Technical Field

The present invention relates to pyrimidine derivatives and guanine derivatives, and their use in treating tumour cells. In particular, it relates to 6-hetarylalkyloxy pyrimidine derivatives, Q -substituted guanine derivatives and £ -substituted thioguanine derivatives, these compounds exhibiting the ability to deplete 0 -alkylguanine-DNA alkyltransferase (ATase) activity in tumour cells.

Background Art

It has been suggested to use 0 -alkyl guanine derivatives possessing 0 -alkylguanine-DNA alkyltransferase depleting activity in order to enhance the effectiveness of chemotherapeutic alkylating agents, principally those that methylate or chloroethylate DNA, used for killing tumour cells. There is increasing evidence that in mammalian cells the toxic and mutagenic effects of alkylating agents are to a large extent a consequence of alkylation at the Q -position of guanine in DNA. The repair of Q -alkylguanine is mediated by ATase, a repair protein that acts on the Q -alkylated guanine residues by stoichiometric transfer of the alkyl group to a cysteine residue at the active site of the repair protein in an

autoinactivating process. The importance of ATase in protecting cells against the biological effects of alkylating agents has been most clearly demonstrated by the transfer and expression of cloned ATase genes or cDNAs into ATase deficient cells: this confers resistance to a variety of agents, principally those that methylate or chloroethylate DNA. Whilst details of the mechanism of cell killing by Q -methylguanine in ATase deficient cells is not yet clear, killing by Q -chloroethylguanine occurs through DNA interstrand crosslink formation to a cytosine residue on the opposite strand via a cyclic ethanoguanine intermediate, a process that is prevented by ATase- ediated chloroethyl group removal or complex formation.

The use of 0 -methylguanine and 0 -n-butylguanine for depleting ATase activity has been investigated (Dolan et al_. , Cancer Res.. (1986) 46, pp. 4500; Dolan et al-, Cancer Chemother. Pharmacol .. (1989) 25. pp 103. 0 -benzylguanine derivatives have been proposed for depleting ATase activity in order to render ATase expressing cells more susceptible to the cytotoxic effects of chloroethylating agents (Moschel et al. , J. Med.Chem.. 1992, 35 , 4486). U.S. Patent 5091 430 and International Patent Application No. W0 91/13898 Moschel et al. disclose a method for depleting r levels of 0 -alkylguanine-DNA alkyl-transferase in tumour cells in a host which comprises administering to the host an effective amount of a composition containing 0 -benzylated guanine derivatives of the following formula:

wherein Z is hydrogen, or

and R ^a is a benzyl group or a substituted benzyl group. A benzyl group may be substituted at the ortho. meta or para position with a substituent group such as halogen, nitro, aryl such as phenyl or substituted phenyl, alkyl of 1-4 carbon atoms, alkoxy of 1-4 carbon atoms, alkenyl of up to 4 carbon atoms, alkynyl of up to 4 carbon atoms, amino, monoalkylamino, dialkylamino, trifluoromethyl , hydroxy, hydroxy eth l , and SO R wherein n is 0, 1, 2 or 3 and h

R is hydrogen, alkyl of 1-4 carbon atoms or aryl. Chae et al . , J.Med.Chem.. 1994, 37, 342-347 describes tests on

0 -benzylguanine analogs bearing increasingly bulky substituent groups on the benzene ring or at position 9. Chae e_t. aj _. ., J. Med. Chem. 1995, 38, 359-365 describe several 8-substituted 0 -benzylguanines, 2- and/or 8-substituted 6-(benzyloxy)purines, substituted 6(4)-(benzyloxy)pyrimidines, and a

6-(benzyloxy)- -triazine which were tested for their ability to inactivate ATase . Two types of compounds were identified as being significantly more effective than Q -benzylguanine at inactivating ATase in human HT29 colon tumour cell extracts. These were 8-substituted 0 -benzylguanines bearing electron-withdrawing groups at the 8-position (e.g. 8-aza-0 -benzylguanine and 0 -benzyl-8-bromoguanine) and 5-substituted

2,4-diamino-6-(benzyloxy)pyrimidines bearing electron withdrawing groups at the 5-position (e.g. 2,4-diamino -6-(benzyloxy)-5-nitroso- and 2,4-diamino-6-(benzyloxy)-5-nitropyrimidine) . The latter derivatives were also more effective than Q -benzylguanine at inactivating ATase in intact HT29 colon tumour cells. WO 96/04280 published after the priority dates of this application concerns ssiimmiillaarr ssuubbssttiittuutteedd 00 --bbeernzylguanines and 6(4)-benzyloxypyrimidines.

The present Applicants are also Applicants in International Patent Application PCT/IE94/00031 which was published under No. W0 94/29312. W094/29312 (the contents of which are incorporated herein by reference in their entirety) describes 0 -substituted guanine derivatives of formula I:

wherein . Y is H, ribosyl, deoxyribosyl , or R'^CHR' ¹¹ , wherein X is 0 or S, R ¹ ' and R ¹ ' ' are alkyl, or substituted derivatives thereof;

R ¹ is H, alkyl or hydroxyalkyl; R is (i) a cyclic group having at least one 5- or 6-membered heterocyclic ring, optionally with a carbocyclic or heterocyclic ring fused thereto, the or each heterocyclic ring having at least one hetero atom chosen from 0, N, or S, or a substituted derivative thereof; or

(ii) naphthyl or a substituted derivative thereof;

and pharmaceutically acceptable salts thereof.

In order to be useful for depleting ATase activity and thus enhance the effects of the above-mentioned chemotherapeutic agents, compounds should have combination of characteristics assessed by reference to:

1) In vitro inactivation of recombinant ATases.

2) Stability.

3) Solubility.

4) Inactivation of ATase in mammalian cells and/or tumour xenografts.

5) Sensitization of mammalian cells and/or tumour xenografts to the killing or growth inhibitory effects of the said chemotherapeutic agents

The behaviour of novel compounds in this combination of tests is unpredictable. Molecular interactions including steric factors in the unpredictability of ATase inactivation may be related to the nature of the environment of the cysteine acceptor site in the ATase molecule.

The structure of the ATase protein derived from E. coli (Ada gene) has been elucidated by X-ray crystallographic techniques (M.H. Moore et. a_ , EMBO Journal . 1994, 13, 1495.). While the amino acid sequence of human ATase differs somewhat from that of bacterial origin, all known ATases (human, rodent, yeast, bacterial) contain the cysteine (Cys) acceptor site in a common fragment, Pro-Cys-His-Arg. A homology model of human ATase generated by computer from the crystal structure of the Ada protein (J.E.A. Wibley et. al. , Anti-Cancer Drug Design. 1995, 10, 75.) resembles it in having the Cys acceptor buried in a pocket deep in the protein. Considerable distortion of the structure is necessary to bring either an 0 -alkylated guanine residue in intact DNA, or even free guanine alkylated by a relatively large group like benzyl, close to the Cys acceptor. These configurational changes are initiated by a characteristic binding of duplex DNA to the protein (K. Goodtzova et. aK Biochemistry, 1994, 33, 8385).

Since the amino acid components and dimensions of the ATase active site "pocket" are still unknown as are the details of the mechanism involved, it is impossible to predict the activity of a particular 0 -alkylated guanine or analogous ring system.

Published work in this field relates predominantly to the use of 0 -alkyl guanine derivatives having a nucleus identical to that of guanine in DNA. Chae et. al. , J. Med. Chem. 1995, 38, 359-365 have described tests on a limited number of compounds in which the

guanine ring was modified. However these compounds all had benzyl substitution at the 0 - position of the modified guanine ring or 6(4)-benzyloxy substitution on the pyrimidine ring. The observation that subtle changes in the substituents on the guanine ring or in the purine skeleton can generate agents that are very ineffective ATase inactivators, in comparison with their "parent" structure, suggests that more substantial modifications might also disrupt the ATase inactivating function.

There is a need for additional novel compounds useful for depleting ATase activity in order to enhance the effects of chemotherapeutic agents such as chloroethylating or methylating anti-tumour agents. It is a further object to provide compounds having better ATase inactivating characteristics than

0 -benzylguanine and having different solubility patterns.

Another object of the invention is to provide pharmaceutical compositions containing compounds which are useful for depleting ATase activity. A further object of the present invention is to provide a method for depleting ATase activity in tumour cells. A still further object of the invention is to provide a method for treating tumour cells in a host in such a way that they become more sensitive to the above-mentioned alkylating agents.

The present i nvention provides 6-hetaryl al kyl oxy pyrimi di ne deri vati ves of formul a I I :

wherein R is (i) a cyclic group having at least one 5- or 6- membered heterocyclic ring, optionally with a carbocyclic or heterocyclic ring fused thereto, the or each heterocyclic ring

having at least one hetero atom chosen from 0, N or S, or a substituted derivative thereof; or

(ii) phenyl or a substituted derivative thereof, 2 R is selected from H, C,-Cr alkyl, halogen or NH ₉ , 4 5 o

R and R which are the same or different are selected from H, NH-Y' or NO wherein Y' is H, ribosyl, deoxyribosyl, arabinosyl, R"XCHR'" wherein X is 0 or S and R" is alkyl and R ¹ ' ¹ is H or alkyl, or substituted derivatives thereof, n = 1 or 2,

4 5 or R and R together with the pyrimidine ring form a 5-or

6-membered ring structure containing one or more hetero atoms, and pharmaceutically acceptable salts thereof,

with the proviso that R ² is not NH if R ⁴ and R ⁵ form a ring structure IX

-N

^ ^,x

I wherein Y is H, ribosyl, deoxyribosyl, or R''XCHR''' wherein X is 0 or S, R' ' and R' ¹ ' are alkyl, or substituted derivatives thereof,

and with the proviso that R is not phenyl in the following circumstances a) to h) :

a) if R ² and R ⁵ are NH ₂ and R ⁴ is NO or 0 ₂

b) if R ² is NH ₂ and R ⁴ and R ⁵ form a ring structure X ^

N X

I

H c) if R ? is NH _? and R4 and R5 form a ring structure XI

d) if R ² is NH ₂ , and R ⁴ is 0 ₂ and R ⁵ is H or CH ₃

e) if R ² , R ⁴ and R ⁵ are NH

f) if R^ and R ^ϋ are NH,, and R is H,

g) if R ² is H, and R ⁴ is 0 ₂ and R ⁵ is NH ₂ , or

h) if R 2 is F or OH, and R4 and R5 form a ring structure

XII

Certain Q -substituted guanine derivatives within the scope of the general formula in WO 94/29312 but not published therein have been found to have a surprisingly advantageous combination of properties which justifies the selection of such derivatives from among the class defined in WO 94/29312.

In another aspect, the present invention provides guanine derivatives of formula XIII:

xm

wherein

E is 0 or S,

Y' is as defined for formula II above,

R is a cyclic group having at least one 5- or 6-membered heterocyclic ring, optionally with a carbocyclic or heterocyclic ring fused thereto, the or each heterocyclic ring having at least one hetero atom chosen from 0, N or S, or a substituted derivative thereof, and pharmaceutically acceptable salts thereof, with the proviso that compounds published in WO 94/29312 are disclaimed.

In particular, the present invention selects advantageous compounds of formula XIV:

wherein R 10 is bromo, chloro or cyano, and Y is as defined for formula II. ,10

Most preferably, R is bromo. A particularly preferred and selected compound is 0 -(4-bromothenyl)guanine having the formula XV:

This compound has an advantageous combination of properties including potential for oral administration.

R or R may suitably be a 5- or 6-membered heterocyclic ring or a benzo derivative thereof, in which latter case the pyrimidine mmooiieettyy mmaayy bbee aattttached to R or R at either the heterocyclic or the benzene ring.

In preferred embodiments, R or R is a 5-membered ring containing S or 0, with or without a second ring fused thereto.

Preferably, R or R is a heterocyclic ring having at least one S atom; more preferably, R or R is a 5-membered heterocyclic ring having at least one S atom; and most preferably, R or R is a thiophene ring or a substituted derivative thereof. Alternatively, R or R may be a heterocyclic ring having at least one 0 atom, particularly, a 5-membered heterocyclic ring having at least one 0 atom and more particularly R or R may be a furan ring or a substituted derivative thereof. As another alternative, R or R may be a heterocyclic ring having at least one N atom, particularly R or R may be a 6-membered heterocyclic ring having at least one atom and in particular, R or R may be a pyridine ring.

The carbocyclic or heterocyclic ring fused to the heterocyclic ring in R or R may itself be bicyclic e.g. naphthalene.

In general the term "substituted derivative" as used in relation to any of the compounds of the invention means any substituted derivative whose presence in the compound is consistent with the compound having ATase depleting activity.

In the definition of Y or Y', the term "substituted derivative" includes further substitution by one or more of the following groups: hydroxy, halo, alkoxy, amino, alkylamino, amido or ureido. In a particularly preferred group of compounds, R" is hydroxy-substituted alkyl and R' ' ' is H, so that Y ¹ is hydroxyalkoxymethyl, preferably having 1 to 10 carbon atoms in the alkoxy group.

In the definition of R or R , the term "substituted derivative" includes substitution of the heterocyclic ring(s) and/or carbocyclic ring(s) by one or more of the following groups: alkyl, alkenyl, alkynyl, alkoxy, aryl, halo, haloalkyl, nitro, cyano, azido, hydroxyalkyl , SO R where R is alkyl and n = 0,1 or 2, o o or a carboxyl or ester group of the formula -C00R wherein R is

H or alkyl. Halo, haloalkyl, cyano, alkylenedioxy, SO R (as

8 8 ^ defined above) and -C00R wherein R is alkyl are preferred substituents.

An alkyl, alkoxy, alkenyl, or alkynyl group preferably contains from 1 to 20, more preferably from 1 to 10 and most preferably from 1 to 5 carbon atoms. Halo includes iodo, bromo, chloro or fluoro. An aryl group preferably contains from 1 to 20, more preferably from 1 to 10 carbon atoms, particularly 5 or 6 carbon atoms.

One embodiment of the invention provides a pharmaceutical composition containing compounds of formula II or formula XIII, as defined above, or a pharmaceutically acceptable salt thereof, and a pharmaceutically acceptable excipient. Optionally the composition may also contain an alkylating agent such as a chloroethylating or methylating agent.

In a further embodiment, the present invention provides a method for depleting ATase activity in a host comprising administering to the host an effective amount of a composition containing a compound of formula II or formula XIII as defined above, or a pharmaceutically acceptable salt thereof, more particularly a pharmaceutical composition as defined above. This method may alternatively be defined as a method of depleting ATase mediated DNA repair activity in a host.

The invention further provides a method for treating tumour cells in a host comprising administering to the host an effective amount of a composition containing a compound of formula II or

formula XIII as defined above or a pharmaceutically acceptable salt thereof, more particularly a pharmaceutical composition as defined above and administering to the host an effective amount of a composition containing an alkylating agent. The method may be used for treatment of neoplasms including those which are known to be sensitive to the action of alkylating agents e.g. melanoma and glioma and others whose resistance to treatment with alkylating agents alone may be overcome by the use of an inactivator according to the invention.

The term "pharmaceutically acceptable salts" as used in this description and the claims means salts of the kind known in the pharmaceutical industry including salts with inorganic acids such as sulfuric, hydrobromic, nitric, phosphoric or hydrochloric acid and salts with organic acids such as acetic, citric, maleic, fumaric, benzoic, succinic, tartaric, propionic, hexanoic, heptanoic, cyclopentanepropionic, glycolic, pyruvic, lactic, malonic, malic, o-(4-hydroxy-benzoyl)benzoic, cinnamic, mandelic, methanesulfonic, ethanesulfonic, 1,2-ethanedisulfonic, 2-hydroxyethanesulfonic, benzenesulfonic, p-chlorobenzenesulfonic 2-naphthalenesulfonic, p-toluenesulfonic, camphorsulfonic,

4-methyl-bicyclo[2.2.2]oct-2-ene-l-carboxyl ic, glucoheptonic, 4,4' -methylenebis(3-hydroxy-2-naphthoic) , 3-phenylpropionic, trimethyl-acetic, tertiary butylacetic, lauryl sulfuric, gluconic , glutamic, hydroxynaphthoic, salicylic, stearic, or muconic, and the like.

Subject to the provisos above the preferred compounds of the invention are those of:

wherein :

R is as defined for formula II, particularly furyl or thienyl unsubstituted or substituted, preferably with a halogen such as chlorine, bromine or fluorine, or with cyano

Y' is as defined for formula XIII, preferably Y ¹ is H or

C,-Cr alkyl, preferably methyl, or halogen, preferably fluorine;

wherein: R is as defined for formula II, particularly phenyl, thienyl or furyl unsubstituted or substituted preferably with a halogen such as chlorine, bromine or fluorine, or with cyano, or phenyl having a methylenedioxy ring structure fused thereto; Y ¹ is as defined for formula XIII; X is CH or N;

A is CH or N; and preferably when X = N, A = CH

Formula V

wherein: R is as defined for formula II

X is CH or N

A is CH or N;

Type 3 Formul a VI

wherein:

R is as defined for formula II, particularly, thienyl or furyl unsubstituted or substituted preferably with a halogen such as chlorine or bromine;

Z is 0 or S or CH = CH;

A particularly preferred group of compounds of this type are 0 -(4-halothenyl)-8-thiaguanines, particularly 0 -(4-bromothenyl)-8-thiaguanine.

Formula VII

wherein:

R is as defined for formula II;

U is CH or N;

V is CH or N;

W i s CH or N; provi ded that U , V and W are not al l CH .

Type 4 Formul a VIII

wherein:

R is as defined for formula II, particularly thenyl or furyl optionally substituted with halogen preferably one or more of chlorine, bromine or fluorine;

T is H, NH or NO where n = 1 or 2; 2 n

Q is H, NH ₂ or NO where n = 1 or 2;

wherein R is as defined for formula XIII Y' is as defined for formula II

Brief Description of Drawings

The invention will be described in greater detail with reference to the accompanying drawings, in which:

Figures 1 to 4 are graphs showing the effect of pretreatment with compound B.4316 on Raji cell sensitization to different chemotherapeutic agents. Each graph plots percentage growth against the concentration (μg/ml) of the chemotherapeutic agent in the presence and absence of B.4316.

Figure 1 shows the effect of luM B.4316 pretreatment on Raji cell sensitization to temozolomide.

Figure 2 shows the effect of lOum B.4316 pretreatment on Raji cell sensitization to BCNU.

Figure 3 shows the effect of lOυM B.4316 pretreatment on Raji cell sensitization to fotemustine.

Figure 4 shows the effect of 10/JM B4316 pretreatment on Raji cell sensitization to melphalan and cisplatin.

Figure 5 is a histogram showing the effect of IOJM B4316 pretreatment on Raji cell sensitization to different chemotherapeutic agents, measured as sensitization factor (SF, defined below) based on D _™ except for fotemustine where SF is based on D _β0 -

Figure 6 is a similar histogram showing the effect of lOμM B4349 pretreatment on Raji cell sensitization to different chemotherapeutic agents, with SF as for Figure 5.

Figure 7 is a series of histograms showing the inactivation of ATase in A375M tumours and urine host tissues two hours after interperitoneal (i.p.) administration of various inactivator compounds at 5mg/kg. Inactivation was calculated as % of control ATase activity, measured as fm/mg protein.

Figure 8 is a graph showing the kinetics of ATase depletion and recovery in A375M tumours and murine host tissues after administration of B.4363 (20 mg/kg i.p.). The graph plots % of control ATase activity against time (hours).

Figure 9 is a graph of percentage residual activity of pure recombinant human ATase following incubation with increasing concentrations of inactivators 0 -benzylguanine (BeG), 0 -thenylguanine (B.4205) and Q -(4-bromothenyl)guanine

(B.4280). The line at 50% residual activity is used for calulating I _π values i.e. the concentration of inactivator required to

produce a 50% reduction in ATase activity. The I values shown are extrapolated from the curves. Preincubation was for 1 hour aafftteerr wwhhiicchh [[ HH]]--mmeetthhyyllaatteedd substrate was added to determine residual activity of ATase.

Figure 10A is three graphs of percentage cell growth against temozolo ide concentration (μg/ml) showing the effect of pretreatment with BeG, B.4205 and B.4280 (0.5μM final concentration) on the sensitivity of Raji cells to the growth inhibitory effects of temozolomide. Inactivator or vehicle was given 2 hours prior to temozolomide.

Figure 10B is a histogram for the inactivators of Figure 10A showing the sensitization factor based on D _™ of Raji cells to growth inhibition by temozolomide.

Figure 11 is a histogram of ATase activity (fm/mg) against time (hours) showing the effect of ATase inactivators BeG, B.4205 and B.4280 on ATase activity in human melanoma xenografts grown in nude mice. Animals were given a single dose of the inactivators intraperitoneally (i.p.) at 30mg/kg or 60mg/kg and sacrificed after the times shown.

Figure 12 is a histogram showing the effect of ATase inactivators on ATase activity (fm/mg) in human melanoma xenografts grown in nude mice. Animals were given B.4205 or temozolomide alone or B.4205 or B.4280 in combination with temozolomide (50mg/kg)i .p. at the doses shown on three consecutive days (except where indicated) and sacrificed 24 hours after the final dose. The vehicles were corn oil for the inactivators and PBS (20%DMSO) for temozolomide.

Figure 13 is a histogram showing the effect of ATase inactivators on ATase activity in livers of nude mice. Animals were given the B.4205 or temozolomide alone or B.4205 or B.4280 in combination with temozolomide (50mg/kg, i.p.) at the doses shown on

three consecutive days (except where indicated) and sacrificed 24 hours after the final dose.

Figure 14A is a graph of % tumour growth against time (days) showing the effect of B.4205 on the sensitivity of human melanoma xenografts to growth inhibition by temozolomide. Animals were untreated, given temozolomide alone (lOOmg/kg, i.p.) or B.4205 (5, 10 or 20mg/kg i.p.) followed 1 hour later by temozolomide (lOOmg/kg, i.p.) on five consecutive days. Tumour growth was monitored as described. The data from a number of separate studies are presented.

Figure 14B is a graph of number of surviving mice against time (days) showing survival of animals (tumour-bearing nude mice) used in the study shown in Figure 14A. Groups of animals in which the xenografts had reached the maximum size were terminated.

Figure 15A is a graph showing the effect of B.4280 on the sensitivity of human melanoma xenografts to growth inhibition by temozolomide. Animals were untreated, given temozolomide alone

(lOOmg/kg. i.p.) or B.4280 alone (20mg/kg, i.p.) or B.4280 (1, 5, 10 or 20 mg/kg, i.p.) followed 1 hour later by temozolomide (lOOmg/kg, i.p.) on five consecutive days. Tumour growth was monitored as described. The data from a number of separate studies are presented.

Figure 15B is a graph showing the survival of the animals (tumour-bearing nude mice) used in the study shown in Figure 15A. Groups of animals in which the xenografts had reached the maximum size were terminated.

Figure 16A is a graph of % tumour growth against time (days) showing the comparison of the effect of B.4280 given i.p. and orally (p.o.) on the sensitivity of human melanoma xenografts to growth inhibition by temozolomide. Animals were untreated, given temozolomide alone (lOOmg/kg) or B.4280 alone (20mg/kg, i.p.) or B.4280 (20mg/kg, i.p.) or B.4280 (30mg/kg, p.o.) followed 1 hour later by temozolomide (lOOmg/kg, i.p.) on five consecutive days.

Tumour growth was monitored as described. The data from a number of separate studies are presented.

Figure 16B is a graph showing the survival of the animals used in the study shown in Figure 16A. Groups of animals in which the xenografts had reached the maximum size were terminated.

Figure 17 is a graph showing the survival of animals in a comparative test of the effects of BeG, B.4205 and B.4280 in combination with temozolomide (TZ) in non-tumour-bearing DBA- mice. Animals were given temozolomide alone (lOOmg/kg i.p) or BeG (10 or 20mg/kg i.p.), B.4205 (10 or 20 mg/kg i.p.) or B.4280 (10 or 20 mg/kg i.p.) followed one hour later by temozolomide (lOOmg/kg i.p.) on five consecutive days.

Figures 18 to 21 consist of pairs of graphs showing the kinetics of ATase depletion and recovery in various tumours and murine host tissues after administration of B.4280 at the doses indicated. The graphs plot ATase activity (fm/mg protein) and % of control ATase activity against time (hours):

Figure 18 relates to B.4280 (20 mg/kg i.p.) in A375M tumours and other tissues.

Figure 19 relates to B.4280 (30mg/kg p.o.) in A375M tumours and other tissues

Figure 20 relates to B.4280 (30mg/kg i.p.) in MCF-7 tumours and other tissues.

Figure 21 relates to B.4280 (20mg/kg i.p.) in DU-145 tumours and other tissues.

Figure 22 is a graph of % tumour growth against time (days) showing the effect of B.4280 on the sensitivity of MCF-7 tumours to growth inhibition by temozolomide. Animals were untreated, were

given temozolomide alone (100 mg/kg, i.p.) or B.4280 (PaTrin-2) (20mg/kg i.p.) alone, or B.4280 (20mg/kg i.p.) followed 1 hour later by temozolomide (lOOmg/kg i.p.) on five consecutive days.

Figure 23 consists of graphs of % tumour growth, number of surviving mice and mean weight (g) against time (days) showing the effect of a single dose of B.4280 (PaTrin-2) on the sensitivity of melanoma tumours to growth inhibition by a single dose of fotemustine. Animals were given fotemustine (20mg/kg i.p.) alone, or B.4280 (30mg/kg p.o) followed 1 hour later by fotemustine (20mg/kg i.p.).

Figure 24 consists of graphs of % tumour growth and number of surviving mice against time (days) for sensitization of A375M tumours with B.4205 (PaTrin-1) and B.4280 20mg/kg pretreatment followed by 150mg/kg temozolomide using a 5 day schedule as for Figure 22.

Figure 25 consists of graphs of % tumour growth, number of surviving mice and mean weight (g) against time showing sensitization of A375M tumours to temozolomide (lOOmg/kg i.p.) following administration of 20mg/kg B.4349 or B.4351 (i.p.).

Figure 26 is a figure showing ATase activities in A375M tumours and murine host tissues at 2 hours and 24 hours following i.p. administration of 90mg/kg B.4335.

In the specification the abbreviations "lh" or "2h" etc. mean "1 hour", "2 hours" etc.. In the drawings the abbreviations "Temo" and "Tz" refer to temozolomide.

Figure 27 consists of graphs of % tumour growth and weight (% of day 1 value) against time (days) showing tumour DU-145 prostate xenograft growth after temozolomide (lOOmg/kg/day) and/or B.4280 (PaTrin-2) (20mg/kg/day) days 1-5. Points are the means of values from at least 4 mice. Growth delays in each group were (p value):

PaTrin-2 alone 0.1 days (>.05); temozolomide alone 7.8 (>.05). Both agents 15.3 (0238).

Figure 28 is a reaction scheme for synthesis of H]-(4-bromothenyl)guanine.

Figure 29 shows of authentic B.4280 and readioactivity in the -(4-bromothenyl)guanine synthesis. Shading indicates counts recovered (LH axis) and the line OD at 254nm (RH axis).

Figure 30 shows transfer of radioactivity from 0 -[ H]-(4-bromothenyl)guanine to rhATase after one hour incubation at 37°C.

Description of the Preferred Embodiments

Examples of compounds of the invention are shown in Tables la and lb. They were synthesized by the procedures presented below, adapted as appropriate.

Type 1 A. 0 -Substituted hypoxanthines were made by the action of alkoxide RCH ₂ 0Na on the quaternary salt ϋ.j ,N-trimethyl-lH-purin-6-aminium chloride.

B. 0 -Substituted 2-methylhypoxanthines were made similarly, from the quaternary salt from diazabicyclooctane (DABC0) and

2 6-chloro-2-methy1purine.

C. Q -Substituted 2-fluorohypoxanthines were made by diazotisation of the corresponding guanines using sodium nitrite and concentrated fluoboric acid at -25°C.

D. 0 -Substituted 9-(2-hydroxyethoxymethyl)guanines were made by condensing the corresponding guanines after silylation with 2-acetoxyethoxymethyl bromide in the presence of mercuric cyanide followed by saponification of the Q-acetyl group.

E. 0 -Substituted 8-hydroxyguanines were made from

6-hetarylmethyl-2,4,5-triaminopyrimidines and 1,

5 1-carbonyldiimidazole in DMF. Reaction of 6-cnloro-2,4-diaminopyrimidine with alkoxide in DMSO, followed by nitrosation with sodium nitrite in aqueous acetic acid and reduction using sodium hydrosulphite in aqueous DMF, gave the

2, 4, 5-triamines.

Type 2

A. 0 -Substituted 8-azaguanines were made from the above triamines and sodium nitrite in aqueous acetic acid.

B. 0 -Substituted 8-aza-7-deazaguanines were made from the alkoxide RCH-ONa and 2-amino-6-chloro-8-aza-7-deazapurine in sulfolane or from the DABCO quaternary salt (in DMSO solvent) derived from it.

Type 3

A. 0 -Substituted 8-oxaguanines were made by lead tetraacetate oxidation of 6-hetarylmethyl-2,4-diamino-5-nitrosopyrimidines obtained as under Type IE.

B. 0 -Substituted 8-thiaguanines were made from the triamine intermediates under Type IE and N-tosylthionylimine in g pyridine.

C. 0 -Substituted pterins were made from these triamines and glyoxal with sodium metabisulphite.

Type 4

A and B. These pyrimidines were obtained as under Type IE.

C. Q -Substituted 2,4-diamino-5-nitropyrimidines were made by the action of alkoxide RCH _? 0Na in DMSO on 6-chloro-2,4-diamino -5-nitropyrimidine.

Type 5

S -Substituted 6-thioguanines were prepared from the thiolate RQ SNa and the quaternary salt 2-amino-N,ϋ,N-trimethyl-l H-purin-6-aminium chloride (WO 94/29312).

0 -Substituted guanines as listed in Tables 6a and 6b were made by the standard preparation as described in WO 94/29312, usually with 3mmol alcohol RCH _? 0H per mmol quaternary salt.

The alcohols were made as described in WO 94/29312 by sodium borohydride reduction of the corresponding aldehydes, with two

12 exceptions. For 4-bromothenyl alcohol required for B.4280 thl€e aldehyde is commercially available. 5-Chlorothiophen-2-aldehyde .13

14 and 5-methylthiothiophen-2-aldehyde were prepared by Vilsmeier reaction on 2-chlorothiophen and 2-methylthiothiophen respectively.

Sodium borohydride reduction of the methylthioaldehyde followed by

15 sodium peπodate oxidation of the resulting methylthioalcohol yielded the methylsulphinylalcohol required for B.4294. Reduction of the chloroaldehyde gave 5-chlorothenyl alcohol for B.4281.

Several other aldehydes were obtained by halogenation of the appropriate thiophen aldehyde or furfural. Thus, direct bromination

17 1ft gave 5-bromofurfural and thence the alcohol for B.4336.

Halogen in presence of aluminium chloride on thiophen-2-aldehyde

19 yielded 4-chlorothiophen-2-aldehyde (for the alcohol for

B.4298), on thiophen-3-aldehyde yielded

20 2-bromothiophen-4-aldehyde (and eventually B.4313), and on

5-chlorothiophen-2-aldehyde yielded 4,5-dichlorothiophen-2-aldehyde (for the alcohol for B.4318).

Cyanoaldehydes were obtained from copper cyanide and the corresponding bromoaldehydes in refluxing dimethylformamide.

23 24

5-Cyanothiophen-2-aldehyde and its 4-cyano isomer then gave

25 the 5-cyano and 4-cyano alcohols, for B.4283 and B.4317 respectively.

fι

4-Methoxythenyl alcohol (for B.4300) was prepared as described from 2,3-dibromosuccinic acid and methyl thioglycollate, and ultimate reduction of the methyl ester (not aldehyde in this case) by lithium aluminium hydride and 2-chloro-4-picolyl

27 28 alcohol (for B.4321) by sodium borohydride reduction of the

29 corresponding acid chloride, made in turn from reaction of phosphorus oxychloride/pentachloride on isonicotinic acid N-oxide.

For B.4282, 3-pyridinemethanol N-oxide is commercially available. 5-Methylsulphonylthenyl alcohol (for B.4309) was obtained by m-chloroperbenzoic acid (MCPBA) oxidation of the alcohol resulting from reduction of 5-methylthio-2-thiophenecarboxaldehyde 30

6-Chloro-3-pyridinemethanol (for B.4319) and 5-bromo-3-pyridinemethanol (for B.4320) were made by treatment of 6-chloro and 5-bromonicotinic acids respectively with phosphorus oxychloride/pentachloride and reduction of the resulting acid

28 chlorides with sodium borohydride . Isothiazole-4-methanol (for

B.4354) was obtained by reduction of the corresponding methyl ester

(A. Adams and R. Slack, J. Chem. Soc. 1959, 3061) with lithium aluminium hydride (M. Hatanaka and T. Ishimaru, J. Med. Chem. 16, 1973, 978).

4-bromo-2-thiophenecarboxaldehyde was converted into the

4-lithio derivative (A.L. Johnson, J. Org. Chem. 41, 1976, 1320) of its ethylene acetal and reaction of this organometallic with dimethyl disulphide followed by acid hydrolysis gave 4-methylthio-2-thiophenecarboxaldehyde (R. Noto, L. Lamartina, C. Arnone and D. Spinel1 , J. Chem. Soc, Perkin Trans. 2, 1987, 689). Sodium borohydride reduced this aldehyde to the 4-methylthio alcohol (for B.4356), which in turn with one of two equivalents of MCPBA yielded the 4-methylsulphinyl and 4-methylsulphonyl alcohols (for B.4377 and B.4361 respectively). Reaction of the above organometallic with naphthalene-2-sulphonyl azide (A.B. Khare and CE. McKenna, Synthesis. 1991, 405) and sodium pyrophosphate followed by hydrolysis by the method (P. Spagnolo and P. Zanirato, J. Org. Chem.. 43, 1978, 3539) for the preparation of other azidothiophene aldehydes gave 4-azido-2-thiophenecarboxaldehyde leading to the alcohol for B.4373.

5-Iodo-3-thiophenemethanol (for B.4357) came from the aldehyde obtained by treatment of 3-thiophenecarboxaldehyde with iodine-iodic acid-sulphuric acid (R. Guilard, P. Fournari and M. Person, Bull . Soc. Chim. France, 1967, 4121).

2-Naphtho[2, l-b]thienylmethanol (for B.4366) was prepared by lithium aluminium hydride reduction of the corresponding carboxylic acid (M.L. Tedjamulia, Y. Tominaga, R.N. Castle and M.L. Lee, A_

Heterocvcl. Chem., 20, 1983, 1143). 5-Phenylthenyl alcohol (m.p.

91.5°C, for B.4378) resulted from sodium borohydride reduction of the aldehyde (P. Demerseman, J .P. Buu-Hoi and R. Royer, J. Chem.

Soc.. 1954, 4193) obtained by Vilsmeier reaction of 2-phenylthiophene (from Gomberg-Bachmann reaction (N.P. Buu-Hoi and

N. Hoan, Ree. trav. chim.. 69, 1950, 1455) of benzenediazonium chloride and alkali with thiophene).

By way of specific example, the preparation of 0 -(4-bromothenyl)guanine (B.4280) will now be described.

Preparation of 0 -(4-bromothenyl)guanine

12 A solution of 4-bromothenyl alcohol [4.63g, 24mmol; R _f 0.38 in

TLC(PhMe-Me0H, 4:1)] in DMSO (4ml) was treated cautiously with sodium hydride (60% in oil; 0.64g, 16mmol). After 1 hour's stirring, 2-amino-ϋ,ϋ,j-trimethyl-lii-purin-6-aminium chloride (1.83g, 8mmol) was added. After 1 hour's further stirring, acetic acid (1.3ml) followed by ether (240ml) was added and the solid filtered off after l-2h. Removal of solvents and excess of alcohol (b.p. 85-90°C/0.4mm) from the filtrate yielded a negligible second fraction (17mg). The main crop was triturated with water (10ml), affording substantially pure product (1.89g, 73%) with R _f 0.22 in TLC (PhMe-MeOH, 4:1). It was recrystal 1 ized by dissolving in hot methanol (100ml) and then concentrating. Analytical data are given in Tables 6a and 6b, together with data for other compounds. Other typical synthetic procedures are described by way of example in a special section later in this text.

Compounds of formula II or XIII in which Y' is R"XCHR" ' and R ¹¹¹ is alkyl (seco-nucleosides) may be prepared by an analogous preparation to the reaction of 0 -benzylguanine with -chloro-ethers (MacCoss et aj.. , Tetrahedron Lett.; European Patent Application No. 184,473., loc. cit.) or with alkyl bromides (e.g. Kjellberg, Liljenberg and Johansson, Tetrahedron Lett.. 1986, 27, 877; Moschel, McDougall, Dolan, Stine, and Pegg, J.Med. Chem.. 1992, 35, 4486).

Typical "sugar" components corresponding to R^XCHR ¹ '', leading to seco-nucleosides, are made by methods described in e.g. McCor ick and McElhinney, J. Chem. Soc. Perkin Trans. l _f 1985, 93; Lucey, McCormick and McElhinney, J. Chem. Soc. Perkin Trans. 1, 1990, 795.

Compounds of formula II or XIII in which Y is ribosyl or deoxyribosyl (nucleosides) may be prepared by methods analogous to the syntheses of 0 -benzylguanine riboside and 2-deoxyriboside (Moschel et al. 1992; cf. Gao, Fathi, Gaffney et a _. , J. Orα. Chem..

1992, 57, 6954; Moschel, Hudgins and Dipple, J. A er. Chem. Soc.. 1981, 103, 5489) (see preparation of Ribosides above).

Industrial Applicability

The amount of the compound of the present invention to be used varies according to the effective amount required for treating tumour cells. A suitable dosage is that which will result in a concentration of the compound of the invention in the tumor cells to be treated which results in the depletion of ATase activity, e.g. about 1 - 2000 mg/kg body weight, and preferably 1 - 800 mg/kg body weight, particularly 1-120 mg/kg body weight, prior to chemotherapy with an appropriate alkylating agent.

The pharmaceutical composition of the invention may be formulated in conventional forms with conventional excipients, as described for example in W0 91/13898 and W096/04281 and U.S. Patents 5,091,430 and 5,352,669, the contents of which are incorporated herein by reference in their entirety. The composition may contain the inactivator according to the invention together with an appropriate alkylating agent; or the composition may comprise two parts, one containing the inactivator and the other containing the alkylating agent. The method of administering the compounds of theinvention to a host may also be a conventional method, as described in W0 91/13898 for example. For administration of an inactivator according to the invention to patients, the pharmaceutical composition may suitably contain the inactivator in a suitable vehicle such as 40% polyethyleneglycol 400 in saline solution, or in saline or 3% ethanol (in saline), for intravenous injection, or in a powder form in suitable capsules for oral administration.

Alkylating agents may be administered in accordance with known techniques and in conventional forms of administration, as described in W0 91/13898 for example or preferably as a single dose immediately after or up to 24 hours after but preferably around 2

hours after administration of the ATase inactivating agents and also at doses lower than those used in standard treatment regimen. A reduction in dose may be necessary because the inactivators would generally be anticipated to increase the toxicity of the alkylating agents. Examples of chloroethylating agents include 1,3 bis (2-chloroethyl)-l-nitrosourea (BCNU) , l-(2-chloroethyl)-3-cyclohexyl-l-nitrosourea (CCNU) , fotemustine, mitozolomide and clo esone and those described in McCormick, McElhinney, McMurry and Maxwell J. Chem. Soc. Perkin Trans. I. 1991, 877 and Bibby, Double, McCormick, McElhinney, Radacic, Pratesi and Dumont Anti-Cancer Drug Design. 1993, 8, 115. Examples of ethylating agents include temozolomide (British Patent GB 2 104, 522 and U.S. Patent 5,260,291 the contents of which are incorporated herein in their entirety) and dacarbazine, procarbazine, and streptozocin.

Methods

0 -alkylguanine-DNA-alkyltransferase assay

Varying amounts of recombinant ATase or cell/tissue extracts were incubated with [ H]-methylnitrosourea-methylated calf thymus

DNA (specific activity, 17Ci/mmol) at 37°C for 1 hour in a total volume of 30Q*xl buffer I/[50mM Tris/HCl (pH8.3), 3mM dithiothreitol

(DTT) , ImM EDTA] containing lmg/ l bovine serum albumin (IBSA) for recombinant ATases and tissue extracts, or 1.1ml buffer I for cell extracts. After incubation, bovine serum albumin (100 l of lOmg/ml in buffer I) and perchloric acid (lOOil of 4M perchloric acid for 30 ul volumes and 400/ιl for 1.1ml volumes) and 2ml of IM perchloric acid were added. Samples were then heated at 75 C for 50 minutes to hydrolyze the DNA. Samples were then centrifuged at 3,000rpm for

10 minutes and the precipitate washed once with 4ml of IM perchloric acid, before being resuspended in 30011 of 0.01M sodium hydroxide and dissolved in 3ml of aqueous scintillation fluid (Ecoscint A,

National Diagnostics). Counting efficiency was approximately 30%.

ATase specific activity was calculated from the region where the

activity was proportional to the amount of extract added, since with higher amounts of extracts the reaction becomes substrate limiting. ATase activity is expressed as f ol methyl transferred to protein per mg of total protein in the extract.

Method of Purification of Recombinant ATases

The cDNA cloning and overexpression of the human ATase has

30 been reported previously . Purification of the recombinant proteins was achieved either by affinity chromatography through a

31 32 DNA-cellulose column as described by Wilkinson ejt a_L , ' , or by DEAE-cellulose ion-exchange chromatography. For the latter, the

ATase protein was partially purified by ammonium sulphate precipitation (30 - 60%) and dialyzed against 10 M Tris-HCl pH 7.5, 1 M DTT, 2 mM EDTA, 10% glycerol, before loading on a DEAE-cellulose column. The ATase was then eluted with a 0-0.1 M NaCl gradient. The purified human ATase protein retained activity for more than one year when stored at high concentration at -20°C in buffer I [50 mM-Tris/HCl (pH 8.3)/3 mM-dithiothreitol/1 mM-EDTA] and could be thawed and refrozen several times without substantial loss of activity.

Incubation with Inactivators and ATase assay

Compounds to be tested were dissolved in DMSO to a final concentration of 10 mM and diluted just before use in buffer I . Recombinant ATase was diluted in buffer I containing 1 mg/ml bovine serum albumin (IBSA) and titrated as described above in order that the reaction be conducted under ATase, and not substrate, limiting conditions. In each assay, fixed amounts of ATase (60-75 fmol) were incubated with varying amounts of 0 -benzylguanine, or test compound in a total volume of 200^1 of IBSA containing lO^ug of calf thymus DNA at 37°C for 1 hour. The [ ³ H]-methylated-DNA substrate (100,ΛI1 containing 4 ug of DNA and 100 fmol of

0 -methylguanine) was then added and incubation continued at 37° for 1 hour, until the reaction was complete. Following acid

3 hydrolysis of the DNA as described above the [ H]-methylated protein was recovered and quantitated by liquid scintillation counting. I _™ is the concentration of inactivator required to produce a 50% reduction in ATase activity under the above conditions.

Cell Culture and preparation of extracts

Mammalian cells including Raji cells (a human lymphoblastoid cell line from a Burkitt's lymphoma) , A375M cells (human melanoma cells), MCF-7 cells (human breast cancer cells) and PC3 and DU145 (both human prostate cancer cells) were cultured under standard conditions. For example, Raji cells were grown in suspension culture in RPMI medium supplemented with 10% horse serum. Cell pellets were resuspended in cold (4 C) buffer I containing 2 ug/ml leupeptin and sonicated for 10 seconds at lZ im peak to peak distance. After cooling in ice, the cells were sonicated for a further 10 seconds at lδ um. Immediately after sonication, lOxil/ml of phenylmethanesulphonylfluoride (PMSF 8.7 mg/ml in 100% ethanol) was added and the sonicates centrifuged at 15 OOOcp for 10 minutes at 4°C to pellet cell debris. The supernatant was transferred to a tube on ice and kept for determination of ATase activity (see above).

Stability of Inactivators at 37°C by Spectrophotometry.

Inactivators (lOmM in DMSO) were diluted to O.lmM in prewarmed degassed PBS (pH 7-7.2). PBS (Phosphate buffered saline) is 0.8% NaCl, 0.02% KC1, 0.15% Na ₂ H ₂ P0 ₄ , 0.02% KH ₂ P0 ₄ - Samples were immediately transferred to a CARY13 spectrophotometer (cuvette block held at 37°C) and scanned at an appropriate wavelength (according to the spectral properties of the compound) at 5-10 minute intervals for up to 80 hours. The results were expressed as percentage absorbance change versus time and Tl/2 values (half life) extrapolated from this. In the tables the results of these tests are identified by "in PBS" or "by Spec".

Stability of Inactivators by ATase Assay

Inactivators (10ιM in DMSO) were diluted to the appropriate concentration (I _qn calculated from previous I determination

data) in buffer I without DTT and incubated for varying times at 37°C. Samples were then taken for use in the competition assay to assess the compound's ability to inactivate human ATase. The results were expressed as reduction in inactivating activity versus time and T 1/2 values extrapolated from this.

Inactivation of ATase activity in Raji cells.

5 6 Raji cells were diluted to between 5 x 10 /ml and 10 /ml in medium containing either the appropriate concentration of inactivator or an equivalent volume of vehicle (DMSO). Following incubation at 37 C for 2 hours the cells were harvested by centrifugation, washed twice with PBS and the resulting cell pellets (between 5 x 10 and 10 cells per pellet) stored at -20°C. ATase activity was determined as described above, in duplicate cell extracts and expressed as the percentage activity remaining, based on that present in the untreated controls (350-450 fm/mg depending on the assay). I _™ (i.e concentration of inactivator required to reduce ATase activity by 50%) values were extrapolated from this data.

Sensitization of Mammalian cells to Cytotoxic Agents.

Sensitization of mammalian cells to the cytotoxic effects of BCNU, temozolomide and other cytotoxic agents following a 2 hour pretreatment with inactivator was analysed using an XTT-based growth

22 inhibition assay . Cells were plated in 96 well plates (for example in the case of Raji cells at 500 cells/well) and incubated at 37°C for 30 minutes prior to the addition of medium containing either the appropriate concentration of inactivator or an equivalent volume of vehicle. Following a 2 hour incubation at 37°C, medium containing either increasing doses of cytotoxic agent or equivalent vehicle was added and the cells allowed to grow for 6 days. At this time XTT solution was added and the cells incubated for a further 4 hours at 37°C. The resulting red/orange formazan reaction product was quantified by measuring absorption at 450nm on a microtitre platereader.

From this data the percentage growth of cells relative to that in control wells was determined for a range of BCNU, temozolomide or other cytotoxic agent doses in both the presence and absence of inactivator. Sensitization factor (SF) based on D _™ (Dr ₀ . Den- ) ^as determined by dividing the D _™ (i.e. dose at which there was 50% growth versus the controls untreated with alkylating agent) calculated for the cytotoxic agent alone r

(Dr _n . ) by that for the cytotoxic agent plus inactivator (Dr _n . )* ^A value of one (1) thus indicates no sensitization by the inactivator. Comparable Sensitization factors were also determined in some cases based on D _™ and D , i.e. the dose at which there was respectively 60% or 80% growth compared to the untreated controls. In Table 3 the Sensitization Factor

C I Dr .. /Dr . is shown as D _™ control / D _™ 'B', with the letter 'B' referring to the inactivator compound.

Xenograft Studies

Animals

Swiss mouse derived athymic male mice (o/nu) weighing between 20-30g were obtained from ZENECA Pharmaceuticals, Alderley Park, Macclesfield, Cheshire, SK10 4T6, England. Animals were housed 4-5/cage in filter top cages and had access to food and water ad l ibitum. All animals were maintained under a controlled

12h-light-12h-dark cycle. These animals were used for all tests except those which are shown in Figures 11 and 17 and Table 8, as mentioned below.

Cells

A375M (human melanoma) and DU145 (human prostate cancer) cells were grown in DMEM containing 10% foetal bovine serum (FBS). MCF-7 (human breast cancer cells) were grown in DMEM containing 10% FBS supplemented with lOOiu insulin.

Tumours

A375M, DU145 and MCF-7 cells (10 ⁶ ) in lOOul PBS were

injected subcutaneously into the right-hand flank of 8-10 week old o/nu athymic mice. These cells were allowed to develop into a tumour for 3-4 weeks (A375M and DU145 cells) and 4-6 weeks (MCF-7 cells). Once established, tumours were maintained by subcutaneous implantation of 2mm blocks into the right-hand flank of athymic o/nu mice. MCF-7 tumours are oestrogen postive and require oestrogen for growth. This was supplied as a subcutaneous implant

(see below) at the tail base simultaneously to the tumour implant and monthly thereafter.

Preparation of Oestrogen Pellets

468mg -oestradiol was added to 9.7g silastic and mixed until evenly distributed, l.lg of curing agent was added and the whole mixture spread into 3 (26mm x 12mm x 1mm) glass fomers. These were then incubated at 42 C overnight before being cut into 2mm x 2mm x lmm cubes, so that each pellet contained 2mg estradiol.

ATase Depletion Experiments Tumours were implanted as previously described and left 3-6 weeks to establish depending on tumour type. An inactivator was homogenized in corn oil at 5mg/ml before administration by interperitoneal injection (i.p.) or oral gavage (p.o.). Mice were sacrificed at various times up to 72h and tumours and murine tissues taken for ATase assay. Samples were snap frozen and stored at -20 C until analysis.

Tumour Sensitization Experiments

0/nu mice were treated with the appropriate dose of the inactivator as indicated (4mg/ml in corn oil) or the appropriate vehicle as a control 1 hour prior to administration of the appropriate dose of the cytotoxic agent (e.g.temozolomide 6mg/ml in PBS + 20% DMSO) or fotemustine or BCNU (2mg/ml in PBS + 3% ethanol) using the doses and schedules indicated.

Tumour Measurements

Animals were weighed twice weekly and xenograft tumour

measurements taken using digital calipers. Tumour volume was calculated using the formula (h x w x l)t /6. Measurements continued until the tumour reached the maximum allowable volume (i.e. 1cm ), Results were expressed as percentage tumour growth using day 1 tumour volumes as controls.

In the tests on the compounds shown in Table 6 and in Figures 9 to 17, the Methods used were as described in WO 94/29312. The following items a) to c) are also to be noted:

a) Standard ATase assay

ATase substrate DNA was prepared by incubation of purified

3 calf thymus DNA with N-[ H]-methyl-N-πitrosourea (18.7 Ci/mmole, Amersham International). Cell or tissue extracts were incubated with [ H]-methylated-DNA substrate (lOOul containing 6.7jg of DNA and lOOfmol of 0 ⁶ -[ ³ H]methylguanine) at 37°C for 60 mins..

33 Following acid hydrolysis of the DNA as previously described the 3 [ H]-methylated protein was recovered and quantitated by liquid scintillation counting.

b) Drug Treatment

Mice were treated with the inactivator as a suspension in corn oil by intraperitoneal injection (i.p.) or by oral gavage (p.o.) 60 mins prior to temozolomide (lOOmg/kg in 20%DMS0 in phosphate-buffered saline) which was always given by intraperitoneal injection: this schedule was repeated on days 1 to 5 inclusive. Controls received vehicle alone, inactivator alone or temozolomide alone.

c) Animals

The mice in the tests shown in Figure 11 and Table 8 were BALB-C derived athymic male mice (nu/nu athymic) from the in-house breeding colony of the Paterson Institute for Cancer Research as described in W0 94/29312 (Animal Services Unit-ASU Mice).

The mice in the tests shown in Figures 12-16 were Swiss mouse derived athymic male mice (o/nu athymic) as described above.

The mice in the tests shown in Figure 17 were DBA,, mice from the in-house breeding colony of the Paterson Institute for Cancer Research (Animal Services Unit), originally from the Jackson Laboratory in 1970.

Test Results

The results of the ATase depletion assay on the compounds of Table 1 are shown in Table 2 or Table 3. Many of the compounds tested were more efficient in inactivating ATase than 0 -benzylguanine. In accordance with the results in WO 94/29312 the parent application, compounds in which R is a heterocyclic group were more efficient than the comparable compounds having benzyloxy side chains. In general the compounds in which RCH _? is substituted or unsubstituted thenyl were the most efficient, the most preferred being halo- substituted thenyl having its halo substituent in a 1,3-relationship with the methyleneoxy group attached to the pyrimidine residue.

Tables 3, 4 and 5 summarize data for a number of parameters. Table 3 includes depletion assay results for recombinant ATase of the following types:

The combinations of properties for the various inactivators can be seen in the tables. The following surprising points are noted in particular:

B.4316 is a compound of surprisingly high water solubility.

B.4335 is a compound that is unexpectedly much more effective in the inactivation of ATase in Raji cells than of pure recombinant protein: generally, the I _fi for inactivation of recombinant ATase in vitro is lower or similar to that in cultured cells.

B.4343 is a compound that has a very low I for ATase in vitro but is not as capable as agents with higher I _rn s (e.g. B.4335) in the sensitization of Raji cells to the growth inhibitory effects of temozolomide. A similar example is

B.4351 versus B.4349.

B.4316 was twice as effective as B.4280 but sensitization to temozolomide of Raji cells was almost identical. Thus different cell lines may respond surprisingly differently to these agents.

Figures 1 to 3 show that temozolomide, BCNU and fotemustine inhibit the growth of Raji cells in a dose-dependent manner but sensitivity is greatly increased by exposure to B.4316 at 0.1, 1.0 and lOtiM respectively. In contrast B.4316 had no measurable effect on growth inhibition of Raji cells by melphalan or cisplatin (Fig.

4). This indicates that the inactivators were specifically sseennssiittiizziinngg cceellllss ttoo tthhee 00 --aallkylating agents and not other classes of alkylating compound

Figures 5 and 6 respectively show the B.4316 and B.4349 sensitization factors for the above therapeutic agents in Raji cells,

Figure 7 shows that of the inactivators examined human melanoma xenograft ATase depletion was complete only after administration of B.4314 and B.4351 under the experimental conditions used. The former was more effective in ATase depletion in liver and kidney of host animals whilst the latter was more effective in the brain, suggesting its relative ease in passing the blood-brain barrier. Noteworthy is the fact that whilst B.4311 was one of the most effective agents in sensitizing Raji cells to the

toxic effects of temozolomide, it was surprisingly one of the least effective agents in depleting mouse tissue or tumour xenograft ATase activity.

Figure 8 shows that B.4363 depletes ATase more effectively in human melanoma xenografts than in murine host tissues under the conditions used: relatively little effect was seen in brain tissue, suggesting its poor ability to cross the blood brain barrier.

The test results for the compounds of Table 6 (and some in Table 1) are shown in Table 7 and Figures 9 to 27.

B.4280, which is 0 -(4-bromothenyl)guanine and has its bromo substituent in a 1, 3-relationship with the methylene group attached to the guanine residue, was more efficient in inactivating ATase in vitro than its 5-bromo analogue B.4269, in which the bromo substituent is in a 1, 4-relationship with the methylene group. Both B.4280 and B.4269 were more efficient than the unsubstituted thenyl derivative B.4205 despite having considerably larger 0 substituents.

Another preferred compound is B.4317 which is 0 -(4-cyanothenyl)guanine. B.4317 is a more efficient inactivator in vitro than its 5-cyano analogue B.4283 or the unsubstituted thenyl derivative B.4205.

Typical ATase inactivation profiles for BeG and B.4205 and B.4280 are shown in Fig. 9.

The inactivation of ATase resulted in the sensitization of Raji cells to the growth inhibitory effects of temozolomide (Fig. 10). B.4280 was considerably more effective than either B.4205 or BeG in this respect.

ATase in human melanoma xenografts was inactivated by BeG, B.4205 and B.4280 (Fig. 11) with some indication that the rates of

recovery of ATase activity were different between the agents. B.4280 was the most effective in vivo inactivator at the doses examined.

B.4280 was able to inactivate ATase in most tissues as shown in Table 8. Thus, activity in brain, testis and bone marrow was near to control levels by 24 hours whereas lung and spleen activity had not completely recovered by 48 hours. Tumour activity was very low at 24 hours but had recovered completely by 48 hours.

Differential recovery rates might be an important factor in the toxicity of ATase inactivators when used in combination with CNU or temozolomide.

Combinations of B.4205 or B.4280 and temozolomide given over three days were more effective in ATase inactivation in tumour xenografts than either agent alone (Fig. 12). Decreasing the dose of B.4205 had no major effect on the ability of the agent to inactivate ATase, lO g/kg being as effective as 60mg/kg. B.4280 was more effective than B.4205 at equivalent doses. As before (Fig. 11) there was some indication that ATase recovery was less efficient in the tumour xenograft (Fig. 12) than in the liver (Fig. 13).

B.4205 (Fig. 14A) and B.4280 (Fig. 15A) were effective in sensitizing human melanoma xenografts to the growth inhibitory effects of temozolomide. A comparison of the two sets of data indicates that B.4280 was about twice as effective as B.4205 in this respect. At equi-effective doses for tumour growth inhibition, B.4280 seems to be less toxic than B.4205 (Figs. 14B and 15B) .

In experiments using DBA ₂ mice in combination with BCNU, B.4280 was considerably less acutely toxic than B.4205 or BeG as shown in Table 9. Oral administration of B.4280 was shown to be almost as effective as i.p. administration in sensitizing human melanoma xenografts to the growth inhibitory effects of temozolomide (Fig. 16A) . Furthermore the oral combination appeared to be marginally less toxic than the i.p. route (Fig. 16B) .

At a dose of 20mg/kg of inactivator in combination with temozolomide in DBA _? mice, B.4205 and B.4280 were shown to be less acutely toxic than BeG, with B.4280 being less acutely toxic than B.4205 (Fig. 17).

Figures 18 and 19 show that B.4280 (PaTrin-2) (i.p. at 20 mg/kg and p.o at 30mg/kg respectively) depletes ATase in human melanoma xenografts more completely and for a more extensive period than it does in host tissues.

Figure 20 show that despite the considerably higher initial level of ATase activity in the human breast tumour, B.4280 depletes ATase therein more completely and for a longer period of time than in murine host tissues. In this study using 30mg/kg B.4280 i.p. extensive depletion was seen in brain tissue, indicating the ability to cross the blood-brain barrier.

Figure 21 likewise shows that despite the considerably higher initial level of ATase activity in the human prostate tumour, B.4280 depletes ATase therein more completely and for a longer period of time than in murine host tissues. In this study using 20mg/kg

B.4280 i.p. relatively little depletion was seen in brain tissue, indicating by reference to Figure 20 that the ability of B.4280 to cross the blood-brain barrier may be dose-dependent.

Figure 22 shows that B.4280 (20mg/kg i.p.) considerably increased the sensitivity of the human breast tumour xenograft to the growth inhibitory effects of temozolomide using a 5 day dosing schedule. This sensitization occurred despite the very high level of ATase in this tumour.

Figure 23 shows that a single dose of B.4280 (30mg/kg p.o.) considerably increased the sensitivity of the human melanoma tumour xenograft to the growth inhibitory effects of a single dose of the chloroethylating agent, fotemustine, without any substantial effect on toxicity.

fi "

Synthesis of 0 -(methylene[ H])-(4-bromothenyl)guanine

Bro othenylaldehyde (0.79mg, 66.8 u oles was reacted with NaB[ ³ H) ₄ (0.0167 mmoles, 60Ci/mmole) in isopropanol (350ul) for lh at room temperature. The resulting [ H]-4-bromothenylalcohol was extracted into pentane, dried, weighed and reacted with NaH

(5.44mgl, and the quaternary ammonium salt of guanine (15.55mg) in

DMSO (250p ) for 1 hour at room temperature. The product was recovered by precipitation from acetic acid-ether (15ul glacial acetic in 1.5ml ether), washed with ether, dried and triturated with

H _? 0. After washing with water, the final product was dried to constant weight. Figure 28 shows the scheme for synthesis of the radio-labelled B.4280.

High performance liquid chromatography analysis

An aliquot of the product was dissolved in buffer A ( lO M KH-PO. containing 7.5% acetonitrile) and subjected to high performance liquid chromatography on an ODS-5 column. Elution at lml/min was with a linear gradient over 20 minutes from 100% A to 20% A:80% B (lOmM KILPO, containing 80% acetonitrile). The effluent was monitored for UV absorption at 254nm and fractions (1

min) were collected and assayed for radioactivity after addiition of 10ml of Ecoscint A. It was shown that 96% of the radio activity co-chromatographed with authentic B.4280 (Figure 29).

Incubation of an aliquot of the product with known amounts of pure recombinant human ATase resulted in the transfer of radioactivity to the protein (Figure 30), strongly suggesting that the mechanism of ATase inactivation involves the transfer of the thenyl group to the active site cysteine residue in the ATase molecule. Measurement of the amount of radioactivity transferred to protein indicated that the 0 -([ H]-4-bromothenyl)guanine had a radiochemical purity of >96% and a specific activity of 16Ci/mmole.

an alternative to H]-labelled substrate

DNA, to determine the amounts of ATase, for example, in cell or tissue extracts. It may also be used to locate active ATase molecules in tumour and other tissue sections by incubation with such sections on microscope slides followed by washing, autoradiography and histological staining. It may also be used to monitor the formation of the [ H]-labelled products of breakdown or metabolism of the agent after administration to mammals. It may also be used to determine the distribution of the B.4280 or its breakdown products in animal tissues and tumours by means of whole body autoradiography.

Typical synthetic procedures

Type I A.

0 ⁶ -(4-Bromothenyl)hypoxanthine, B. 4292

4-Bromothenyl alcohol (1.16 g, 6 mmol) was added to sodium hydride (60% in oil ; 0.16 g, 2 mmol) and DMSO (1 ml). The solution was stirred for 30 min. The trimethylammonium salt (0.427 g , 2 mmol) was then added and stirring continued for 2.5 h at 20°C. The solution was cooled in an ice bath and poured into ether (60 ml) containing acetic acid (0.32 ml). A white precipitate was collected, triturated with water (4 ml) and collected again to give B. 4292 (436 mg , 69%) recrystallised from methanol.

Type IB.

O ⁶ -Thenyl-2 -methylhypoxanthine, B. 4350

DABCO salt from 6-chloro-2-methylpurine:

6-chloro-2-methylpurine (0.5 g, 3 mmol) was dissolved in a mixture of DMF (5 ml) and diglyme (25 ml). DABCO (0.66 g, 6 mmol) was then added. The mixture was stirred for 1 h and the precipitate collected to give the quaternary salt (700 mg , 82%). NMR (300 MHz, DMSO-d ₆ ) : shift in ppm 2.65 (s), 3.27 (t, 1=7.5 Hz), 3.78 (s), 4.14 (t, J=7.5 Hz), 8.21 (s).

Thenyl alcohol (684 mg , 6 mmol) was added to sodium hydride ( 60% in oil ; 80 mg , 2 mmol) and DMSO (0.5 ml). The solution was stirred for 30 min. The DABCO salt was then added and stirring continued for 5 h. The solution was then poured into ether (30 ml) containing acetic acid (0.15 ml). A precipitate was collected, triturated with water (4 ml) and collected again to give 0 ⁶ -Thenyl-2-methylhypoxanthine (96 mg, 35%) recrystallised from acetonitrile.

Type IC.

0 ⁶ -(4-Bromothenyl)-2-fluorohypoxanthine, B. 4353

To 3.6 ml of 40% fluoroboric acid precooled to -25°C in a bath was added O ⁶ -(4-bromothenyl) guanine (326 mg, 1 mmol) with vigorous stirring. A solution of sodium nitrite (0.116 g, 1.7 mmol) in water (0.15 ml) was added dropwise over a period of 10 min. After 20 min, the solution was poured into ice. The mixture was then allowed to stand at 0°C for 15 h, then collected and dried to afford almost pure (t.l.c.) B. 4353 (180 mg, 55%). Flash chromatography ( Hexane - Ethyl Acetate decreasing polarity little by little ) afforded B. 4353 .

Typical synthetic procedures (continued)

Type 3D

0*-Thenyl-5-deazapterin, B. 4376

5 a) N -Pivaloyl-5-deazapterin

A mixture of 5-deazapterin ³³ ' ³⁴ (2.0g, 13.36mmol), 4-dimethylaminopyridine (0.22g, l .δmmol) and pivalic anhydride (12ml) was heated to 165°C. Excess pivalic anhydride was distilled off and the residue dissolved in dichloromethane and applied to . _n a pad of silica gel, and eluted with 2% methanol in dichloromethane. Evaporation and recrystallisation of the product from ethanol gave shiny cream coloured crystals (2.25g, 74%) of the pivaloyl derivative, m.p. 258-259°C ; λ„„ _x (MeOH) 277 nm; NMR (300MHz, DMSO-d _fi ) δ 1 28(s), 7.44(q), 8 43(dd), 8 88(dd), 1 1.4(s), 12.3 l(s) b) ² -pivaloyl-0*-thenyl-5-deazapterin

^ A suspension of N -pivaloyl-5-deazapterin (0.492g, 2mmol) in tetrahydrofuran

(8ml) was stirred for 10 min, and tri-n-butylphosphine (0.606g, 3mmol), thenyl alcohol (0.432g, 3mmol) and diisopropylazodicarboxylate (0.606g, 3mmol) were added successively. The reaction was allowed to proceed for 2h at room temperature and evaporation then gave an oil Hexane was added to induce crystallisation Filtration and recrystallisation from hexane gave bright yellow crystals of the thenyl

20 derivative (0 32g, 47%) m p. 107-108 ^ϋ C ; λ^MeOH) 272, 31 1 nm;

NMR (300MHz, DMSO-d ₆ ) δ 1.28(s), 5.86(s), 6 98(q), 7 28(dd), 7 43(dd), 7 52(q), 8 46(dd), 8.89(dd) c) B 4376 oe N-pivaloyl-O ^' '-thenyl-5-deazapterin (0.28g, 0 82mmol) was heated for 24h under reflux with aqueous NaOH (3M, 2ml) and ethanol (1ml). The solvent was removed by evaporation and the residual solid dissolved in water. Acidification with acetic acid gave a white precipitate Filtration and recrystallisation of the solid from ethanol gave white crystals of O*-thenyl-5-deazapterin (B 4376), (0 107g, 51%)

Type 4D

30

C \ r6-(4-Bromothenyl)-5-nitrocytosme, B 4380

Sodium hydride (60% in oil, 80mg, 2mmol) was added to a stirred solution of 4-bromothenyl alcohol (290mg, 1.5mmol) in dry DMSO (1ml) After 30 min, 4-amino- 2-chloro-5-nitropyrimidine ³⁵ (174mg, lmmol) was added and the mixture heated at 35 50°C for 2h. The DMSO was removed in vacuo and the pH adjusted to 7 with aqueous acetic acid. After extraction into ethyl acetate, the product B 4380 was crystallised from methanol ( Img, 15%).

Type 5

S -(4-bromothenyl)-6-thiognanine, B.4352

Sodium hydride (60% in oil; 44mg, 1.1 mmol) was added to a stirred solution of 4-bromothenyl mercaptan (418mg, 2mmol) in dry DMSO (0.5ml). After 30 min, 2- amino-N,N,N-trimethyI-lH-purin-6-aminium chloride (228mg, lmmol) was added and stirring continued for lh. Acetic acid (0.12ml) and ether (30ml) were added and after decantation and trituration with fresh ether, B.4352 (38mg, 11%) was filtered off.

9-Substituted O -(4-bromothenyl)guanines: 0 0 ⁶ -(4-Bromoihenyl)-9-(ethoxymethyl)guanim, B.4369

O ⁶ -(4-BromothenyI)guanine (652mg, 2mmol) was dissolved in sodium ethoxide (IM, 2ml, 2mmol) After 10 min, the ethanol was removed and the residue was dissolved in dry DMF Chloromethyl ethyl ether (189mg, 2mmol) was added dropwise to the stirred solution under an atmosphere of argon After 45 min, the 5 solvent was removed. The oily product was crystallised from ethanol giving B.4369 (158mg) as needles. A further 1 18mg was obtained by flash chromatography of the mother liquor on silica gel with 5% ethanol in CH ₂ C1 ₂ . Total yield, 39%.

0 ⁶ -(4~Bromothenyl)-9-(2-hydroxyethoxymethyl)guanme, B . 4335

_Q A stirred mixture of O ^tf -(4-bromothenyl)guanine (294mg, lmmol), (NH ₄ ) ₂ SΟ ₄

(47mg) and hexamethyldisilazane (5ml) was heated at reflux for 3h Volatile material was then evaporated under vacuum. The residue was stirred with benzene (15ml) and Hg(CN) ₂ (344mg, 1.3mmol) under reflux for 30 min. A solution of (2- acetoxyethoxy)methyl bromide (Ref 4 p33) (197mg, lmmol) in benzene (10ml) was added, reflux maintained for 2h, and the cloudy diluted with chloroform (150ml) The organic phase was washed with saturated aqueous NaHCΟ (30ml), followed by KI 5 (IM , 30ml), dried over MgSΟ ₄ and evaporated to give an oil (313mg) This oil was chromatographed on a silica gel column with CHCl ₃ -MeΟH (12 1) as eluant, yielding almost pure (t.l.c.) Ο-acetate (141mg) of B 4335

Methanol (60ml) was saturated with dry ammonia and poured onto this O-acetate in a flask which was tightly stoppered. After dissolution, stirring was stopped and the flask left closed overnight Evaporation of methanol gave B. 4335 (135mg , 46%),

30 recrystallised from isopropanol

0 ⁶ -4-bromothe/tyl-9-(β -D-ribofuranosyl) guanine, B 4363

A mixture of 2',3',5 ^, -tri-(O-acetyl)guanosine ³⁶ (409mg, lmmol), tii-n-butylphosphine (303mg, 1.5mmol) and 4-bromothenyl alcohol (290mg, l .Smmol) in dry or tetrahydrofuran (16ml) was stirred at room temperature for 45 min. Then diisopropyl azodicarboxylate (303mg, 1.5mmol) was added dropwise and the mixture stirred for 2h. The solution was evaporated leaving an oil which was dissolved in THF/MeOH/25% aqueous ammonia ( 1 : 1 : 1 ; 5 ml) and kept for 48 h at 4°C.

Adsorption on silica gel and column chromatography with CHCl ₃ /MeOH (15 1 to 10 1) gave the riboside B 4363 (205mg, 44%)

0 ⁶ -4-Broιnothenyl-9-(β -O-2'-deoxyrώofura?ιosyl) guanine, B 4379 A mixture of 3',5'-di-(O-acetyl)-2'-deoxyguanosine ³⁷ (554mg, 1 5mmol), tri-n- butylphosphine (666 6mg, 3 3mmol) and 4-bromothenyl alcohol (638mg, 3 3mmol) in dry tetrahydrofuran (40ml) was stirred at 80°C for 15 min Then diisopropyl azodicarboxylate (666 6mg, 3 3 mmol) was added dropwise and 15 min later, the reaction mixture was cooled and evaporated leaving an oil This was dissolved in THF/MeOH/25% aqueous ammonia ( 1.1 1 , 5 ml) and kept for 48 h at 4°C Adsorption on silica gel and column chromatography with CHCl ₃ /MeOH (20 1) gave the 2'-deoxyriboside B 4379 (338mg, 51%)

9-(β-O-Arabmofuranosyl)-0 ⁶ -(4-bromolhenyl)guamne, B 4368

An alkoxide solution was made from sodium hydride (60% in oil, 60mg, 1 5mmol) and 4-bromothenyl alcohol (344mg, 1 8mmol) in dry DMSO (0 5ml) over 1 h It was reacted with 2-amino-9-(β- -arabino uranosyl)-6-chloropurine ^,8 (15 Img, 0 5mmol) and stirred for 5 mm at room temperature, then 15 min at 60-65°C Cooling and trituration with ether (50ml) and filtration yielded a solid which was dissolved in water (5ml), neutralised with acetic acid and treated with silica gel Column chromatography with ethyl acetate/MeOH (19 1) gave the arabinoside B.4368 (87mg, 38%), pure on t l.c

O ⁶ -substituted guanines

These were made by the standard procedure from the quaternary salt 2-amino-N,N,N- trimethyl-lH-purin-6-aminium chloride and the appropriate alkoxide derived from the alcohol and sodium hydride in DMSO (cf pp 16d, 17, 18, 47 of 7/12/95)

TABLE IA

TABLE IA (continued)

-P C

TABLE IA (continued)

TABLE IA (continued)

Continuation of Table la ^

TABLE IA (continued)

Compound, Test No. 9-Substituent Yield % Solvent for Recrystn. M.p. Formula Molecular Analysis ³

CC) Weight C H

B 4369 ethoxymethyl 39 EtOH 134-5 CnH ₁₄ BrN ₅ O ₂ S 384 40.58 3 71 17

(40.64 3 67 18

B 4370 77-octyloxymethyl 39 EtOH 90 C _!9 H ₂₆ BrN5O ₂ S 468 48.97 5 67 14.

(48.72 5 60 14

B 4334 2-hydroxy- 46 7-PrOH 150-2 C ₁₅ H _I7 N ₅ O ₃ 315 57.19 5 59 21. ethoxymethyl (57 13 5 43 22.

B 4335 2-hydroxy- 42 /-PrOH 156-8 Ci3H,4BrN5θ ₃ S 400 39.16 3.68 17 ethoxymethyl (39 01 3.53 17 5 B 4363 β-D-ribo- 44 C ₁₅ H ₁₆ BrN ₅ O ₅ S 458 furanosyl B 4368 β-D-arabino- 38 C _I5 H ₁₆ BrN _; O ₅ S 458 furanosyl B4379 β-D-2-deoxyribo- 51 C ₁₅ H ₁₆ BrN ₅ O ₄ S 442 furanosyl ^a Found, with required values in parenthesis ^b O ^δ -benzyl

TABLE IB

Compound Type, lest No. fZ-Substittienf RCii _λ λ.,„ (MeOH) δ _H |pp from TMS, (CD ₃ ) ₂ SO,μ(Hz) (nm)

560(s), 653(dd, 3 I, 19), 669(d, 31), 776(dd, I 9, 09) 839(s), 855(s) 583(s), 708(dd, 5 I, 34), 7 5(d, 34), 76(d, 51 , 839(s).85l(s) 580(s), 738(d, I 3), 773(d. I 3), 842(s), 858(s)

261(s), 560(s), 750(m), 832(s) 263(s), 577(s), 705(dd, 51, 24, 733(d), 24), 758(dd, 5 0) 826(s),

1322(s)

Type IC. -Ffuoioliypoxciiithmes B 4353 4-bromothenyl 233, 255 577(s), 74(d, I 5), 777(d, I 5), 845(s).1364(bs)

benzyl 247, 283 348(m), 470(s), 545(s), 659(s), 745(m), 803(s), B 4335 4-bro othenyl 245, 284 349( ), 47l(s), 545(s ⁾ , 566(s), 665(s), 730(d, 15) 772(d, I 5) 804(s)

Type IE.8~H)drox)γιιanιπes- B 434 4-bromothen l 239,293 554(s), 624(s), 733(d, I 4) 770(d, I 4), 1049(s) J 1 12(s)

Type A.8-Azagιιaιιιncs B 4270 4-fluorobenzyl 288 557(s), 704(s), 728(m), 765(m), 1538(s) B 4314 4-chlorothenyl 288 571(s), 713(s),741(d, 15), 766(d, 15), I542(s) B 4289 4-bromothenyl 287 573(s), 712(s), 743(d, 15), 776(d, 15), 1539(s)

TABLE IB (continued)

550(s).668(s).774(nι), 7 S2(s ), |2 S7(bs)

549(0,670(0 720(m) 76l(m) 7 S2(s). I288(bs)

550(s), 669(s) 74<>(d. S 4).756(d.84), 7 SKs) 1290(s)

539(s), 605(s), 669M 6 o ₄ ( _c |.70) 704(dd 79. I 5), 7 I (d. I 5) 7 S0(s)

1286(bs)

546(s).652(s).670(s).671(0, 773(0.779(s), 1285(bs)

569(s), 673(s), 707(d, 35), 73 (s), 760(d. I I), 779(s), 1290(bs)

565(s), 676(s) 738(0.772(d, 13).7SKs). I29l(b<

562(s).730(1.9 I), 768(ιn), 79I(.0, 7 7(0 563(s), 753(d, 83), 765(d.83).790(s).797(s) 578(s), 746(d, 16).772(d, 16), 795(s).8 OI(s) 579(s).749(c). I 6).7 l(d 1 ) 795(0.801 Cs ^" )

559(s).729089).7 ?l(bO 767(m)

575(s), 744(d, I 6).755(bs) 769(d. I 6) 578(s), 745(cl.16), 746(b 775(cl, I 6)

Type3C. p/ertns

B 4290

B 4316

B 4288

TABLE IB (continued)

5 10(s), 5 19(s), 5 96(s), 6 10(s), 7 19(t, 8 8), 7 44(dd, 8 8, 5 8)

5 1 l (s), 5 22(s), 5 96(s), 6 10(s), 7 44(s)

5 09(s), 5 ] l (s), 5 97(s), 6 03(s), 6 07(s), 6 91 (d, 1 1 ), 7 00(s)

5 08(s), 5 40(s), 6 00(s), 6 ! 0(s), 7 03(dd, 8 1 , 3 5)7 20(dd, 8 1 , 1 ), 7 54

(dd, 3 5, 1 1) 5 08(s), 5 35(s), 6 03(s), 6 I 3(s), 7 19(s), 7 55(d I 6)

5 59(s), 7 26(m), 7 65(m), 7 80(bs), 7 85(bs), 8 00(bs), 10 05(bs)

5 7300, 7 40(d, 1 ό), 7 66(d, 1 6), 7 94(s), 7 98(d, 2 7), 8 1 l (d, 4 2) 10 03

(d, 4 2) 5 7500, 7 42(d, 1 4), 7 75(d, 1 4), 7 93(s), 7 98(s), 8 I 2(d, 4 0), 10 04

(d, 4 0)

5-πιlιop ₎ i iniidiiies

B 4308 piperonyl 288,330 5 33(s), 6 05(s), 6 95(d, 8 0), 7 00(dd, 8 0, 1 4), 7 10(d, 1 4); 7 26(bs), 7 3

7 96(bs)

B 4306 thenyl 234, 329 5 59(s), 7 03(dd, 5 1 , 3 5) 7 28(d, 3 5), 7 32(bs), 7 56(d 5 1 ), 7 94(bs)

TABLE IB (continued)

Compound Type, Test No. Substituent (MeOH) δ _H [ppm from TMS, (CD ₃ ) ₂ SO,]/(Hz) RCH ₂ (nm)

Type 3D 5-Deazapterins (O ⁴ -substituent)

B 4376 thenyl 248, 309 5 54(s), 6.96(q), 7.716(dd), 7.38(dd), 7.41(q),

8 39(dd), 8.79(dd).

Type 4D 5-Nilrocytosιnes (O ² -substituent)

B 4380 4-bromothenyl 255 sh, 334 5 19(s), 7 20(s), 7.56(d), 8 24(s), 8.70(s), 8.90(

Type 5 6-Thioguamnes

B 4228 piperonyl 245, 31 1 4 56(s), 6.06(s), 6.55(s), 7 03(d), 7 06(d), 7.14(

8.08(s), 12.67(bs).

B 4352 4-bromothenγl 241, 314 4.77(s), 6.52(s), 7.18(d), 7 51(d), 7.93(s), 12.61

TABLE IB (cont inued)

Compound Type, Test No. δ _H [ppm from TMS, (CD ₃ ) ₂ SO,]7(Hz)

B 4369 3 35(s), 5 41 (s), 5 66(s), 6 66(s), 7 38(d), 7 73(d), 8 04(s)

B 4370 0 09(t), 1 17(m), 3 36(t), 5 41(s), 5 66(s), 6 66(s), 7 38(d) 7 72(d), 8 03 (s)

B .4334 a 3 48(m), 4 70(s), 5 45(s), 6 59(s), 7 45(s), 8 03(s)

B 4335 3 49(m), 4 71(s), 5 45(s), 5 66(s), 6 65(s), 7 30(d 1 5),

7 72(d, 1 5), 8 40(s)

B 4363 3 54(m), 3 63(m), 3 91(dd), 4 12(dd), 4 48 (ddd), 5 12(dd

5 18(d), 5 45(d), 5 66(s), 5 80(dd), 6 61(s), 7 38(d), 7 71(

8 15(s)

B 4368 3 64(m), 3 76(dd), 4 07(m), 5 09(dd), 5 51(d), 5 53(m),

6 13(d), 6 60(d), 7 37(d), 7 71(d), 7 95(s) B 4379 2 39(ddd), 2 72(ddd), 3 65(ddd), 3 98(dd), 4 40(dd), 5 l l( 5 41(d), 5 80(s), 6 38(dd), 6 67(s), 7 49(d), 7 83(d), 8 25(

0 ⁶ -benzyl

TABLE 2 INACTIVATOR TYPE

IA

B.4291 0 ⁶ -(thenyl)-hypoxanthine

B.4293

0 _, 6-(furfury1)-hypoxanthine B.4292

0_δ-(4-bromothenyl)-hypoxanthine θ6-(benzyl)-hypoxanthine -

IB B.4347

0"-(benzyl )-2-methylhypoxanthine 75

B.4350

0 _, 6-(thenyl )-2-methylhypoxanthine 14

IC B.4353

0 _, ^-(4-bromothenyl )-2-fluorohypoxanthine 1.4

0^-(benzyl)-2-fluorohypoxanthine ^a 48

ID B.4334

^-(benzyl)-9-(2-hydroxyethoxymethyl) guanine 8 >20

B.4335

0,6-(4-bromothenyl)-9-(2-hydroxy ethoxy ethyl)guanine See Table 3 _1E

B.4349

0_6-(4-bromothenyl)-8-hydroxyguanine See Table 3

()6-(benzyl)-8-hydroxyguanine ^a 0.3 2A

B.4270

0.6-(4-f luorobenzyl )-8-azaguanine 0.08

TABLE 2 (continued) INACTIVATOR TYPE

B.4314 g6_(4_chlorothenyl)-8-azaguanine

B.4289 g6_(4-bromothenyl)-8-azaguanine θ6-(benzyl)-8-azaguanine ^a 2B

B.4310

0_6-(benzyl )-7-deaza-8-azaguanine

B.4340

C)6-(4-fluorobenzyl)-8-aza-7-deazaguanine

B.4339 g6_(4_chlorobenzyl)-8-aza-7-deazaguanine

B.4343 g6-(piperonyl)-8-aza-7-deazaguanine B.4348

()6-(furfuryl)-8-aza-7-deazaguanine

B.4338 ()6-(thenyl)-8-aza-7-deazaguanine

B.4337 g6_(4_bromothenyl)-8-aza-7-deazaguanine

3A

B.4272 g6_(4_f luorobenzyl)-8-oxaguanine See Table 3

B.4285 0 ⁶ -(4-chlorobenzyl)-8-oxaguanine 0.225 4.6

B.4299

0 ⁶ (4-chlorothenyl)-8-oxaguanine 0.243 9.2

B.4287 g6-(-4_bromothenyl)-8-oxaguanine 0.24 2.6 B.4232

()6_(benzyl )-8-oxaguanine 0.25

TABLE 2 (continued) INACTIVATOR TYPE

3B B.4296

()6-(benzyl )-8-thiaguanine

B.4286 j6-(4-f luorobenzyl) -8-th iaguan ine

B.4315 Cj6_(4_chlorothenyl )-8-thiaguanine ^c

B.4351 fj6-(4-bromothenyl) -8-th iaguan ine

3C

B.4290 g4_(4_fi _uoro benzyl)-pterin 0.088 >10

B.4316 θ -(4-chlorotheny1)-pterin See Table 3

B.4288

0 ⁴ -(4-bromothenyl)-pterin 0.025 >10

B.4305

2,4-diamino-6-(4-f luorobenzyloxy)pyrimidine

B.4304

2, 4-d i ami no-6-(4-chlorobenzyloxy) pyrimidine

B.4303

2,4-diamino-6-(3,4-piperonyloxy)pyrimidine

B.4307

2,4-diamino-6-(thenyloxy)pyrimidine B-4302

2,4-diamino-6-(4-chlorothenyloxy)pyrimidine

2,4-diamino-6-(benzyloxy)pyrimidine ^a

4B

B.4301 2,4-diamino-6-(4-f1uorobenzyloxy)-5- nitrosopyri idine 0.0175 >16

TABLE 2 (continued) INACTIVATOR TYPE

B.4311

2,4-diamino-(4-chlorothenyloxy)-5- nitrosopyri idine

B.4312

2,4-diamino-6-(4-bromotheπyloxy)-5- nitrosopyrimidine

2,4-diamino-6-(benzyloxy)-5- nitrosopyrimidine ^a

4C

B.4306

2,4-diamino-6-(thenyloxy)-5- nitropyrimidine 2.3 >16

B.4308

2,4-diamino-6-piperonyloxy-5-nitropyrimidine 0.5 9.2

2,4-diamino-6-benzyloxy-5-nitropyrimidine ^a 0.06

4D

B .4380

(3 ² (4-bromothenyl ) -5-nitrocytosine 50

B .4228

S>6-(piperonyl ) -6-thioguanine 50

B.4352 s6_(4-bromothenyl )-6-thioguanine 8

Comparative

B.4376 ⁽ )6-thenyl-5-deazapterin 1,600

Results for some 9-substituted 0^ (4- bromothenyl)guanines are included in Table 7. a Data taken from Chae et al, J. Med. Chem. 1995, 38, 359-365 b Data taken from Moschel et al., J. Med. Chem. 1992, 35, 4486-4491 c B.4315 Raji I ₅₀ (uM) 0.002

Blank Space = not done.

TABLE 3

= Not Done

TABLE 4

EFFECT OF INACTIVATOR PRETREATMENT ON SENSITISATION OF VAROUS HUMAN CANCER CELL LINES TO TEMOZOLOMIDE

* Toxic to Raji cells at 10 μM

** Sensitisation factor = D^ control/D^ 'B'

— Not done

TABLE 5

EFFECT OF INACTIVATOR PRETREATMENT ON SENSITISATION OF VARIOUS HUMAN CANCER CELL LINES TO BCNU

* Toxic to Raji cells at 10 μM

** Sensitisation factor = D ₆₀ control/D^ 'B'

— Not done

TABLE 6A

Formula Analysis

° 5 6 mmol alcohol per mmol quaternary salt used in synthesis ^b Dimethylformamide reaction solvent

O ⁶ -Substituted guanines (continuation of Table 6 a,)

TABLE 6B

δ _H [ppm from TMS, (CD ₃ ) ₂ SO], J (Hz)

5 65(s), 6 40(s), 7 37(d), 7 71 (d), 7 85(s), 12 49(s)

5 59(s), 6 40(s), 7 06(d), 7 22(d), 7 87(s), 12 47(bs)

5 73(s), 6 46(s), 7 49(d), 7 87(s), 7 92(d), 12 54(bs)

2 93(s), 5 73(s), 6 41(s), 7 40(d), 7 52(d), 7 88(s), 12 52(bs)

5 64(s), 6 42(s), 7 34(d), 7 62(d), 7 86(s), 12 51 (s)

3 75(s), 5 57(s), 6 37(s), 6 60(d), 7 01 (d), 7 85(s), 12 48(s) 5 42(s), 6 38(s), 7 40(d), 7 72(d), 7 85(s), 12 47(s)

5 68(s), 6 44(s), 7 74(d), 7 86(s), 8 60(d), 12 50(s)

5 58(s), 6 45(s), 7 41 (s), 7 87(s), 12 52(s)

5 58(s), 6 36(s), 7 51 (bs), 7 61 (bs), 7 91 (bs), 8 44(bs), 12 56(bs)

5 42(s), 6 39(s), 6 64(d), 6 78(d), 7 85(s), 12 49(s)

0 ⁶ -Substituted guanines (continuation of Table 6B)

Compound Type, Test No. <3 ^δ -Subsu'tιιent λ _m „ (MeOH) δ _π [ppm from TMS, {CΩ ₃ )ιSO.]J(Ez)

RCH ₂ (nm)

B 4282 3-picolyl N-oxide 271 5 48(s), 6 41 (s), 7 47(m), 7 S7(s), 8 22(m), 8 42(s), 12 52(s)

5-methylsulphonyl- 242, 284 5 75(s), 6 43(s), 7 47(d\ 7 74(d), ^" 37(s), 12 52(s) thenyl

6-chloro-3-picolyl 242, 276 5 53(s), 6 38(s), 7 59(d), 7 87(s), 8 05(dd), 8 64(d),

12 48(s)

5-bromo-3-picolyl 242, 281 5 53(s), 6 41 (s), 7 86(s), 7 86(s), 8 26(dd), 8 73(d).

8 78(d), 12 50(s)

4-isothiazolyl 244, 284 5 58(s), 6 41(s), 7 84(s), 8 81 (s), 9 22(s), 12 47(s)

2 48(s), 5 62(s), 6 40(s), 7 26(m), 7 85(s), 12 48(s)

5 43(s), 6 38(s), 7 48(d), 7 77(s), 7 84(s), 12 47(s)

3 26(s), 5 70(s), 6 40(s), 7 72(s), 7 85(s), 8 38(d),

12 49(s)

5 90(s), 6 47(s), 7 60(t), 7 69(t), 7 86(t), 8 04(dd),

8 44(s), 8 51(d), 12 5 1 (s)

5 64(s), 6 36(s), 7 20(s), 7 28(s), 7 84(s), 12 47(s) 2 82(s), 5 68(s), 6 33(s), 7 60(s), 7 82(s), 8 01 (s),

12 45(s)

B 4378 5 67(s), 6 32(s), 7 31(m), 7 41 (m), 7 41 (m), 7 63(d),

7 82(s), 12 43(s)

TABLE 7

I ₅₀ (μM) Raji I _5(J Stability T l/2(h) INACTIVATOR M.Wt hAT (μM) By Spec

B.4280

0 -(4-bromothenyl)guanine 326 0.0034

B.4281

Q_ - (5-chlorothenyl ) guanine 281.7 0.004 >10

B.4282

0 - (oxido-3-picoly1 ) guam ^' ne 276 1 .4 >20

B.4283

0 -(5-cyanothenyl)guanine 272 0.005 >20

B.4294

0 -(5-methylsulphinylthenyl)guanine 309 0.03 >10

B.4298

0 -(4-chlorothenyl)guanine 282 0.008 0.005 >16

B.4300

0 -(4-methoxythenyl)guanine 277 0.0165 0.83

TABLE 7 (continued)

I_ _n (μH) Raji I Stability T 1/2 (h) ^l 5(T 5 RΠ0

INACTIVATOR M.Wt hAT (μM) By Spec

B.4309

0 -(5-methy1sulphonyltheny1)guanine 325 0.072 >16

B.4313

0 -(5-bromo-3-thienylmethyl)guanine 326 0.0065 0.035

B.4317

0 -(4-cyanothenyl)guanine 272 0.0028 >19

B.4318

Q_ -(4,5-dichlorothenyl)guanine 348 0.015 2.5

B.4319

0 -(6-chloro-3-picolyl)guanine 277 0.2 >13

B.4320 0 -(5-bromo-3-pico1yl) guanine 321 0.25 >13

B.4321

0 -(2-chloro-4-picolyl)guanine 277 0.04 >16

TABLE 7 (continued)

I _5O ιH) Raji I ₅₀ Stability T 1/2 (h)

INACTIVATOR M.Wt hAT CuH) By Spec

B.4336

0 -(5-bromofurfuryl) guanine 310 0.02 0.32

B.4354

0 -(4-isothiazolylmethyl)guanine 248 0.07

B.4356

0 -(4-methylthiothenyl)guanine 293 0.0095

B.4357

0 -(5-iodo-3-thienylmethyl)guanine 447 0.009 >16

B.4361

0 -(4-methylsulphonylthenyl)guanine 325 0.2 >16

B.4366

0 -(πaphtho[2,l-b]thiophen-2-ylmethyl)guanine 347 0.05

TABLE 7 (continued)

I _5Q (μM) Raji I _5Q Stability T 1/2 (h) INACTIVATOR M. t hAT (μM) By Spec

B.4368

9-(B-D-arabinofuranosyl)-0 -(4-bromothenyl)guanine 458 0.115

B.4369

0 -(4-bromothenyl)-9-(ethoxymethyl)guanine 384 0.28

B.4370 I

0 -(4-bromothenyl)-9(octyloxymethyl)guanine 468 1.2 ^~~

B.4373

0_ ⁶ -(4-azidothenyl)guam ^' ne 288 0.0063

B.4377

0 -(4-methylsulphinylthenyl)guanine 309 0.15

B.4379

0_ -(4-bromothenyl)-2-deoxyguanosine 442 0.095

TABLE 7B

INACTIVATOR M.Wt In vitro I50 (μM) Raji I50 Stability T 1/2 ( (uM) hAT mAT rAT chAT ogt By Spec By Assa

B.4363 θ (4-bromothenyl)guanosine 458 0.08 0.24 0.95 30 >16 >48

Blank space = not done

TABLE 8

ATASE ACTIVITY IN VARIOUS TISSUES OF NU/NU MICE AFTER

* control values taken from a separate experiment ** mean of 2 control liver values

Table 8.

Effect of B.4280 on ATase activity in several tissues of nude mice. Animal s were g i ven a single dose of B.4280 (lOmg/kg i.p.) and sacrificed 24 or 48 hours later.

TABLE 9

TOXICITY OF INACTIVATORS IN COMBINATION WITH BCNU IN DBA ₂ MICE

INACTIVATOR %SURVIVAL AFTER 14 DAYS (60mg/kg) 20mg/kg BCNU 16mg/kg BCNU 12mg/kg BCNU

O^-benzylguanine 33 (2/6) 0 (0/6)- 50 (3/6) ¹

50 (3/6)* 100 (6/6)** 100 (15/15) 100 (15/15)

All agents were given as a single i.p. dose

Table 9

Effect of ATase inactivators on the acute toxicity of bis-chloroethylnitrosourea (BCNU) in

DBA mi ce .

References

1

1

2

2 Press, New York, 1968, vol. 5, p.115; Shealy, Y.F., Clayton,

12. M.D. Dowle, R. Hayes, D.B. Judd and C . Williams, Synthesis, 1983,73.

13. E. Campaigne and W.L. Archer, J.Amer. Chem. Soc, Zϋ, 1953, 989.

14. J. Cymerman-Craig and J.W. Loder, J. Chem. Soc, 1954, 237.

15. CR. Johnson and J.E. Keiser, Org. Synth. Col]. Vol. 5. 1973, 791.

16. T.L. Cairns and B.C. McKusick, J. Org. Chem., 15., 1950, 790.

17. Z.N. Nazarova, Zhur. Obshch. Khim. , 24, 1954, 575 (Chem. Abs., 42, 6214, 10261; 5_3_, 15047).

18. W.J. Chute, W.M. Orchard and G.F. Wright, J. Org. Chem., 6,1941, 157.

19. J. Iriarte, E. Martinez and J.M. Muchowski, J. Heterocycl. Chem., 13, 1976, 393.

20. P. Fournari, R. Guilard and M. Person, Bull. Soc Chim. France, 1967, 4115.

21. S. Conde, R. Madronero, M.P. Fernandez-Tome and J. del Rio, J. Med. Chem., 21, 1978, 978.

22. E. Profft and D. Gerber, J. Prakt. Chem., 1J , 1962, 18.

23. Farbwerke Hoechst A. -G., Brit. Pat.1127 ,064 1968 (Chem. Abs., 10, 47284f).

24. P. Dubus, B. Decroix, J. Morel and P. Pastour, Bull. Soc Chim. France, 1976, 628.

25. P.J. Newcombe and R.K. Norris, Austra l. J. Chem. , 34. 1981, 1879.

26. P.R. Huddleston, J.M. Barker, B. Stickland, M.L. Wood and L.H.M. Guindi, J. Chem. Research, 1988, (S) 240, (M) 1871.

27. M. Hamana and M. Ya azaki, J. Pharm. Soc. Japan, 81, 1961, 574 (Chem. Abs. 55, 24743).

28. F.E. Ziegler and J.G. Sweeny, J. Org. Chem. , 34, 1969, 3545.

29. CR. de Wet and P.A. de Villiers, Tydskr. Natuurwet. , 14, 1974, 70 (Chem. Abs. 84, 30822w) .

30. Fan, C-Y., Potter, P.M., Rafferty, J.A., Watson, A.J., Cawkwell, L., Searle, P.F., O'Connor, P.J. and Margison, G.P. (1991) Nucleic Acids Res. 18, 5723-5727

31. Wilkinson, M.C, Potter, P.M., Cawkwell, L., Georgiadis, P.,

Patel, D., Swann, P.F. and Margison, G.P. (1989) Nucleic Acids Res. 17, 8475-8484.

32. Wilkinson, M.C, Cooper, D.P., Southan, C, Potter, P.M. & Margison, G.P. (1990) Nucleic Acids Res.. 18, 13-16.

33. R. Bernetti, F. Mancini and CC Price, J. Org. Chem. 27, 1962, 2863.

34. M.T.G. Ivery and J.E. Gready, J. Heterocvcl . Chem.. 31, 1994, 1385.

35. A. Albert, D.J. Brown and G. Cheesman, J. Chem. Soc. 1951, 474.

36. M.J. Robins and B. Uznanski , Can. J. Chem.. 59,. 1981, 2601.

37. B. Zajc, M.K. Lakshman, J.M. Sayer and D.M. Jerina, Tetrahedron Lett.. 33, 1992, 3409.

38. N.B. Hanna, K. Ramasamy, R.K. Robsins and G.R. Revankar, J_. Heterocvcl. Chem.. 25, ^' 1988, 1899.