Hoed HO OH - ACS Publications

reported here are as effective as a class against C. globo- sum as are thiocarbohydrazones,'6 for example. Since moderate effectiveness against both ...
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254 Journal of Medicinal Chemistry, 1971, Vol. 14, No. S

that of good commercial fungicides'? and some dithios e m i c a r b a ~ o n e s . ~Nevertheless, ~ the thiosemicarbazones of none of the 3 types of heterocyclic aldehydes reported here are as effective as a class against C. globosum as are thiocarbohydrazones,'6 for example. Since moderate effectiveness against both organisms is important, however, some useful generalizations about chemical structure and activity can be made. The order of decreasing effectiveness (by aldehyde class) of the thiosemicarbazones is pyrrole carboxaldehyde furfural > N-methylpyrrolecarboxaldehyde Ei thiopheriecarboxaldehyde. Substitution a t the 4 position does not seem to be important for the first and last types but is for the second and third (cf. ref 3 ) . The order of decreasing effectiveness of substituents is aromatic > aliphatic in the case of the pyrrole carboxaldehyde thiosemicarbazories but is reversed for the N-methyl analogs. There is no obvious reason why the 5-methylthiophene derivatives (30-38) should be completely ineffective (cf. ref 4). Experimental Section Thiosemicarbazide, the substituted isothiocyanates, and the heterocyclic aldehydes were the purest grades obtainable from commerical sources, and were used as received. The preparation of the 4-substituted thiosemicarbazides has been described. 17 General Preparation for Thiosemicarbazones (Table I).-To a warm s o h of [substituted] thiosemicarbazide (0.01 mole) ill Ii2O[Et,OH] (50 nil) containing HAC (1 ml) was added dropwise a s o h of heterocyclic aldehyde (0.01 mole) in EtOH (50 ml). The mixt was heated gently o n a steam bath for 1 hr; Ii20 was added \inti1 the oiiset of ppt8ri. The ppt, which formed on sitbsequent, cooling was sepd by filtrration, washed with cold 507; EtOH-HzO, dried, and recrystd to constant mp. Characteristic ir absorptions: all compds, 3360-3140 ( N H ) ; 1630-159.5 (CN); 1560-1535 (CNH); 1160-1110 (NCN); 836-800 (CS); 2,12, 21, 31, 40, 1640 tC=C). I r spectra were measured with a Model 621 Perkin-Elmer spectrophotometer. Elemental analyses were carried out at the microanalytical lab of Drs. Weiler and Strauss in Oxford, England. Melting points were determined using a Fisher-Johns apparatus and have been corrected. The antimicrobial activity of the compds listed in Table I has been evaluated11 by the tube-dilution method,12using pure cultures of C. globosum (Strain USIIA 1042.4) and Aspergillus niger (Strain USDA 215-5373.16).

Acknowledgments.-The authors thank Aliss G . Colin for the microbiological screening data, and R. Ironside and V. Boyko for recording the ir spectra. (16) I). A I . Wiles and T Suprunchuk, J . .Wed. Chem., 13, 323 (1970). (17) 1). hI. Wiles and T. Siiprunchuk, Cun. J . Chem.. 46, 1865 (1968). ..~-.

Potential Antitumor Agents. Selenoguanosine and Related Compounds' SHIH-" CHU Division of Biological and Medical Sciences, Brown University, Providence, Rhode Island 02912 Received June 5, 1970

It has been shown previously that 6-selenog~anine~ exhibits antitumor activity on ascites cells of Sarcoma 1SO and against lymphomas L1210 and L-5178Y. (1) This work has been supported by Grant T-536 from the American Cancer Society and Grant 16538-01 from the United States Public Health Service. (2) H. G. Mautner, 8 . H. Chu, J. J. Jaffe, and A. C. Sartorelli, J. Med. Chem. 6, 36 (1963).

These findings have led us to prepare the additional uiireported methylseleno 9-P-D-ribosyl derivatives of (iselenoguanine. We hope these niorc solublc :innlogs will offer further improvement in antitumor :nctivity. This coniniuiiicatiori describes thc iyritlicsis of (i-sclcnoguanosine3 (l),G-methq.lselenogu31iiiic, &met Ii~~lsolcnoguanosine, arid G-metli~lseleiioi1io5i!i~arid prdiminary studies of their biological propcrt ics.

Hoed HO

OH

Experimental Section'

%-Amino-6-seleno-9-p-~-ribofuranosylpur~ne (6-Selenoguanosine) (l).-Condensed ILSe (1.5 ml) was bubbled through a so111 of 0.3 g (0.013 mole) of N a in 30 ml of abs MeOH. 2-Amino-6chloro-9-~-~-ribofuranosylpurine5(3.0 g, 0.00906 mole) in 70 ml of abs MeOH was introduced into the well-stirred orange solli. The mixture was stirred under N2 at room temp for I hr. The greenish solid was collected by filtration and taken up iii 35 ml of 37, NaZCO, arid the colloidal Se was filtered off. The filtrate was acidified with glacial AcOR to pH 4 and cooled. The bright yellow solid was collected, washed with cold HzO, and dried. The yield was 1.75 g (54.4%) mp 197.5' dec. On t l P the Br value in Hz0 is 0.40. Anal. (CIOH1BN,04Se.0.T,HzO) C, H, N . 2-Amino-6-methylseleno-p-u-ribofuranosylpurine(6-Methylselenoguanosine).-A solii of 1.2 g (0.00338 mole) of 1 i n S.45 ml of 0.4 N NaOH (0.00338 mole) was stirred at room temp and 0.22 ml (0.00348 mole) of Me1 was added. The wln was stirred a t room temp for 1 hr. The resulting mixture was filtered and the filtrate extd continuously with E t 2 0 . After 24 hr, the solid was collected and dried in vacuo. The yield was 0.65 g (52.35;,). The product was recrystd from Et,OH-pet ether (30°-60"), mp 144-147". On tlq6 the Rr value in H2O is 0.49. Anal. (CIIHIP NjO4Se.O.5H20) C , H, II'. 2-Amino-6-methylselenopurine (6-Methylselenoguanine).-A soln of 2.23 g (0.01 mole) of selenoguanine in 25 ml (0.01 mole) of 0.4 N NaOH was stirred at room temp and 0.65 ml (0.01 mole) of Me1 added. The soln was kept a t room temp for 1 hr. The light yellow solid was collected, washed with H20, and dried. The yield was 1.85 g (81.170). It was recrystd from h/leOH, mp 218'. On tlce the Rr value in H 2 0 is 0.30. Anal. (C6H?N;Se) C, H, N. 6-Methylseleno-9-p-~-ribofuranosylpurine(6-Methylselenoinosine).-A soln of 0.192 g (0.00058 mole) of selenoinosine' in 1.45 ml (0.00058 mole) of 0.4 N NaOH was stirred a t room temp, and 0.073 ml(0.00058 mole) of Me1 was added. The soln was stirred at room temp for 1 hr. The resulting mixture was extd continuously with EtrO. After 24 hr the solid was collected by filtratioii and dried in vacuo. The Et20 s o h was evapd to dryness. The yield was 0.175 g (85.00/,). The product was recrystd from EtOH-pet ether (30-60°),mp 154-155'. On tlca the Rr value in HzO is 0.70. Anal. ( C ~ I H M N ~ O ~ S ~C, . HH, ZO N.) Dissociation Constants.-pK, values were determined by potentiometric tit,ration using a Radiometer pH meter 26. The selenoguanine, which is very insol in HzO, was dissolved in boiling (3) Very recently 6-aelenoguanosine was synthesized by L. B. Townsend and G . H. Milne, J . Heterocycl. Chem., 7, 753 (1970). (4) All melting points are uncorrected. Analyses were carried out at Midwest Microlab, Inc., Indianapolis, I n d . (5) J. F. Gerster, J. W. Jonea, and R . K . Robins, J. Org. Chem., 26, 945 (1963). (6) Polygram C E L 300 P E I from Brinkmann Instruments, Inc., Westbury, N . Y. (7) H. G. Mautner and J. J. Jaffe, Cancer Res., 10, 381 (1960)

Journnl of Medicinal Chemistry, 1971, Vol. 14, No. 3 255

NOTES

TABLE I ULTRAVIOLET SPECTRA AND ACIDDISSOCIATION CONSTANTS -pH

7-Distd

-1

Compds

mfi

f

6-Thioguaninen

258 347

8100 20900

6-14 ethy1thi oguanineb

24 1 273 317 263 372 329

7000 10000 13000 5600 16500 12700

6-SelenoguaiiineC 6-Me thylselenognaniiie

H20-

mfi

7 -

PH 11-

--Methanol----.

Xmsx,

Xmsx.

Xmsx.

mr

f

e

242 270 322 228 313

8700 7200 16000 20200 10600

360

10800

318

6900

246 315

8900 12400

317

12300

262 319 256 330

14700 2 1000 10800 17200

7.81,7.62d

r p H 4-6-7

6-Thioguanosinec

257 342 267 365

6-Selenoguanosine

8800 24800 4600 18200

264 357

5600 22300

221 245 310 221 252 314

6-Methyl thioguanosine' 6-Methylselenoguanosine

252 316

8.33

9700 13100

15300 14400 11000 12900 10000 10100

6-Selenoinosineo

235 7700 11200 (Phosphate-citrate buffer, pH 7) 345 229 8400 230 8000 6-Methylselenoinosi~ie 302 13500 300 17600 G. 13. Elion and G. Hitchings, J . Amer. Chem. SOC.,77, 1676 (1957). b J . A. Montgomery and L. B. Holum, ibid., 79, 2183 (1937). See ref 2. A . F. Ross, private communication (it was determined by a spectrophotometric method). e J. J. Fox, I. Wempen, A . Hamptoii, and I. L. Doerr, J . Amer. Chem. Soc., 80. 1669 (1958). C. W. Noel1 and 13. K. Robins, J . Nal. Pharm. Chcm., 5, 1074 (1962). See ref 7. T A I & ~ ~ :11 EFFECTO F 6-THIOGUANINE, SISLICNOQUANINli,SELI':NOGUANOSINI~:, ME:THYLS~LENOQUANINI~, A N D Ml~THYLSliLI~;NOGUANOSINlCO N THE: GnowTH O F L-5178Y

--------Yo 1.0 x 10-4

survival-------1.0 x 10-6 1.0 x 10-6

Control 100%

M

M

M

Thioguanine Selenoguanosine Selenoguaiiine Methylselenoguanosine Methylselenoguanine

4

9 8 20 46 45

33 31 45 80 82

4

12 21 24

H20 and then cooled to room temp. All determinations were made in duplicate. Stability Studies.-The half-life from the height of the 360mfi peak of 1 in HzO (pH 6.01) a t room temp was about 24 hr, in phosphate buffer a t p H 7.0 2.