sequence

273 1410 CCTTTTCACATTAGATAAA 273

274 1411 CTTTTCACATTAGATAAAT 274

275 1474 GTATGAAATGGGGATTATT 275

276 1450 CCATTTTGGGGCTATATTT 276

277 1451 CATTTTGGGGCTATATTTA 277

278 1546 GAAAAGATTTTAACAAGTA 278

279 1559 CAAGTATAAAAAATTCTCA 279

280 1576 CATAGGAATTAAATGTAGT 280

281 1611 GCTCTTTCATAGTATAACT 281

282 1612 CTCTTTCATAGTATAACTT 282

283 1614 CTTTCATAGTATAACTTTA 283

284 1628 CTTTAAATCTTTTCTTCAA 284

285 1641 CTTCAACTTGAGTCTTTGA 285

286 1644 CAACTTGAGTCTTTGAAGA 286

287 1650 GAGTCTTTGAAGATAGTTT 287

288 1652 GTCTTTGAAGATAGTTTTA 288

289 1654 CTTTGAAGATAGTTTTAAT 289

290 1704 CAGTTATAGCTTATTAGGT 290

291 1712 GCTTATTAGGTGTTGAAGA 291

292 1770 GCTTTCATAGAGAGTTTCA 292

293 1826 CATGCATTGGTTAGTCAAA 293

294 1925 CATTGCTTTTGTTTCTTAA 294

295 1929 GCTTTTGTTTCTTAAGAAA 295

296 1930 CTTTTGTTTCTTAAGAAAA 296

297 1939 CTTAAGAAAACAAACTCTT 297

298 1944 GAAAACAAACTCTTTTTTA 298

299 2041 CAATGAAGTGAAAAAGTTT 299

300 2045 GAAGTGAAAAAGTTTTACA 300

301 2084 CTCTTAACACTGGTTAAAT 301

302 2086 CTTAACACTGGTTAAATTA 302

303 2096 GTTAAATTAACATTGCATA 303

304 2110 GCATAAACACTTTTCAAGT 304

305 2169 CAATCCTTTTGATAAATTT 305

306 2263 GTGACTTAGGTTCTAGATA 306

307 2287 CTTTTAGGACTCTGATTTT 307

308 2311 CATCACTTACTATCCATTT 308

309 2314 CACTTACTATCCATTTCTT 309

310 2316 CTTACTATCCATTTCTTCA 310

311 2320 CTATCCATTTCTTCATGTT 311

312 2324 CCATTTCTTCATGTTAAAA 312

313 2343 GAAGTCATCTCAAACTCTT 313

314 2348 CATCTCAAACTCTTAGTTT 314

315 2351 CTCAAACTCTTAGTTTTTT 315

316 2380 CTATGTAATTTATATTCCA 316

317 2403 CATAAGGATACACTTATTT 317

318 2432 GCACAATCTGTAAATTTTT 318 Target Position in

K-Ras Target Targeted by aiRNA ID

SEQ ID NM_004985

Sequence NO:

NO: Sequence

319 2454 CTATGTTACACCATCTTCA 319

[0011] In some embodiments, the RNA duplex molecule, also referred to herein as an asymmetrical interfering RNA molecule or aiRNA molecule, comprises a sense strand sequence, an antisense strand sequence or a combination of a sense strand sequence and antisense strand sequence selected from those shown in Table 2 below.

Table 2.

Antisense aiRNA Sense Strand Sense Strand Antisense Strand

Strand SEQ ID NO: Sequence SEQ ID NO: Sequence

ID NO:

W34 AAAAGAAACUGAAUA 353 AAGUAUUCAGUUUCUUUUUCA 671

35 AGCACAAUCUGUAAA 354 AAAUUUACAGAUUGUGCUGAG 672

36 CUUUCAUAGUAUAAC 355 AAAGUUAUACUAUGAAAGAGC 673

37 CUAGUGUGGUCUGUA 356 AAUUACAGACCACACUAGCAC 674

38 GUGUGGUCUGUAAUA 357 AAAUAUUACAGACCACACUAG 675

39 GACGUAUAUUGUAUC 358 AAUGAUACAAUAUACGUCUGC 676

40 CCCAAGUAGGCAUUC 359 AAAGAAUGCCUACUUGGGAAC 677

41 CGAAUAUGAUCCAAC 360 AAUGUUGGAUCAUAUUCGUCC 678

42 GCAAGUAGUAAUUGA 361 AAAUCAAUUACUACUUGCUUC 679

43 UCCUGAUGAUGAUUC 362 AAAGAAUCAUCAUCAGGAAGC 680

44 GACCUCAAGUGAUUC 363 AAUGAAUCACUUGAGGUCAGG 681

W45 UCCCUACCUUCCACA 364 AAAUGUGGAAGGUAGGGAGGC 682

W46 AUUUCCUUUUCACAU 365 AAAAUGUGAAAAGGAAAUGGC 683

W47 GUAUAUUGUAUCAUU 366 AAAAAUGAUACAAUAUACGUC 684

W48 CAUUUCCUUUUCACA 367 AAAUGUGAAAAGGAAAUGGCC 685

W49 GGAGAAUUCUAGAAA 368 AAAUUUCUAGAAUUCUCCCCC 686

50 CCCAAGUAGGCAUUC 369 AAAGAAUGCCUACUUGGGAAC 687

51 CGAAUAUGAUCCAAC 370 AAUGUUGGAUCAUAUUCGUCC 688

52 GCAAGUAGUAAUUGA 371 AAAUCAAUUACUACUUGCUUC 689

53 UCCUGAUGAUGAUUC 372 AAAGAAUCAUCAUCAGGAAGC 690

54 CUGUACUACUCCUAA 373 AAAUUAGGAGUAGUACAGUUC 691

55 GACCUCAAGUGAUUC 374 AAUGAAUCACUUGAGGUCAGG 692

56 CUUAGGUAGUGCUAG 375 AAACUAGCACUACCUAAGGAC 693

57 UCAGACUGCUCUUUC 376 AAUGAAAGAGCAGUCUGACAC 694

58 UGCUCUUUCAUAGUA 377 AAAUACUAUGAAAGAGCAGUC 695

59 GAUGAAUGUAAAGUU 378 AAUAACUUUACAUUCAUCAGG 696

60 GUCUGAUCCAUAUUU 379 AAUAAAUAUGGAUCAGACUUG 697

61 GAGCAAAGAUGGUAA 380 AAUUUACCAUCUUUGCUCAUC 698

62 GAGGUGAAGUUUAUA 381 AAAUAUAAACUUCACCUCUUG 699

63 AGGGUGUUAAGACUU 382 AAUAAGUCUUAACACCCUACC 700

64 GGCAUCAUGUCCUAU 383 AAUAUAGGACAUGAUGCCUAG 701

65 UGAAUGUUCCCAAGU 384 AAUACUUGGGAACAUUCACUC 702

66 AGUAGGAAAUAAAUG 385 AAACAUUUAUUUCCUACUAGG 703

67 UGAACUAGUUCACAG 386 AAUCUGUGAACUAGUUCAGGC 704

68 GAAAUCUUCAUGCAA 387 AAAUUGCAUGAAGAUUUCUGG 705

69 GUGGAUAUCUCCAUG 388 AAUCAUGGAGAUAUCCACAGC 706

70 AGCAAGUAGUAAUUG 389 AAUCAAUUACUACUUGCUUCC 707

71 ACGUAUAUUGUAUCA 390 AAAUGAUACAAUAUACGUCUG 708

72 UUGACGAUACAGCUA 391 AAUUAGCUGUAUCGUCAAGGC 709

73 GGUGACUUAGGUUCU 392 AAUAGAACCUAAGUCACCUUC 710

74 UAGUUCUCUUAACAC 393 AAAGUGUUAAGAGAACUAGCC 711

75 UAUGUCAGAUAUUCA 394 AAAUGAAUAUCUGACAUACAC 712

76 CCUUUGAGCUUUCAU 395 AAUAUGAAAGCUCAAAGGUUC 713

77 ACAAGGAAACUUCUA 396 AAAUAGAAGUUUCCUUGUCUG 714

78 CGAUCAAGCUACUUU 397 AAUAAAGUAGCUUGAUCGAAG 715

79 UGCCAAUUUCUUACU 398 AAUAGUAAGAAAUUGGCACUC 716 Antisense aiRNA Sense Strand Sense Strand Antisense Strand

Strand SEQ ID NO: Sequence SEQ ID NO: Sequence

ID NO:

80 GACAAAUCAAGAGCA 399 AAAUGCUCUUGAUUUGUCAGC 717

81 AUCUCAAACUCUUAG 400 AAACUAAGAGUUUGAGAUGAC 718

82 GAUGCCUUCUAUACA 401 AAAUGUAUAGAAGGCAUCAUC 719

83 GUAUGAAUAGACAGA 402 AAUUCUGUCUAUUCAUACCAG 720

84 UGAGUCACAUCAGAA 403 AAUUUCUGAUGUGACUCAGUG 721

85 GUCACCAUUGCACAA 404 AAAUUGUGCAAUGGUGACAAC 722

86 AAGCUCAGCACAAUC 405 AAAGAUUGUGCUGAGCUUGAC 723

87 AUUAUUAUAGCAACC 406 AAUGGUUGCUAUAAUAAUCCC 724

88 GGAAGAAGGUGACUU 407 AAUAAGUCACCUUCUUCCUAG 725

89 CUCUGAAGAUGUACC 408 AAAGGUACAUCUUCAGAGUCC 726

90 AGUAGCUGGGAUUAC 409 AAUGUAAUCCCAGCUACUCAG 727

91 GAGUUCUUGAAGAAU 410 AAUAUUCUUCAAGAACUCAUG 728

92 GACGAAUAUGAUCCA 411 AAUUGGAUCAUAUUCGUCCAC 729

93 UGGAUAUCUCCAUGA 412 AAUUCAUGGAGAUAUCCACAG 730

94 AAGGAAACUUCUAUG 413 AAACAUAGAAGUUUCCUUGUC 731

95 UAUAGCAGACGUAUA 414 AAAUAUACGUCUGCUAUAUUC 732

96 UCAAGCUACUUUAUG 415 AAACAUAAAGUAGCUUGAUCG 733

97 GGUAUGAAUAGACAG 416 AAUCUGUCUAUUCAUACCAGG 734

98 UAAUACAUUCCAUUG 417 AAACAAUGGAAUGUAUUACUG 735

99 AACCUUUGAGCUUUC 418 AAUGAAAGCUCAAAGGUUCAC 736

101 GAAAAUGACUGAAUA 419 AAAUAUUCAGUCAUUUUCAGC 737

102 AAAAUGACUGAAUAU 420 AAUAUAUUCAGUCAUUUUCAG 738

103 AAUGACUGAAUAUAA 421 AAUUUAUAUUCAGUCAUUUUC 739

104 UACAGCUAAUUCAGA 422 AAUUCUGAAUUAGCUGUAUCG 740

105 CUAAUUCAGAAUCAU 423 AAAAUGAUUCUGAAUUAGCUG 741

106 AAUUCAGAAUCAUUU 424 AAAAAAUGAUUCUGAAUUAGC 742

107 UCAUUUUGUGGACGA 425 AAUUCGUCCACAAAAUGAUUC 743

108 AUAUGAUCCAACAAU 426 AAUAUUGUUGGAUCAUAUUCG 744

109 CCAACAAUAGAGGAU 427 AAAAUCCUCUAUUGUUGGAUC 745

110 CAAUAGAGGAUUCCU 428 AAUAGGAAUCCUCUAUUGUUG 746

111 UUCCUACAGGAAGCA 429 AAUUGCUUCCUGUAGGAAUCC 747

112 ACAGGAAGCAAGUAG 430 AAACUACUUGCUUCCUGUAGG 748

113 CAGGAAGCAAGUAGU 431 AAUACUACUUGCUUCCUGUAG 749

114 GAAGCAAGUAGUAAU 432 AAAAUUACUACUUGCUUCCUG 750

115 AGUAGUAAUUGAUGG 433 AAUCCAUCAAUUACUACUUGC 751

116 GUAAUUGAUGGAGAA 434 AAUUUCUCCAUCAAUUACUAC 752

117 GGAGAAACCUGUCUC 435 AAAGAGACAGGUUUCUCCAUC 753

118 AAACCUGUCUCUUGG 436 AAUCCAAGAGACAGGUUUCUC 754

119 ACCUGUCUCUUGGAU 437 AAUAUCCAAGAGACAGGUUUC 755

120 UCUUGGAUAUUCUCG 438 AAUCGAGAAUAUCCAAGAGAC 756

121 UUGGAUAUUCUCGAC 439 AAUGUCGAGAAUAUCCAAGAG 757

122 GGAUAUUCUCGACAC 440 AAUGUGUCGAGAAUAUCCAAG 758

123 UAUUCUCGACACAGC 441 AAUGCUGUGUCGAGAAUAUCC 759

124 GACACAGCAGGUCAA 442 AACUUGACCUGCUGUGUCGAG 760

125 GGUCAAGAGGAGUAC 443 AAUGUACUCCUCUUGACCUGC 761

126 GAGGAGUACAGUGCA 444 AAUUGCACUGUACUCCUCUUG 762 Antisense aiRNA Sense Strand Sense Strand Antisense Strand

Strand SEQ ID NO: Sequence SEQ ID NO: Sequence

ID NO:

127 GAGUACAGUGCAAUG 445 AAUCAUUGCACUGUACUCCUC 763

128 UGAGGGACCAGUAC 446 AAUGUACUGGUCCCUCAUUG 764

129 CCAGUACAUGAGGAC 447 AAAGUCCUCAUGUACUGGUCC 765

130 AGGGCUUUCUUUGUG 448 AAACACAAAGAAAGCCCUCCC 766

131 GGCUUUCUUUGUGUA 449 AAAUACACAAAGAAAGCCCUC 767

132 CUUUCUUUGUGUAUU 450 AAAAAUACACAAAGAAAGCCC 768

133 UGUGUAUUUGCCAUA 451 AAUUAUGGCAAAUACACAAAG 769

134 UUUGCCAUAAAUAA 452 AAAUUAUUUAUGGCAAAUAC 770

135 AAUCAUUUGAAGAUA 453 AAAUAUCUUCAAAUGAUUUAG 771

136 GAUAUUCACCAUUAU 454 AAUAUAAUGGUGAAUAUCUUC 772

137 UUAUAGAGAACAAAU 455 AAAAUUUGUUCUCUAUAAUGG 773

138 UAUAGAGAACAAAUU 456 AAUAAUUUGUUCUCUAUAAUG 774

139 AACAAAUUAAAAGAG 457 AAACUCUUUUAAUUUGUUCUC 775

140 CAAAUUAAAAGAGUU 458 AAUAACUCUUUUAAUUUGUUC 776

141 UUAAGGACUCUGAAG 459 AAUCUUCAGAGUCCUUAACUC 777

142 AAGGACUCUGAAGAU 460 AACAUCUUCAGAGUCCUUAAC 778

143 CUCUGAAGAUGUACC 461 AAAGGUACAUCUUCAGAGUCC 779

144 UCUGAAGAUGUACCU 462 AAUAGGUACAUCUUCAGAGUC 780

145 AAGAUGUACCUAUGG 463 AAACCAUAGGUACAUCUUCAG 781

146 AUGGUCCUAGUAGGA 464 AAUUCCUACUAGGACCAUAGG 782

147 UGGUCCUAGUAGGAA 465 AAUUUCCUACUAGGACCAUAG 783

148 CUAGUAGGAAAUAAA 466 AAAUUUAUUUCCUACUAGGAC 784

149 GGAAAUAAAUGUGAU 467 AAAAUCACAUUUAUUUCCUAC 785

150 UCUAGAACAGUAGAC 468 AAUGUCUACUGUUCUAGAAGG 786

151 GAACAGUAGACACAA 469 AAUUUGUGUCUACUGUUCUAG 787

152 CAGUAGACACAAAAC 470 AAUGUUUUGUGUCUACUGUUC 788

153 AACAGGCUCAGGACU 471 AAAAGUCCUGAGCCUGUUUUG 789

154 GCUCAGGACUUAGCA 472 AAUUGCUAAGUCCUGAGCCUG 790

155 UCAGGACUUAGCAAG 473 AAUCUUGCUAAGUCCUGAGCC 791

156 GACUUAGCAAGAAGU 474 AAAACUUCUUGCUAAGUCCUG 792

157 AGCAAGAAGUUAUGG 475 AAUCCAUAACUUCUUGCUAAG 793

158 AGAAGUUAUGGAAUU 476 AAGAAUUCCAUAACUUCUUGC 794

159 GUUAUGGAAUUCCUU 477 AAAAAGGAAUUCCAUAACUUC 795

160 AUGGAAUUCCUUUUA 478 AAAUAAAAGGAAUUCCAUAAC 796

161 AUUCCUUUUAUUGAA 479 AAUUUCAAUAAAAGGAAUUCC 797

162 ACAUCAGCAAAGACA 480 AAUUGUCUUUGCUGAUGUUUC 798

163 CAGCAAAGACAAGAC 481 AAUGUCUUGUCUUUGCUGAUG 799

164 AAGACAAGACAGGGU 482 AACACCCUGUCUUGUCUUUGC 800

165 AGACAAGACAGGGUG 483 AAACACCCUGUCUUGUCUUUG 801

166 AAGACAGGGUGUUGA 484 AAAUCAACACCCUGUCUUGUC 802

167 GACAGGGUGUUGAUG 485 AAUCAUCAACACCCUGUCUUG 803

168 GGUGUUGAUGAUGCC 486 AAAGGCAUCAUCAACACCCUG 804

169 GUUGAUGAUGCCUUC 487 AAAGAAGGCAUCAUCAACACC 805

170 UUGAUGAUGCCUUCU 488 AAUAGAAGGCAUCAUCAACAC 806

171 GAUGAUGCCUUCUAU 489 AAUAUAGAAGGCAUCAUCAAC 807

172 AUGCCUUCUAUACAU 490 AAAAUGUAUAGAAGGCAUCAU 808 Antisense aiRNA Sense Strand Sense Strand Antisense Strand

Strand SEQ ID NO: Sequence SEQ ID NO: Sequence

ID NO:

173 GCCUUCUAUACAUUA 491 AACUAAUGUAUAGAAGGCAUC 809

174 UUCUAUACAUUAGUU 492 AAGAACUAAUGUAUAGAAGGC 810

175 CUAUACAUUAGUUCG 493 AAUCGAACUAAUGUAUAGAAG 811

176 UACAUUAGUUCGAGA 494 AAUUCUCGAACUAAUGUAUAG 812

177 GAAAUUCGAAAACAU 495 AAUAUGUUUUCGAAUUUCUCG 813

178 AAAUUCGAAAACAUA 496 AAUUAUGUUUUCGAAUUUCUC 814

179 AAACAUAAAGAAAAG 497 AAUCUUUUCUUUAUGUUUUCG 815

180 AACAUAAAGAAAAGA 498 AAAUCUUUUCUUUAUGUUUUC 816

181 AAAGAAAAGAUGAGC 499 AAUGCUCAUCUUUUCUUUAUG 817

182 AAGAUGGUAAAAAGA 500 AAUUCUUUUUACCAUCUUUGC 818

183 AGAUGGUAAAAAGAA 501 AACUUCUUUUUACCAUCUUUG 819

184 GGUAAAAAGAAGAAA 502 AAUUUUCUUCUUUUUACCAUC 820

185 AAAAAGAAGAAAAAG 503 AAUCUUUUUCUUCUUUUUACC 821

186 AAAAGAAGAAAAAGA 504 AAUUCUUUUUCUUCUUUUUAC 822

187 GAAAAAGAAGUCAAA 505 AACUUUGACUUCUUUUUCUUC 823

188 AAAGAAGUCAAAGAC 506 AAUGUCUUUGACUUCUUUUUC 824

189 GUCAAAGACAAAGUG 507 AAACACUUUGUCUUUGACUUC 825

190 AAAGACAAAGUGUGU 508 AAUACACACUUUGUCUUUGAC 826

191 AGACAAAGUGUGUAA 509 AAAUUACACACUUUGUCUUUG 827

192 AAAGUGUGUAAUUAU 510 AACAUAAUUACACACUUUGUC 828

193 AGUGUGUAAUUAUGU 511 AAUACAUAAUUACACACUUUG 829

194 UUUGUACUUUUUUCU 512 AAAAGAAAAAAGUACAAAUUG 830

195 CUUUUUUCUUAAGGC 513 AAUGCCUUAAGAAAAAAGUAC 831

196 UUUUCUUAAGGCAUA 514 AAGUAUGCCUUAAGAAAAAAG 832

197 AAGGCAUACUAGUAC 515 AAUGUACUAGUAUGCCUUAAG 833

198 ACUAGUACAAGUGGU 516 AAUACCACUUGUACUAGUAUG 834

199 GUACAAGUGGUAAUU 517 AAAAAUUACCACUUGUACUAG 835

200 CAAGUGGUAAUUUUU 518 AACAAAAAUUACCACUUGUAC 836

201 GUAAUUUUUGUACAU 519 AAAAUGUACAAAAAUUACCAC 837

202 AUUUUUGUACAUUAC 520 AAUGUAAUGUACAAAAAUUAC 838

203 CAUUACACUAAAUUA 521 AAAUAAUUUAGUGUAAUGUAC 839

204 UACACUAAAUUAUUA 522 AACUAAUAAUUUAGUGUAAUG 840

205 AAUUAUUAGCAUUUG 523 AAACAAAUGCUAAUAAUUUAG 841

206 UUUGUUUUAGCAUUA 524 AAGUAAUGCUAAAACAAAUGC 842

207 UUAGCAUUACCUAAU 525 AAAAUUAGGUAAUGCUAAAAC 843

208 GCUCCAUGCAGACUG 526 AAACAGUCUGCAUGGAGCAGG 844

209 CUCCAUGCAGACUGU 527 AAAACAGUCUGCAUGGAGCAG 845

210 CCAUGCAGACUGUUA 528 AACUAACAGUCUGCAUGGAGC 846

211 UGCAGACUGUUAGCU 529 AAAAGCUAACAGUCUGCAUGG 847

212 UGUUAGCUUUUACCUU 530 AAUAAGGUAAAAGCUAACAGUC 848

213 AGCUUUUACCUUAAA 531 AAAUUUAAGGUAAAAGCUAAC 849

214 UUUACCUUAAAUGCU 532 AAAAGCAUUUAAGGUAAAAGC 850

215 UUACCUUAAAUGCUU 533 AAUAAGCAUUUAAGGUAAAAG 851

216 UUUUUUUCCUCUAAG 534 AAACUUAGAGGAAAAAAAAAC 852

217 GUAUUCCCAGAGUUU 535 AAAAAACUCUGGGAAUACUGG 853

218 AGUUUUGGUUUUUGA 536 AAUUCAAAAACCAAAACUCUG 854 Antisense aiRNA Sense Strand Sense Strand Antisense Strand

Strand SEQ ID NO: Sequence SEQ ID NO: Sequence

ID NO:

219 UUUUGGUUUUUGAAC 537 AAAGUUCAAAAACCAAAACUC 855

220 GCAAUGCCUGUGAAA 538 AAUUUUCACAGGCAUUGCUAG 856

221 UGAAAAAGAAACUGA 539 AAUUCAGUUUCUUUUUCACAG 857

222 AAAAAGAAACUGAAU 540 AAUAUUCAGUUUCUUUUUCAC 858

223 AAUACCUAAGAUUUC 541 AAAGAAAUCUUAGGUAUUCAG 859

224 UACCUAAGAUUUCUG 542 AAACAGAAAUCUUAGGUAUUC 860

225 UUGAUUACUUCUUAU 543 AAAAUAAGAAGUAAUCAACUG 861

226 GAUUACUUCUUAUUU 544 AAAAAAUAAGAAGUAAUCAAC 862

227 UACUUCUUAUUUUUC 545 AAAGAAAAAUAAGAAGUAAUC 863

228 AUUUUUCUUACCAAU 546 AAAAUUGGUAAGAAAAAUAAG 864

229 ACCAAUUGUGAAUGU 547 AAAACAUUCACAAUUGGUAAG 865

230 UGUUGGUGUGAAACA 548 AAUUGUUUCACACCAACAUUC 866

231 UGAAACAAAUUAAUG 549 AAUCAUUAAUUUGUUUCACAC 867

232 AUUCUGUGUUUUAUC 550 AAAGAUAAAACACAGAAUAGG 868

233 UUCUGUGUUUUAUCU 551 AAUAGAUAAAACACAGAAUAG 869

234 AAAUGGAUUAAUUAC 552 AAAGUAAUUAAUCCAUUUAUG 870

235 CUAAUUGGUUUUUAC 553 AAAGUAAAAACCAAUUAGAAG 871

236 AUUGGUUUUUACUGA 554 AAUUCAGUAAAAACCAAUUAG 872

237 UUUACUGAAACAUUG 555 AAUCAAUGUUUCAGUAAAAAC 873

238 UCAUGUCCUAUAGUU 556 AAAAACUAUAGGACAUGAUGC 874

239 CACAAAGGUUUUGUC 557 AAAGACAAAACCUUUGUGAAC 875

240 AUUUCCUUUUCACAU 558 AAAAUGUGAAAAGGAAAUGGC 876

241 UUUCCUUUUCACAUU 559 AAUAAUGUGAAAAGGAAAUGG 877

242 CAUGCAGACUGUUAG 560 AAGCUAACAGUCUGCAUGGAG 878

243 GCAGACUGUUAGCUU 561 AAAAAGCUAACAGUCUGCAUG 879

244 GACUGUUAGCUUUUA 562 AAGUAAAAGCUAACAGUCUGC 880

245 UUAGCUUUUACCUUA 563 AAUUAAGGUAAAAGCUAACAG 881

246 UAAAUGCUUAUUUUA 564 AAUUAAAAUAAGCAUUUAAGG 882

247 AGUGGAAGUUUUUUU 565 AAAAAAAAAACUUCCACUGUC 883

248 GUGGAAGUUUUUUUU 566 AAAAAAAAAAACUUCCACUGU 884

249 CUAAGUGCCAGUAUU 567 AAGAAUACUGGCACUUAGAGG 885

250 AGUGCCAGUAUUCCC 568 AAUGGGAAUACUGGCACUUAG 886

251 CCAGUAUUCCCAGAG 569 AAACUCUGGGAAUACUGGCAC 887

252 AGUAUUCCCAGAGUU 570 AAAAACUCUGGGAAUACUGGC 888

253 GUAUUCCCAGAGUUU 571 AAAAAACUCUGGGAAUACUGG 889

254 UAUUCCCAGAGUUUU 572 AACAAAACUCUGGGAAUACUG 890

255 UUCCCAGAGUUUUGG 573 AAACCAAAACUCUGGGAAUAC 891

256 AGAGUUUUGGUUUUU 574 AACAAAAACCAAAACUCUGGG 892

257 GAGUUUUGGUUUUUG 575 AAUCAAAAACCAAAACUCUGG 893

258 GUUUUGGUUUUUGAA 576 AAGUUCAAAAACCAAAACUCU 894

259 UUGGUUUUUGAACUA 577 AACUAGUUCAAAAACCAAAAC 895

260 UUUUGAACUAGCAAU 578 AACAUUGCUAGUUCAAAAACC 896

261 CUAGCAAUGCCUGUG 579 AAUCACAGGCAUUGCUAGUUC 897

262 AUGCCUGUGAAAAAG 580 AAUCUUUUUCACAGGCAUUGC 898

263 UGCCUGUGAAAAAGA 581 AAUUCUUUUUCACAGGCAUUG 899

264 UGUGAAAAAGAAACU 582 AACAGUUUCUUUUUCACAGGC 900 Antisense aiRNA Sense Strand Sense Strand Antisense Strand

Strand SEQ ID NO: Sequence SEQ ID NO: Sequence

ID NO:

265 GUGAAAAAGAAACUG 583 AAUCAGUUUCUUUUUCACAGG 901

266 AAAAGAAACUGAAUA 584 AAGUAUUCAGUUUCUUUUUCA 902

267 ACUGAAUACCUAAGA 585 AAAUCUUAGGUAUUCAGUUUC 903

268 UCUUGGGGUUUUUGG 586 AAACCAAAAACCCCAAGACAG 904

269 UUGGGGUUUUUGGUG 587 AAGCACCAAAAACCCCAAGAC 905

270 GGGGUUUUUGGUGCA 588 AAAUGCACCAAAAACCCCAAG 906

271 UGCAGUGUUUUUGGU 589 AACACCAAAAACACUGCAUGC 907

272 UUUGGUGCAUGCAGU 590 AAAACUGCAUGCACCAAAAAC 908

273 UUUCACAUUAGAUAA 591 AAUUUAUCUAAUGUGAAAAGG 909

274 UUCACAUUAGAUAAA 592 AAAUUUAUCUAAUGUGAAAAG 910

275 UGAAAUGGGGAUUAU 593 AAAAUAAUCCCCAUUUCAUAC 911

276 UUUUGGGGCUAUAUU 594 AAAAAUAUAGCCCCAAAAUGG 912

277 UUUGGGGCUAUAUUU 595 AAUAAAUAUAGCCCCAAAAUG 913

278 AAGAUUUUAACAAGU 596 AAUACUUGUUAAAAUCUUUUC 914

279 GUAUAAAAAAUUCUC 597 AAUGAGAAUUUUUUAUACUUG 915

280 AGGAAUUAAAUGUAG 598 AAACUACAUUUAAUUCCUAUG 916

281 CUUUCAUAGUAUAAC 599 AAAGUUAUACUAUGAAAGAGC 917

282 UUUCAUAGUAUAACU 600 AAAAGUUAUACUAUGAAAGAG 918

283 UCAUAGUAUAACUUU 601 AAUAAAGUUAUACUAUGAAAG 919

284 UAAAUCUUUUCUUCA 602 AAUUGAAGAAAAGAUUUAAAG 920

285 CAACUUGAGUCUUUG 603 AAUCAAAGACUCAAGUUGAAG 921

286 CUUGAGUCUUUGAAG 604 AAUCUUCAAAGACUCAAGUUG 922

287 UCUUUGAAGAUAGUU 605 AAAAACUAUCUUCAAAGACUC 923

288 UUUGAAGAUAGUUUU 606 AAUAAAACUAUCUUCAAAGAC 924

289 UGAAGAUAGUUUUAA 607 AAAUUAAAACUAUCUUCAAAG 925

290 UUAUAGCUUAUUAGG 608 AAACCUAAUAAGCUAUAACUG 926

291 UAUUAGGUGUUGAAG 609 AAUCUUCAACACCUAAUAAGC 927

292 UUCAUAGAGAGUUUC 610 AAUGAAACUCUCUAUGAAAGC 928

293 GCAUUGGUUAGUCAA 611 AAUUUGACUAACCAAUGCAUG 929

294 UGCUUUUGUUUCUUA 612 AAUUAAGAAACAAAAGCAAUG 930

295 UUUGUUUCUUAAGAA 613 AAUUUCUUAAGAAACAAAAGC 931

296 UUGUUUCUUAAGAAA 614 AAUUUUCUUAAGAAACAAAAG 932

297 AAGAAAACAAACUCU 615 AAAAGAGUUUGUUUUCUUAAG 933

298 AACAAACUCUUUUUU 616 AAUAAAAAAGAGUUUGUUUUC 934

299 UGAAGUGAAAAAGUU 617 AAAAACUUUUUCACUUCAUUG 935

300 GUGAAAAAGUUUUAC 618 AAUGUAAAACUUUUUCACUUC 936

301 UUAACACUGGUUAAA 619 AAAUUUAACCAGUGUUAAGAG 937

302 AACACUGGUUAAAUU 620 AAUAAUUUAACCAGUGUUAAG 938

303 AAAUUAACAUUGCAU 621 AAUAUGCAAUGUUAAUUUAAC 939

304 UAAACACUUUUCAAG 622 AAACUUGAAAAGUGUUUAUGC 940

305 UCCUUUUGAUAAAUU 623 AAAAAUUUAUCAAAAGGAUUG 941

306 ACUUAGGUUCUAGAU 624 AAUAUCUAGAACCUAAGUCAC 942

307 UUAGGACUCUGAUUU 625 AAAAAAUCAGAGUCCUAAAAG 943

308 CACUUACUAUCCAUU 626 AAAAAUGGAUAGUAAGUGAUG 944

309 UUACUAUCCAUUUCU 627 AAAAGAAAUGGAUAGUAAGUG 945

310 ACUAUCCAUUUCUUC 628 AAUGAAGAAAUGGAUAGUAAG 946 Antisense aiRNA Sense Strand Sense Strand Antisense Strand

Strand SEQ ID NO: Sequence SEQ ID NO: Sequence

ID NO:

311 UCCAUUUCUUCAUGU 629 AAAACAUGAAGAAAUGGAUAG 947

312 UUUCUUCAUGUUAAA 630 AAUUUUAACAUGAAGAAAUGG 948

313 GUCAUCUCAAACUCU 631 AAAAGAGUUUGAGAUGACUUC 949

314 CUCAAACUCUUAGUU 632 AAAAACUAAGAGUUUGAGAUG 950

315 AAACUCUUAGUUUUU 633 AAAAAAAACUAAGAGUUUGAG 951

316 UGUAAUUUAUAUUCC 634 AAUGGAAUAUAAAUUACAUAG 952

317 AAGGAUACACUUAUU 635 AAAAAUAAGUGUAUCCUUAUG 953

318 CAAUCUGUAAAUUUU 636 AAAAAAAUUUACAGAUUGUGC 954

319 UGUUACACCAUCUUC 637 AAUGAAGAUGGUGUAACAUAG 955

[0012] In some embodiments, the RNA duplex molecule (aiRNA) comprises a sense strand sequence selected from the group consisting of SEQ ID NOs: 320-637. In some embodiments, the RNA duplex molecule (aiRNA) comprises an antisense strand sequence selected from the group consisting of SEQ ID NOs: 638-955. In some embodiments, the RNA duplex molecule (aiRNA) comprises a sense strand sequence selected from the group consisting of SEQ ID NOs: 320-637 and an antisense strand sequence selected from the group consisting of SEQ ID NOs: 638-955.

[0013] In some embodiments, the RNA duplex molecule (aiRNA) comprises a sense strand sequence that is at least, e.g., 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more identical to a sequence selected from the group consisting of SEQ ID NOs: 320-637. In some embodiments, the RNA duplex molecule (aiRNA) comprises an antisense strand sequence that is at least, e.g., 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more identical to a sequence selected from the group consisting of SEQ ID NOs: 638-955. In some embodiments, the RNA duplex molecule (aiRNA) comprises a sense strand sequence that is at least, e.g., 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more identical to a sequence selected from the group consisting of SEQ ID NOs: 320-637 and an antisense strand sequence that is at least, e.g., 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more identical to a sequence selected from the group consisting of SEQ ID NOs: 638-955.

[0014] In some embodiments, at least one nucleotide of the sequence of 5' overhang is selected from the group consisting of A, U, and dT.

[0015] In some embodiments, the GC content of the double stranded region is

20%-70%.

[0016] In some embodiments, the first strand has a length from 19-22 nucleotides. [0017] In some embodiments, the first strand has a length of 21 nucleotides. In a further embodiment, the second strand has a length of 14-16 nucleotides.

[0018] In some embodiments, the first strand has a length of 21 nucleotides, and the second strand has a length of 15 nucleotides. In a further embodiment, the first strand has a 3'-overhang of 2-4 nucleotides. In an even further embodiment, the first strand has a 3'- overhang of 3 nucleotides.

[0019] In some embodiments, the duplex RNA molecule contains at least one modified nucleotide or its analogue. In a further embodiment, the at least one modified nucleotide or its analogue is sugar-, backbone-, and/or base- modified ribonucleotide. In an even further embodiment, the backbone-modified ribonucleotide has a modification in a phosphodiester linkage with another ribonucleotide. In some embodiments, the phosphodiester linkage is modified to include at least one of a nitrogen or a sulphur heteroatom. In another embodiment, the nucleotide analogue is a backbone-modified ribonucleotide containing a phosphothioate group.

[0020] In some embodiments, the at least one modified nucleotide or its analogue is an unusual base or a modified base. In another embodiment, the at least one modified nucleotide or its analogue comprises inosine, or a tritylated base.

[0021] In a further embodiment, the nucleotide analogue is a sugar-modified ribonucleotide, wherein the 2'-OH group is replaced by a group selected from H, OR, R, halo, SH, SR, NH ₂ , NHR, NR ₂ , or CN, wherein each R is independently C1-C6 alkyl, alkenyl or alkynyl, and halo is F, CI, Br or I.

[0022] In some embodiments, the first strand comprises at least one deoxynucleotide. In a further embodiment, the at least one deoxynucleotides are in one or more regions selected from the group consisting of 3 '-overhang, 5 '-overhang, and double- stranded region. In another embodiment, the second strand comprises at least one deoxynucleotide.

[0023] The present invention also provides a method of modulating K-Ras expression, e.g., silencing K-Ras expression or otherwise reducing K-Ras expression, in a cell or an organism comprising the steps of contacting said cell or organism with an asymmetrical duplex RNA molecule of the disclosure under conditions wherein selective K-Ras gene silencing can occur, and mediating a selective K-Ras gene silencing effected by the duplex RNA molecule towards K-Ras or nucleic acid having a sequence portion substantially corresponding to the double-stranded RNA. In a further embodiment, said contacting step comprises the step of introducing said duplex RNA molecule into a target cell in culture or in an organism in which the selective K-Ras silencing can occur. In an even further embodiment, the introducing step is selected from the group consisting of transfection, lipofection, electroporation, infection, injection, oral administration, inhalation, topical and regional administration. In another embodiment, the introducing step comprises using a pharmaceutically acceptable excipient, carrier, or diluent selected from the group consisting of a pharmaceutical carrier, a positive-charge carrier, a liposome, a protein carrier, a polymer, a nanoparticle, a nanoemulsion, a lipid, and a lipoid.

[0024] In some embodiments, the modulating method is used for determining the function or utility of a gene in a cell or an organism.

[0025] In some embodiments, the modulating method is used for treating or preventing a disease or an undesirable condition. In some embodiments, the disease or undesirable condition is a cancer, for example, gastric cancer.

[0026] The disclosure provides compositions and methods for targeting K-Ras in the treatment, prevention, delaying the progression of, or otherwise ameliorating a symptom of gastric cancer. In some embodiments, the method comprises administering to subject in need thereof a therapeutically effective amount of a duplex RNA molecule of the disclosure. In some embodiments, the subject is human. In some embodiments, the subject is suffering from gastric cancer. In some embodiments, the subject is diagnosed with gastric cancer. In some embodiments, the subject is predisposed to gastric cancer.

[0027] The disclosure also provides compositions and methods for targeting K-Ras to inhibit the survival and/or proliferation of cancer stem cells. In some embodiments, the method comprises administering to subject in need thereof a therapeutically effective amount of a duplex RNA molecule of the disclosure. In some embodiments, the subject is human. In some embodiments, the subject is suffering from gastric cancer. In some embodiments, the subject is diagnosed with gastric cancer. In some embodiments, the subject is predisposed to gastric cancer.

[0028] The disclosure also provides compositions and methods for targeting K-Ras in the inhibition of to inhibit the survival and/or proliferation of CSCs in the treatment, prevention, delaying the progression of, or otherwise ameliorating a symptom of gastric cancer. In some embodiments, the method comprises administering to subject in need thereof a therapeutically effective amount of a duplex RNA molecule of the disclosure. In some embodiments, the subject is human. In some embodiments, the subject is suffering from gastric cancer. In some embodiments, the subject is diagnosed with gastric cancer. In some embodiments, the subject is predisposed to gastric cancer. [0029] The disclosure also provides a method for treating cancer in a selected patient population, the method comprising the steps of: (a) measuring a level of mutant K-Ras gene amplification in a biological sample obtained from a patient candidate diagnosed of a cancer; (b) confirming that the patient candidate's mutant K-Ras gene amplification level is above a benchmark level; and (c) administering to the patient candidate a duplex RNA molecule comprising a first strand comprising a nucleotide sequence with a length from 18- 23 nucleotides, wherein the nucleotide sequence of the first strand is substantially complementary to a target K-Ras mRNA sequence, and a second strand comprising a nucleotide sequence with a length from 12-17 nucleotides, wherein the second strand is substantially complementary to the first strand, and forms a double-stranded region with the first strand, wherein the first strand has a 3 '-overhang from 1-9 nucleotides, and a 5 '-overhang from 0-8 nucleotides, and wherein said duplex RNA molecule is capable of effecting selective K-Ras gene silencing.

[0030] In some embodiments, the steps (a), (b), and (c) may be performed by one actor or several actors.

[0031] In some embodiments, a patient candidate's mutant K-Ras gene amplification level is considered to be above a benchmark level if it is at least, e.g., 2-fold greater relative to that of a control patient who would not respond favorably to the claimed treatment method according to the present invention. Likewise, a skilled physician may determine that the optimal benchmark level of the DNA copy number is, e.g., about 3-fold or 4-fold greater relative to that of a non-responsive patient, based on the data presented in the present disclosure.

[0032] The disclosure also provides a method for treating cancer in a selected patient population, the method comprising the steps of: (a) measuring an expression level of mutant K-Ras protein in a biological sample obtained from a patient candidate diagnosed of a cancer; (b) confirming that the patient candidate's mutant K-Ras protein expression level is above a benchmark level; and (c) administering to the patient candidate a duplex RNA molecule comprising a first strand comprising a nucleotide sequence with a length from 18- 23 nucleotides, wherein the nucleotide sequence of the first strand is substantially complementary to a target K-Ras mRNA sequence, and a second strand comprising a nucleotide sequence with a length from 12-17 nucleotides, wherein the second strand is substantially complementary to the first strand, and forms a double-stranded region with the first strand, wherein the first strand has a 3 '-overhang from 1-9 nucleotides, and a 5 '-overhang from 0-8 nucleotides, and wherein said duplex RNA molecule is capable of effecting selective K-Ras gene silencing.

[0033] In some embodiments, the steps (a), (b), and (c) may be performed by one actor or several actors.

[0034] In some embodiments, a patient candidate's mutant K-Ras protein expression level is considered to be above a benchmark level if it is at least, e.g., 2-fold greater relative to that of a control patient who would not respond favorably to the claimed treatment method according to the present invention. Likewise, a skilled physician may determine that the optimal benchmark level of the mutant K-Ras protein expression is, e.g., about 3-fold or 4- fold greater relative to that of a non-responsive patient, based on the data presented in the present disclosure.

[0035] The present invention further provides a kit. The kit comprises a first RNA strand with a length from 18-23 nucleotides and a second RNA strand with a length from 12- 17 nucleotides, wherein the second strand is substantially complementary to the first strand, and capable of forming a duplex RNA molecule with the first strand, wherein the duplex RNA molecule has a 3 '-overhang from 1-9 nucleotides, and a 5 '-overhang from 0-8 nucleotides, wherein said duplex RNA molecule is capable of effecting K-Ras specific gene silencing.

[0036] The present invention also provides a method of preparing the duplex RNA molecule. The method comprises the steps of synthesizing the first strand and the second strand, and combining the synthesized strands under conditions, wherein the duplex RNA molecule is formed, which is capable of effecting sequence-specific gene silencing. In some embodiments, the method further comprises a step of introducing at least one modified nucleotide or its analogue into the duplex RNA molecule during the synthesizing step, after the synthesizing and before the combining step, or after the combining step. In another embodiment, the RNA strands are chemically synthesized, or biologically synthesized.

[0037] The present invention provides an expression vector. The vector comprises a nucleic acid or nucleic acids encoding the duplex RNA molecule operably linked to at least one expression-control sequence. In some embodiments, the vector comprises a first nucleic acid encoding the first strand operably linked to a first expression-control sequence, and a second nucleic acid encoding the second strand operably linked to a second expression-control sequence. In another embodiment, the vector is a viral, eukaryotic, or bacterial expression vector. [0038] The present invention also provides a cell. In some embodiments, the cell comprises the vector. In another embodiment, the cell comprises the duplex RNA molecule. In a further embodiment, the cell is a mammalian, avian, or bacterial cell.

[0039] The modulating method can also be used for studying drug target in vitro or in vivo. The present invention provides a reagent comprising the duplex RNA molecule.

[0040] The present invention also provides a method of preparing a duplex RNA molecule of the disclosure comprising the steps of synthesizing the first strand and the second strand, and combining the synthesized strands under conditions, wherein the duplex RNA molecule is formed, which is capable of effecting K-Ras sequence-specific gene silencing. In some embodiments, the RNA strands are chemically synthesized, or biologically synthesized. In another embodiment, the first strand and the second strand are synthesized separately or simultaneously.

[0041] In some embodiments, the method further comprises a step of introducing at least one modified nucleotide or its analogue into the duplex RNA molecule during the synthesizing step, after the synthesizing and before the combining step, or after the combining step.

[0042] The present invention further provides a pharmaceutical composition. The pharmaceutical composition comprises as an active agent at least one duplex RNA molecule and one or more carriers selected from the group consisting of a pharmaceutical carrier, a positive-charge carrier, a liposome, a protein carrier, a polymer, a nanoparticle, a cholesterol, a lipid, and a lipoid.

[0043] Other features and advantages of the present invention are apparent from the additional descriptions provided herein including the different examples. The provided examples illustrate different components and methodology useful in practicing the present invention. The examples do not limit the claimed invention. Based on the present disclosure the skilled artisan can identify and employ other components and methodology useful for practicing the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0044] Figure 1(A) shows an in vitro study in which aiRNA ID NO: 21 ("aiK-Ras

#1") was used to target K-Ras Target SEQ ID NO: 22 to determine the IC ₅₀ for aiK-Ras #1.

[0045] Figure 1(B) shows an in vitro study in which aiRNA ID NO: 142 ("aiK-Ras

#2") was used to target K-Ras Target SEQ ID NO: 142 to determine the IC ₅₀ for aiK-Ras #2. [0046] Figure 2(A) shows detection of siRNA and aiR A loading to RISC by northern blot analysis.

[0047] Figure 2(B) shows detection of TLR3/aiRNA or siRNA binding.

[0048] Figure 2(C) shows that TLR3/RNA complexes were immunoprecipitated with anti-HA antibody.

[0049] Figure 3(A) shows colony formation assay in AGS and DLD1 transfected with aiK-Ras #1 or aiK-Ras #2.

[0050] Figure 3(B) shows western blot analysis of lysate from AGS and DLD1.

[0051] Figure 3(C) shows colony formation assay results in large cell panel.

[0052] Figure 4 shows western blot analysis of K-Ras and EGFR-RAS pathway molecules.

[0053] Figure 5(A) shows that aiK-Ras sensitivity was correlated with K-Ras amplification in K-Ras mutant large cell panel.

[0054] Figure 5(B) shows that aiK-Ras sensitivity was correlated with K-Ras amplification in K-Ras mutant large cell panel.

[0055] Figure 6(A) shows sternness gene expression in CSC culture.

[0056] Figure 6(B) shows the results of sphere formation assay in various cell lines.

[0057] Figure 6(C) shows depletion of CD44-high population in AGS and DLD1 cells with aiK-Ras #1 and aiK-Ras #2.

[0058] Figure 7(A) shows heat map of CSC-related genes in cancer cells transfected with aiK-Ras.

[0059] Figure 7(B) shows confirmation of down-regulated Notch signaling by western blot.

DETAILED DESCRIPTION OF THE INVENTION

[0060] The present invention relates to asymmetric duplex RNA molecules that are capable of effecting selective K-Ras gene silencing in a eukaryotic cell. In some embodiments, the duplex RNA molecule comprises a first strand and a second strand. The first strand is longer than the second strand. The second strand is substantially complementary to the first strand, and forms a double-stranded region with the first strand.

[0061] The protein K-Ras is a molecular switch that under normal conditions regulates cell growth and cell division. Mutations in this protein lead to the formation of tumors through continuous cell growth. About 30% of human cancers have a mutated Ras protein that is constitutively bound to GTP due to decreased GTPase activity and insensitivity to GAP action. Ras is also an important factor in many cancers in which it is not mutated but rather functionally activated through inappropriate activity of other signal transduction elements. Mutated K-Ras proteins are found in a large proportion of all tumor cells. K-Ras protein occupies a central position of interest. The identification of oncogenically mutated K- Ras in many human cancers led to major efforts to target this constitutively activated protein as a rational and selective treatment. Despite decades of active agent research, significant challenges still remain to develop therapeutic inhibitors of K-Ras.

[0062] The compositions and methods provided herein are useful in elucidating the function of K-Ras in the cancer development and maintenance. The compositions and methods use asymmetric interfering RNAs (aiRNAs) that are able to silence target genes with high potency leading to long-lasting knockdown, and reducing off-target effects, and investigated the dependency of K-Ras on cell survival in several types of human cancer cell lines. Much to our surprise, we found K-Ras plays a more significant role for gastric cancer maintenance compared to other types of cancer. aiRNA-induced silencing of K-Ras was found to inhibit the cell proliferation of gastric cancer cells and the ability of gastric cancer cells to form colonies compared to other cancer types. Accumulating evidence has revealed that cancer stem cells (CSCs) are highly associated with prognosis, metastasis, and recurrence. To investigate the effect of K-Ras on CSCs, we tested the K-Ras gene silencing effects on an in vitro CSC culturing system. As a result, K-Ras inhibition decreased the colonies derived from gastric CSCs and altered the gene expression patterns of several genes involved in "sternness" compared to other cancer types. The results of these studies suggest that gastric cancer and gastric CSCs are affected by the K-Ras oncogene and that Kras aiRNAs are promising therapeutic candidates for the treatment of gastric cancer. Accordingly, the disclosure provides compositions and methods for targeting K-Ras in the treatment, prevention, delaying the progression of, or otherwise ameliorating a symptom of gastric cancer. The disclosure also provides compositions and methods for targeting K-Ras to inhibit the survival and/or proliferation of CSCs, as well as compositions and methods for targeting K-Ras in the inhibition of to inhibit the survival and/or proliferation of CSCs in the treatment, prevention, delaying the progression of, or otherwise ameliorating a symptom of gastric cancer. In some embodiments, the method comprises administering to subject in need thereof a therapeutically effective amount of a duplex RNA molecule of the disclosure. In some embodiments, the subject is human. In some embodiments, the subject is suffering from gastric cancer. In some embodiments, the subject is diagnosed with gastric cancer. In some embodiments, the subject is predisposed to gastric cancer. [0063] In some embodiments, the duplex RNA molecule used in the compositions and methods of the disclosure has a 3'-overhang from 1-8 nucleotides and a 5'-overhang from 1 -8 nucleotides, a 3 '-overhang from 1-10 nucleotides and a blunt end, or a 5'- overhang from 1- 10 nucleotides and a blunt end. In another embodiment, the duplex RNA molecule has two 5'-overhangs from 1-8 nucleotides or two 3'-overhangs from 1- 10 nucleotides. In a further embodiment, the first strand has a 3 '-overhang from 1-8 nucleotides and a 5'-overhang from 1 -8 nucleotides. In an even further embodiment, the duplex RNA molecule is an isolated duplex RNA molecule.

[0064] In some embodiments, the first strand has a 3'-overhang from 1-10 nucleotides, and a 5'-overhang from 1-10 nucleotides or a 5'-blunt end. In another embodiment, the first strand has a 3 ^overhang from 1-10 nucleotides, and a 5 ^overhang from 1-10 nucleotides. In an alternative embodiment, the first strand has a 3 '-overhang from 1-10 nucleotides, and a 5 '-blunt end.

[0065] In some embodiments, the first strand has a length from 5-100 nucleotides, from 12-30 nucleotides, from 15-28 nucleotides, from 18-27 nucleotides, from 19-23 nucleotides, from 20-22 nucleotides, or 21 nucleotides.

[0066] In another embodiment, the second strand has a length from 3-30 nucleotides, from 12-26 nucleotides, from 13-20 nucleotides, from 14-23 nucleotides, 14 or 15 nucleotides.

[0067] In some embodiments, the first strand has a length from 5-100 nucleotides, and the second strand has a length from 3-30 nucleotides; or the first strand has a length from 10-30 nucleotides, and the second strand has a length from 3-29 nucleotides; or the first strand has a length from 12-30 nucleotides and the second strand has a length from 10-26 nucleotides; or the first strand has a length from 15-28 nucleotides and the second strand has a length from 12-26 nucleotides; or the first strand has a length from 19-27 nucleotides and the second strand has a length from 14-23 nucleotides; or the first strand has a length from 20-22 nucleotides and the second strand has a length from 14-15 nucleotides. In a further embodiment, the first strand has a length of 21 nucleotides and the second strand has a length of 13-20 nucleotides, 14-19 nucleotides, 14-17 nucleotides, 14 or 15 nucleotides.

[0068] In some embodiments, the first strand is at least 1, 2, 3, 4, 5, 6, 7, 8, 9, or 10 nucleotides longer than the second strand.

[0069] In some embodiments, the duplex RNA molecule further comprises 1 -10 unmatched or mismatched nucleotides. In a further embodiment, the unmatched or mismatched nucleotides are at or near the 3' recessed end. In an alternative embodiment, the unmatched or mismatched nucleotides are at or near the 5' recessed end. In an alternative embodiment, the unmatched or mismatched nucleotides are at the double- stranded region. In another embodiment, the unmatched or mismatched nucleotide sequence has a length from 1-5 nucleotides. In an even further embodiment, the unmatched or mismatched nucleotides form a loop structure.

[0070] In some embodiments, the first strand or the second strand contains at least one nick, or formed by two nucleotide fragments.

[0071] In some embodiments, the gene silencing is achieved through one or two, or all of RNA interference, modulation of translation, and DNA epigenetic modulations.

[0072] In some embodiments, the target K-Ras mRNA sequence to be silenced is a target sequence shown in Table 1.

[0073] In some embodiments, the RNA duplex molecule, also referred to herein as an asymmetrical interfering RNA molecule or aiRNA molecule, comprises a sense strand sequence, an antisense strand sequence or a combination of a sense strand sequence and antisense strand sequence selected from those shown in Table 2.

[0074] In some embodiments, the RNA duplex molecule (aiRNA) comprises a sense strand sequence selected from the group consisting of SEQ ID NOs: 320-637. In some embodiments, the RNA duplex molecule (aiRNA) comprises an antisense strand sequence selected from the group consisting of SEQ ID NOs: 638-955. In some embodiments, the RNA duplex molecule (aiRNA) comprises a sense strand sequence selected from the group consisting of SEQ ID NOs: 320-637 and an antisense strand sequence selected from the group consisting of SEQ ID NOs: 638-955.

[0075] In some embodiments, the RNA duplex molecule (aiRNA) comprises a sense strand sequence that is at least, e.g, 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more identical to a sequence selected from the group consisting of SEQ ID NOs: 320-637. In some embodiments, the RNA duplex molecule (aiRNA) comprises an antisense strand sequence that is at least, e.g., 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more identical to a sequence selected from the group consisting of SEQ ID NOs: 638-955. In some embodiments, the RNA duplex molecule (aiRNA) comprises a sense strand sequence that is at least, e.g., 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more identical to a sequence selected from the group consisting of SEQ ID NOs: 320-637 and an antisense strand sequence that is at least, e.g., 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more identical to a sequence selected from the group consisting of SEQ ID NOs: 638-955. [0076] As used in the specification and claims, the singular form "a", "an", and "the" include plural references unless the context clearly dictate otherwise. For example, the term "a cell" includes a plurality of cells including mixtures thereof.

[0077] As used herein, a "double stranded RNA," a "duplex RNA" or a "RNA duplex" refers to an RNA of two strands and with at least one double-stranded region, and includes RNA molecules that have at least one gap, nick, bulge, and/or bubble either within a double-stranded region or between two neighboring double-stranded regions. If one strand has a gap or a single-stranded region of unmatched nucleotides between two double-stranded regions, that strand is considered as having multiple fragments. A double- stranded RNA as used here can have terminal overhangs on either end or both ends.. In some embodiments, the two strands of the duplex RNA can be linked through certain chemical linker.

[0078] As used herein, an "antisense strand" refers to an RNA strand that has substantial sequence complementarity against a target messenger RNA.

[0079] The term "isolated" or "purified" as used herein refers to a material that is substantially or essentially free from components that normally accompany it in its native state. Purity and homogeneity are typically determined using analytical chemistry techniques such as polyacrylamide gel electrophoresis or high performance liquid chromatography.

[0080] As used herein, "modulating" and its grammatical equivalents refer to either increasing or decreasing (e.g., silencing), in other words, either up-regulating or down- regulating. As used herein, "gene silencing" refers to reduction of gene expression, and may refer to a reduction of gene expression about, e.g., 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90% or 95% of the targeted gene.

[0081] As used herein, the term "subject" refers to any animal (e.g., a mammal), including, but not limited to humans, non-human primates, rodents, and the like, which is to be the recipient of a particular treatment. Under some circumstances, the terms "subject" and "patient" are used interchangeably herein in reference to a human subject.

[0082] Terms such as "treating" or "treatment" or "to treat" or "alleviating" or "to alleviate" as used herein refer to both (1) therapeutic measures that cure, slow down, lessen symptoms of, and/or halt progression of a diagnosed pathologic condition or disorder and (2) prophylactic or preventative measures that prevent or slow the development of a targeted pathologic condition or disorder. Thus those in need of treatment include those already with the disorder; those prone to have the disorder; and those in whom the disorder is to be prevented. A subject is successfully "treated" according to the methods of the present invention if the patient shows one or more of the following: a reduction in the number of or complete absence of cancer cells; a reduction in the tumor size; inhibition of or an absence of cancer cell infiltration into peripheral organs including the spread of cancer into soft tissue and bone; inhibition of or an absence of tumor metastasis; inhibition or an absence of tumor growth; relief of one or more symptoms associated with the specific cancer; reduced morbidity and mortality; and improvement in quality of life.

[0083] As used herein, the terms "inhibiting", "to inhibit" and their grammatical equivalents, when used in the context of a bioactivity, refer to a down-regulation of the bioactivity, which may reduce or eliminate the targeted function, such as the production of a protein or the phosphorylation of a molecule. When used in the context of an organism (including a cell), the terms refer to a down-regulation of a bioactivity of the organism, which may reduce or eliminate a targeted function, such as the production of a protein or the phosphorylation of a molecule. In particular embodiments, inhibition may refer to a reduction of about, e.g., 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90% or 95% of the targeted activity. When used in the context of a disorder or disease, the terms refer to success at preventing the onset of symptoms, alleviating symptoms, or eliminating the disease, condition or disorder.

[0084] As used herein, the term "substantially complementary" refers to complementarity in a base-paired, double-stranded region between two nucleic acids and not any single-stranded region such as a terminal overhang or a gap region between two double- stranded regions. The complementarity does not need to be perfect; there may be any number of base pair mismatches, for example, between the two nucleic acids. However, if the number of mismatches is so great that no hybridization can occur under even the least stringent hybridization conditions, the sequence is not a substantially complementary sequence. When two sequences are referred to as "substantially complementary" herein, it means that the sequences are sufficiently complementary to each other to hybridize under the selected reaction conditions. The relationship of nucleic acid complementarity and stringency of hybridization sufficient to achieve specificity is well known in the art. Two substantially complementary strands can be, for example, perfectly complementary or can contain from 1 to many mismatches so long as the hybridization conditions are sufficient to allow, for example discrimination between a pairing sequence and a non-pairing sequence. Accordingly, substantially complementary sequences can refer to sequences with base- pair complementarity of, e.g., 100%, 95%, 90%, 80%, 75%, 70%, 60%, 50% or less, or any number in between, in a double-stranded region. [0085] RNA interference (abbreviated as RNAi) is a cellular process for the targeted destruction of single-stranded RNA (ssRNA) induced by double-stranded RNA (dsRNA). The ssRNA is gene transcript such as a messenger RNA (mRNA). RNAi is a form of post-transcriptional gene silencing in which the dsRNA can specifically interfere with the expression of genes with sequences that are complementary to the dsRNA. The antisense RNA strand of the dsRNA targets a complementary gene transcript such as a messenger RNA (mRNA) for cleavage by a ribonuclease.

[0086] In RNAi process, long dsRNA is processed by a ribonuclease protein Dicer to short forms called small interfering RNA (siRNA). The siRNA is separated into guide (or antisense) strand and passenger (or sense) strand. The guide strand is integrated into RNA- induced-silencing-complex (RISC), which is a ribonuclease-containing multi-protein complex. The complex then specifically targets complementary gene transcripts for destruction.

[0087] RNAi has been shown to be a common cellular process in many eukaryotes.

RISC, as well as Dicer, is conserved across the eukaryotic domain. RNAi is believed to play a role in the immune response to virus and other foreign genetic material.

[0088] Small interfering RNAs (siRNAs) are a class of short double-stranded RNA

(dsRNA) molecules that play a variety of roles in biology. Most notably, it is involved in the RNA interference (RNAi) pathway where the siRNA interferes with the expression of a specific gene. In addition, siRNAs also play roles in the processes such as an antiviral mechanism or shaping the chromatin structure of a genome. In some embodiments, siRNA has a short (19-21 nt) double- strand RNA (dsRNA) region with 2-3 nucleotide 3' overhangs with 5 '-phosphate and 3'-hydroxyl termini.

[0089] Dicer is a member of RNase III ribonuclease family. Dicer cleaves long, double-stranded RNA (dsRNA), pre-microRNA (miRNA), and short hairpin RNA (shRNA) into short double-stranded RNA fragments called small interfering RNA (siRNA) about 20- 25 nucleotides long, usually with a two-base overhang on the 3' end. Dicer catalyzes the first step in the RNA interference pathway and initiates formation of the RNA-induced silencing complex (RISC), whose catalytic component argonaute is an endonuclease capable of degrading messenger RNA (mRNA) whose sequence is complementary to that of the siRNA guide strand.

[0090] As used herein, an effective siRNA sequence is a siRNA that is effective in triggering RNAi to degrade the transcripts of a target gene. Not every siRNA complementary to the target gene is effective in triggering RNAi to degrade the transcripts of the gene. Indeed, time-consuming screening is usually necessary to identify an effective siRNA sequence. In some embodiments, the effective siRNA sequence is capable of reducing the expression of the target gene by more than 90%, more than 80%, more than 70%, more than 60%, more than 50%, more than 40%, or more than 30%.

[0091] The present invention uses a structural scaffold called asymmetric interfering

RNA (aiRNA) that can be used to effect siRNA-like results, and also to modulate miRNA pathway activities, initially described in detail PCT Publications WO 2009/029688 and WO 2009/029690, the contents of which are hereby incorporated by reference in their entirety.

[0092] The structural design of aiRNA is not only functionally potent in effecting gene regulation, but also offers several advantages over the current state-of-art, RNAi regulators (mainly antisense, siRNA). Among the advantages, aiRNA can have RNA duplex structure of much shorter length than the current siRNA constructs, which should reduce the cost of synthesis and abrogate or reduce length-dependent triggering of nonspecific interferon-like immune responses from host cells. The shorter length of the passenger strand in aiRNA should also eliminate or reduce the passenger strand's unintended incorporation in RISC, and in turn, reduce off-target effects observed in miRNA-mediated gene silencing. AiRNA can be used in all areas that current miRNA-based technologies are being applied or contemplated to be applied, including biology research, R&D in biotechnology and pharmaceutical industries, and miRNA-based diagnostics and therapies.

[0093] In some embodiments, the first strand comprises a sequence being substantially complimentary to a target K-Ras mRNA sequence. In another embodiment, the second strand comprises a sequence being substantially complimentary to a target K-Ras mRNA sequence.

[0094] The present invention is pertinent to asymmetrical double stranded RNA molecules that are capable of effecting K-Ras gene silencing. In some embodiments, an RNA molecule of the present invention comprises a first strand and a second strand, wherein the second strand is substantially complementary, or partially complementary to the first strand, and the first strand and the second strand form at least one double-stranded region, wherein the first strand is longer than the second strand (length asymmetry). The RNA molecule of the present invention has at least one double-stranded region, and two ends independently selected from the group consisting of a 5 '-overhang, a 3'-overhang, and a blunt.

[0095] Any single-stranded region of the RNA molecule of the invention, including any terminal overhangs and gaps in between two double-stranded regions, can be stabilized against degradation, either through chemical modification or secondary structure. The RNA strands can have unmatched or imperfectly matched nucleotides. Each strand may have one or more nicks (a cut in the nucleic acid backbone), gaps (a fragmented strand with one or more missing nucleotides), and modified nucleotides or nucleotide analogues. Not only can any or all of the nucleotides in the RNA molecule chemically modified, each strand may be conjugated with one or more moieties to enhance its functionality, for example, with moieties such as one or more peptides, antibodies, antibody fragments, aptamers, polymers and so on.

[0096] In some embodiments, the first strand is at least 1 nt longer than the second strand. In a further embodiment, the first strand is at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 1 1 , 12, 13, 14, 15, 16, 17, 18, 19, or 20 nt longer than the second strand. In another embodiment, the first strand is 20-100 nt longer than the second strand. In a further embodiment, the first strand is 2-12 nt longer than the second strand. In an even further embodiment, the first strand is 3-10 nt longer than the second strand.

[0097] In some embodiments, the first strand, or the long strand, has a length of 5-100 nt, or preferably 10-30 or 12-30 nt, or more preferably 15-28 nt. In one embodiment, the first strand is 21 nucleotides in length. In some embodiments, the second strand, or the short strand, has a length of 3-30 nt, or preferably 3-29 nt or 10-26 nt, or more preferably 12-26 nt. In some embodiments, the second strand has a length of 15 nucleotides.

[0098] In some embodiments, the double-stranded region has a length of 3-98 basepairs (bp). In a further embodiment, the double-stranded region has a length of 5-28 bp. In an even further embodiment, the double-stranded region has a length of 10-19 bp. The length of the double-stranded region can be 3, 4, 5, 6, 7, 8, 9, 10, 1 1, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, or 30 bp.

[0099] In some embodiments, the double-stranded region of the RNA molecule does not contain any mismatch or bulge, and the two strands are perfectly complementary to each other in the double-stranded region. In another embodiment, the double-stranded region of the RNA molecule contains mismatch and/or bulge.

[00100] In some embodiments, the terminal overhang is 1-10 nucleotides. In a further embodiment, the terminal overhang is 1-8 nucleotides. In another embodiment, the terminal overhang is 3 nt.

[00101] The present invention also provides a method of modulating K-Ras gene expression in a cell or an organism (silencing method). The method comprises the steps of contacting said cell or organism with the duplex RNA molecule under conditions wherein selective K-Ras gene silencing can occur, and mediating a selective K-Ras gene silencing effected by the said duplex RNA molecule towards a target K-Ras nucleic acid having a sequence portion substantially corresponding to the double-stranded RNA.

[00102] In some embodiments, the contacting step comprises the step of introducing said duplex RNA molecule into a target cell in culture or in an organism in which the selective gene silencing can occur. In a further embodiment, the introducing step comprises transfection, lipofection, infection, electroporation, or other delivery technologies.

[00103] In some embodiments, the silencing method is used for determining the function or utility of a gene in a cell or an organism.

[00104] The silencing method can be used for modulating the expression of a gene in a cell or an organism. In some embodiments, the gene is associated with a disease, e.g., a human disease or an animal disease, a pathological condition, or an undesirable condition. In some embodiments, the disease is gastric cancer.

[00105] The RNA molecules of the present invention can be used for the treatment and or prevention of various diseases or undesirable conditions, including gastric cancer. In some embodiments, the present invention can be used as a cancer therapy or to prevent or to delay the progression of cancer. The RNA molecules of the present invention can he used to silence or knock down k-Ras, which is involved with cell proliferation or other cancer phenotypes.

[00106] The present invention provides a method to treat a disease or undesirable condition. The method comprises using the asymmetrical duplex RNA molecule to effect gene silencing of a gene associated with the disease or undesirable condition.

[00107] The present invention further provided a pharmaceutical composition. The pharmaceutical comprises (as an active agent) at least one asymmetrical duplex RNA molecule. In some embodiments, the pharmaceutical comprises one or more carriers selected from the group consisting of a pharmaceutical carrier, a positive-charge carrier, a liposome, a protein carrier, a polymer, a nanoparticle, a nanoemulsion, a lipid, and a lipoid. In some embodiments, the composition is for diagnostic applications. In some embodiments, the composition is for therapeutic applications.

[00108] The pharmaceutical compositions and formulations of the present invention can be the same or similar to the pharmaceutical compositions and formulations developed for siRNA, miRNA, and antisense RNA (see e.g., de Fougerolles et al, 2007, "Interfering with disease: a progress report on siRNA-based therapeutics." Nat Rev Drug Discov 6, 443453; Kim and Rossi, 2007, "Strategies for silencing human disease using RNA interference." Nature reviews 8, 173-184), except for the RNA ingredient. The siRNA, miRNA, and antisense RNA in the pharmaceutical compositions and formulations can be replaced by the duplex RNA molecules of the present disclosure. The pharmaceutical compositions and formulations can also be further modified to accommodate the duplex RNA molecules of the present disclosure.

[00109] A "pharmaceutically acceptable salt" or "salt" of the disclosed duplex RNA molecule is a product of the disclosed duplex RNA molecule that contains an ionic bond, and is typically produced by reacting the disclosed duplex RNA molecule with either an acid or a base, suitable for administering to a subject. Pharmaceutically acceptable salt can include, but is not limited to, acid addition salts including hydrochlorides, hydrobromides, phosphates, sulphates, hydrogen sulphates, alkylsulphonates, arylsulphonates, acetates, benzoates, citrates, maleates, fumarates, succinates, lactates, and tartrates; alkali metal cations such as Na, K, Li, alkali earth metal salts such as Mg or Ca, or organic amine salts.

[00110] A "pharmaceutical composition" is a formulation containing the disclosed duplex RNA molecules in a form suitable for administration to a subject. In one embodiment, the pharmaceutical composition is in bulk or in unit dosage form. The unit dosage form is any of a variety of forms, including, for example, a capsule, an IV bag, a tablet, a single pump on an aerosol inhaler, or a vial. The quantity of active ingredient (e.g., a formulation of the disclosed duplex RNA molecule or salts thereof) in a unit dose of composition is an effective amount and is varied according to the particular treatment involved. One skilled in the art will appreciate that it is sometimes necessary to make routine variations to the dosage depending on the age and condition of the patient. The dosage will also depend on the route of administration. A variety of routes are contemplated, including oral, pulmonary, rectal, parenteral, transdermal, subcutaneous, intravenous, intramuscular, intraperitoneal, intranasal, and the like. Dosage forms for the topical or transdermal administration of a duplex RNA molecule of this invention include powders, sprays, ointments, pastes, creams, lotions, gels, solutions, patches and inhalants. In one embodiment, the active duplex RNA molecule is mixed under sterile conditions with a pharmaceutically acceptable carrier, and with any preservatives, buffers, or propellants that are required.

[00111] The present invention provides a method of treatment comprising administering an effective amount of the pharmaceutical composition to a subject in need. In some embodiments, the pharmaceutical composition is administered via a route selected from the group consisting of iv, sc, topical, po, and ip. In another embodiment, the effective amount is 1 ng to 1 g per day, 100 ng to 1 g per day, or 1 ug to 1 mg per day. [00112] The present invention also provides pharmaceutical formulations comprising a duplex RNA molecule of the present invention in combination with at least one pharmaceutically acceptable excipient or carrier. As used herein, "pharmaceutically acceptable excipient" or "pharmaceutically acceptable carrier" is intended to include any and all solvents, dispersion media, coatings, antibacterial and antifungal agents, isotonic and absorption delaying agents, and the like, compatible with pharmaceutical administration. Suitable carriers are described in "Remington: The Science and Practice of Pharmacy, Twentieth Edition," Lippincott Williams & Wilkins, Philadelphia, PA., which is incorporated herein by reference. Examples of such carriers or diluents include, but are not limited to, water, saline, Ringer's solutions, dextrose solution, and 5% human serum albumin. Liposomes and non-aqueous vehicles such as fixed oils may also be used. The use of such media and agents for pharmaceutically active substances is well known in the art. Except insofar as any conventional media or agent is incompatible with the active duplex RNA molecule, use thereof in the compositions is contemplated. Supplementary active duplex RNA molecules can also be incorporated into the compositions.

[00113] A duplex RNA molecule of the present invention is administered in a suitable dosage form prepared by combining a therapeutically effective amount (e.g., an efficacious level sufficient to achieve the desired therapeutic effect through inhibition of tumor growth, killing of tumor cells, treatment or prevention of cell proliferative disorders, etc.) of a duplex RNA molecule of the present invention (as an active ingredient) with standard pharmaceutical carriers or diluents according to conventional procedures (i.e., by producing a pharmaceutical composition of the invention). These procedures may involve mixing, granulating, compressing, or dissolving the ingredients as appropriate to attain the desired preparation. In another embodiment, a therapeutically effective amount of a duplex RNA molecule of the present invention is administered in a suitable dosage form without standard pharmaceutical carriers or diluents.

[00114] Pharmaceutically acceptable carriers include solid carriers such as lactose, terra alba, sucrose, talc, gelatin, agar, pectin, acacia, magnesium stearate, stearic acid and the like. Exemplary liquid carriers include syrup, peanut oil, olive oil, water and the like. Similarly, the carrier or diluent may include time-delay material known in the art, such as glyceryl monostearate or glyceryl distearate, alone or with a wax, ethylcellulose, hydroxypropylmethylcellulose, methylmethacrylate or the like. Other fillers, excipients, flavorants, and other additives such as are known in the art may also be included in a pharmaceutical composition according to this invention. [00115] The pharmaceutical compositions containing active duplex RNA molecules of the present invention may be manufactured in a manner that is generally known, e.g., by means of conventional mixing, dissolving, granulating, dragee-making, levigating, emulsifying, encapsulating, entrapping, or lyophilizing processes. Pharmaceutical compositions may be formulated in a conventional manner using one or more physiologically acceptable carriers comprising excipients and/or auxiliaries which facilitate processing of the active duplex RNA molecules into preparations that can be used pharmaceutically. Of course, the appropriate formulation is dependent upon the route of administration chosen.

[00116] A duplex RNA molecule or pharmaceutical composition of the invention can be administered to a subject in many of the well-known methods currently used for chemotherapeutic treatment. For example, for treatment of cancers, a duplex RNA molecule of the invention may be injected directly into tumors, injected into the blood stream or body cavities or taken orally or applied through the skin with patches. For treatment of psoriatic conditions, systemic administration (e.g., oral administration), or topical administration to affected areas of the skin, are preferred routes of administration. The dose chosen should be sufficient to constitute effective treatment but not as high as to cause unacceptable side effects. The state of the disease condition (e.g., gastric cancer) and the health of the patient should be closely monitored during and for a reasonable period after treatment.

EXAMPLES

[00117] Examples are provided below to further illustrate different features of the present invention. The examples also illustrate useful methodology for practicing the invention. These examples do not limit the claimed invention.

EXAMPLE 1 : In vitro potency of aiK-Ras

[00118] Figure 1(A) shows an in vitro study in which aiRNA ID NO: 21 ("aiK-Ras

#1") was used to target K-Ras Target SEQ ID NO: 22 to determine the IC ₅ o for aiK-Ras #1. DLD1 cells (ATCC) were transfected with aiK-Ras #1. 48 hours after transfection, cells were collected and RNA was isolated. The IC ₅₀ of aiK-Ras #1 was determined by qPCR. Remaining mRNA was standardized to the GAPDH expression level. The IC ₅₀ of 3.1 pM indicates that aiK-Ras #1 silences K-Ras gene expression with high potency. [00119] Figure 1(B) shows an in vitro study in which aiRNA ID NO: 142 ("aiK-Ras

#2") was used to target K-Ras Target SEQ ID NO: 142 to determine the IC ₅₀ for aiK-Ras #2. DLD1 cells were transfected with aiK-Ras #2. 48 hours after transfection, cells were collected and RNA was isolated. The IC ₅₀ of aiK-Ras #2 was determined by qPCR. Remaining mRNA was standardized to the GAPDH expression level. The IC ₅₀ of 3.5 pM indicates that aiK-Ras #1 silences K-Ras gene expression with high potency.

EXAMPLE 2: Reduced off-target effect of aiK-Ras

[00120] Figure 2(A) shows detection of siRNA and aiRNA loading to RISC by northern blot analysis. To analyze small RNA RISC loading, HEK293 Flag-Ago2 stable cells were transfected with aiRNA or siRNA duplexes. Cells were lysed at the indicated time points and immunoprecipitated with Flag antibody (Sigma, Catalog # F1804). Immunoprecipitates were washed, RNA isolated from the complex by TRIZOL (Life Technologies, 15596-018) extraction, and loaded on 15% TBE-Urea PAGE or 15% TBE non-denaturing PAGE gels. Following electrophoreses, RNA was transferred to Hybonad-XL Nylon membrane. Then hybridizing the r-P32 labeled detect sense strand or anti-sense strand probe to RNA on the membrane. HEK293 cells (Invivogen, Catalog # 293-null) expressing Flag-Ago2 were transfected with siRNA or aiRNA, after which an immunoprecipitation assay was conducted. FLAG-Ago2 HEK 293 cells stably expressing FLAG-Ago2 cells were generated through transient transfection of FLAG-Ago2 neomycin plasmid DNA vectors. After selective neomycin containing medium culture, the monoclonal populations were selected by western blot. Non-denatured gel was used to detect dsRNA.

[00121] Figure 2(B) shows reduced off-target of aiRNA. HeLa cells were transfected with luciferase reporter genes fused with antisense or sense strand-based aiRNA or siRNA target sequences and aiK-Ras#2 or siK-Ras#2 (5 nM). Figure 2(C) shows that TLR3/RNA complexes were immunoprecipitated with anti-HA antibody (Invivogen, Catalog # ab-hatag). RNA was extracted from the pellet, and northern blot analysis was performed to determine the interaction between aiRNA/siRNA and the TLR3 receptor.

[00122] Figures 2(A)-(C) show that the asymmetric structure of aiK-Ras #1 and aiK-

Ras #2 reduced sense strand mediated off-target effect and LTR3 binding.

EXAMPLE 3: aiK-Ras sensitivity in K-Ras mutant cells

[00123] Figure 3(A) shows colony formation assay in AGS (ATCC) and DLD1 cells transfected with aiK-Ras #1 or aiK-Ras #2. Cells were transfected with 1 nM GFP aiRNA (control; GGTTATGTACAGGAACGCA (SEQ ID NO: 956)) or 1 nM aiK-Ras #1 or aiK- Ras #2 for 24 hours. Cells were then trypsinized and re-plated on 6-well plates at 500-2000 cells/well to determine the colony formation ability of the cells. After 11-14 days, colonies were stained with Giemsa stain and were counted. For the western blot analysis, cells were washed with ice-cold PBS and lysed in lysis buffer [50 mM Hepes (pH 7.5), 1% Nonidet P- 40, 150 mM NaCl, 1 mM EDTA, and 1 * Halt Protease Inhibitor Cocktail (Thermo Scientefic, Catalog # 87786)]. Soluble protein (10 μg) was separated by SDS/PAGE and transferred to PVDF membrane. Primary antibodies against were used in this study. The antigen-antibody complexes were visualized by enhanced chemiluminescence (BioRad, Catalog # 170-5060).

[00124] Figure 3(B) shows western blot analysis of lysate from AGS and DLD1, and the transfection effects of aiK-Ras #1 and aiK-Ras #2 on K-Ras expression, cleaved caspase 3, and cleaved PARP.

[00125] Figure 3(C) shows colony formation assay results in a large cell panel. All cell lines in the panel were obtained from ATCC. Cells harboring K-Ras mutant are highlighted.

EXAMPLE 4: Correlation between aiK-Ras sensitivity and K-Ras amplification

[00126] Figure 4 shows western blot analysis of K-Ras and EGFR-RAS pathway molecules. Lysate (10 μg/lane) was loaded and total and phosphorylated forms of EGFR, cRaf, MEK, and ERK were detected. Activated form of K-Ras (K-Ras GTP) was affinity- purified from cell lysate using GST-Raf-RBD and analyzed by western blotting with K-Ras antibody. The following antibodies were used for western blot: Actin (Sigma, Catalog # A5316) K-RAS (Santa Cruz, sc30 and Cell signaling, Catalog # 8955), Cleaved PARP (Cell Signaling, Catalog # 5625), Cleaved Caspase-3 (Cell Signaling, Catalog # 9664), Phospho- EGF Receptor (Cell Signaling, Catalog # 3777), EGF Receptor (Cell Signaling, Catalog # 4267), Phospho-c-Raf (Cell signaling, Catalog # 9427), c-Raf (Cell Signaling, Catalog # 9422), Phospho-MEKl/2 (Cell Signaling, Catalog # 9154), MEK1/2 (Cell Signaling, Catalog # 8727), Phospho-p44/42 MAPK (Erkl/2) (Cell Signaling, Catalog # 4370), p44/42 MAPK (Erkl/2) (Cell Signaling, Catalog # 4695), Jaggedl (Cell Signaling, Catalog # 2620), Notchl (Cell Signaling, Catalog # 3608), c-Myc (Cell Signaling, Catalog # 5605). RBD pulldown was performed using a Ras Activation Kit (Abeam, Catalog # ab 128504) according to the manufacturer's protocol. Precipitations were blotted for K-Ras (Santa Cruz, Catalog # sc30). Actin (Sigma, Catalog # A5316) was blotted as loading control. Figure 4 shows that aiK-Ras sensitivity correlates with K-Ras amplification, and not with the activation state of the Ras pathway molecules.

[00127] Figure 5(A) shows that aiK-Ras sensitivity was correlated with K-Ras amplification in K-Ras mutant large cell panel. All cell lines in the panel were obtained from ATCC. Copy number of K-Ras was analyzed by qPCR. Statistical difference was determined by two-sided Mann-Whitney's U test. Difference with p<0.05 was considered statistically significant.

[00128] Figure 5(B) shows that aiK-Ras sensitivity was correlated with K-Ras amplification in K-Ras mutant large cell panel. K-Ras protein expression level was measured by western blot. Band of western blot was quantified by Image Lab (Biorad). Statistical difference was determined by two-sided Mann- Whitney's U test. Difference with p<0.05 was considered statistically significant.

[00129] Figures 3(A)-(C) and 5(A)-(B) show that aiK-Ras sensitivity varies in K-Ras mutant cells and it correlates with K-Ras copy number.

EXAMPLE 6: Effect of aiK-Ras on CSC-like phenotvpe in sensitive cell lines

[00130] Figure 6(A) shows sternness gene expression in CSC culture. AGS cells were cultured in CSC medium [DMEM nutrient mixture F- 12 (DMEM/F- 12, Life technologies, Catalog # 1 1320-033) containing B-27 supplement (Life Technologies, Catalog # 17504- 044), 20 ng/mL EGF (R&D Systems, Catalog # 236-EG), 10 ng/mL FGF (R&D Systems, Catalog # 233-FB), and 1% penicillin/streptomycin] for 2 weeks. Nanog, Oct4, and Sox2 gene expression of CSC spheres was quantified by qPCR.

[00131] Figure 6(B) shows the results of sphere formation assay in various cell lines.

For the sphere formation assay, agarose coated plates were prepared to dispense autoclaved 0.5% agar and aspirated immediately. Transfected cells were trypsinized and counted, then diluted to 2000 cells/100 uL of 1 x CSC medium. 1.9 mL of warmed CSC medium including 0.33% agarose (Sigma type VII, Catalog # A-4018) was added to the cells in CSC medium for final agarose concentration of 0.3%. The plate was placed at 4°C for 10 minutes to cool. The plate was placed 10 minutes at room temperature and 1 mL of CSC medium was added to the top layer. The plate was incubated in a 37°C 15% CO ₂ incubator for 18-25 days. To count spheres, CSC medium was aspirated and Crystal violet (EMD, Catalog # 192- 12) solution in PBS were added and incubated for 1 hour at room temperature to stain spheres.

[00132] Cells were trypsinized and re-plated in CSC medium/3% soft agar onto agar coated 6-well plates at 2000 cells/well to determine the sphere formation ability of the cells. After 18-25 days, spheres were stained with crystal violet, and the number of spheres was counted.

[00133] Figure 6(C) shows depletion of CD44-high population in AGS and DLD1 cells with aiK-Ras #1 and aiK-Ras #2. CD44 expression was detected by flow cytometry, wherein AGS and DLD 1 cells were stained with PE conjugated anti-CD44 (BD Pharmingen, Catalog # 555479) in Stain Buffer (BD Pharmingen, Catalog # 554657) on ice for 45 minutes and washed once with Stain Buffer. CD44 positive population was detected with flow cytometry (Attune Acoustic Focusing Cytometer, Life technologies).

[00134] Figures 6(A)-(C) show that aiK-Ras according to the present invention modulate CSC-like phenotype in sensitive cell lines.

EXAMPLE 7: Effect of K-Ras knockdown on CSC-related gene expression patterns.

[00135] Figure 7(A) shows heat map of CSC-related genes in cancer cells transfected with aiK-Ras. Cells were transfected with 1 nM control aiRNA or aiK-Ras #1 for 48 hours. Real-time PCR was performed on total RNA using specific validated primers for 84 CSC- related genes with RT2 Profiler PCR array. The fold change in gene expression was calculated as the ratio between aiK-Ras #1 and the control aiRNA samples. Figure 7(B) shows confirmation of down-regulated Notch signaling by western blot. Table 3 below summarizes the genes down-regulated >3 fold with aiK-Ras #1 corresponding to the heat map as shown in Figure 7(A)

Table 3.

[00136] The embodiments illustrated and discussed in this specification are intended only to teach those skilled in the art the best way known to the inventors to make and use the invention. Nothing in this specification should be considered as limiting the scope of the present invention. All examples presented are representative and non-limiting. The above- described embodiments of the invention may be modified or varied, without departing from the invention, as appreciated by those skilled in the art in light of the above teachings. It is therefore to be understood that, within the scope of the claims and their equivalents, the invention may be practiced otherwise than as specifically described.