Genetic and biochemical studies with the adenosine analogs toyocamycin and tubercidin: mutation at the adenosine kinase locus in Chinese hamster cells.

The pyrrolopyrimidine nucleosides toyocamycin and tubercidin show several unique features of growth inhibition in Chinese hamster ovary (CHO) cells. Stable mutants which are more than 600-fold resistant to these drugs are obtained in CHO cells at a strikingly high frequency of approximately 10(-3), in the absence of mutagenesis. The mutants resistant to toyocamycin (Toyr) and tubercidin (Tubr) exhibit similar cross-resistance patterns to the two selective drugs as well as to adenosine and 6-methyl mercaptopurine riboside, indicating that the same lesion is probably involved in all cases. The mutants examined were found to be deficient in the enzyme adenosine kinase (AK), indicating that the phosphorylation of these analogs is an essential first step in their toxic action. The above mutants (AK-) behaved recessively in cell hybrids, and segregation studies indicate that the AK locus is not linked to the X chromosome. The frequencies of similar Toyr mutants in other Chinese hamster lines, e.g., V79, CHW, M3-1, GM7, and CHO-K1, varied from similar to more than three logs less than that observed for CHO cells, indicating that various cell lines probably differ in the number of functional gene copies for this locus.     

Involvement of adenosine kinase in the phosphorylation of formycin B in CHO cells

In Chinese hamster ovary cells, [3H]formycin B is metabolized into formycin B-5'-monophosphate, formycin A-5'-monophosphate and higher phosphorylated derivatives of formycin A which are incorporated into RNA. Mutants of CHO cells independently selected for resistance to various adenosine analogs viz. toyocamycin, tubercidin, 6-methylmercaptopurine riboside, which contain no detectable activity of adenosine kinase (AK) in cell extracts, all exhibited between 2- to 3-fold increased resistance to formycin B. Formycin B-resistant mutants of CHO cells are also affected in AK, as indicated by the absence of AK activity in cell extracts. Both types of AK- mutants showed reduced uptake and phosphorylation of [3H]formycin B in comparison to the parental (AK+) cells. In addition, toxicity of formycin B towards CHO cells was reduced in presence of adenosine in a concentration dependent manner. These observations strongly indicate that in CHO cells, formycin B is phosphorylated via AK and that like other nucleoside analogs its phosphorylation may be essential for the drugs cellular toxicity.     

High frequency of mutation to tubercidin resistance in CHO cells.

The acquisition of high-level resistance to tubercidin (an adenosine analog) in CHO cells occurs in a single step at high frequency (10(-3) to 10(-4)) without mutagenesis. Analysis of a large number of independent mutants by a fluctuation test (Luria and Delbruk, 1943) indicates that they arise independently of the selection medium and all fall into the same complementation group. All mutants tested lack detectable adenosine kinase activity. An analysis of hybrids between mutant and wild-type cells indicates that resistance to tubercidin is a recessive marker which segregates as would be expected if it were a haploid locus in the parental CHO cell. Resistance to tubercidin is not linked to the X chromosome in CHO cells and appears to occur at much lower frequency in primary Chinese hamster cells and other cultured cell lines.     

Quantitative mutagenesis at the adenosine kinase locus in Chinese hamster ovary cells. Development and characteristics of the selection system

Stable mutants exhibiting high degree of resistance (100-1000-fold) to various nucleoside analogs viz, toyocamycin, tubercidin, 6-methyl mercaptopurine riboside (6-MeMPR) and pyrazofurin, are obtained at similar frequency (congruent to 1 X 10(-4] in CHO cells. The mutants resistant to any of the above analogs exhibit similar degree of cross-resistance to the other three nucleoside analogs, and all of the mutants examined contained no measurable activity of the purine salvage pathway enzyme adenosine kinase (AK) which converts these analogs to their phosphorylated derivatives. These results indicate that very similar mutants are selected using any of these analogs. The recovery of AK- mutants in CHO cells is not affected by cell density (up to at least 5 X 10(5) cells per 100-mm diameter dish) and after treatment with mutagen(s) maximum mutagenic effect is observed after 7-8 days, which then remains unchanged for the next several days. Treatment of CHO cells with a number of mutagenic agents e.g. ethyl methanesulfonate, ICR170, ultraviolet light, and benzo[a]pyrene, led to a nearly linear concentration-dependent increase in the frequency of the AK- mutants in cultures. The mutagenic response of the AK locus to these agents compared favorably with that of the HGPRT locus (6-thioguanine resistance) within the same experiments. These results show that the selection system for AK- mutants provides an additional valuable genetic marker for quantitative mutagenesis studies in CHO cells.     

Adenosine metabolism in wild-type and enzyme-deficient variants of Chinese hamster ovary and Novikoff rat hepatoma cells

Variants of Chinese hamster ovary and Novikoff rat hepatoma cells resistant to tubercidin and 2,5-diaminopurine, or to both drugs, were isolated, and their ability to convert adenosine and various adenosine analogs to nucleotides was compared to that of wild-type cells, both in intact cells and cell-free extracts. Adenosine deamination, and thus its conversion to nucleotides via inosine-hypoxanthine-inosine monophosphate, was inhibited by pretreatment of the cells or cell extracts with 2-deoxycoformycin. Cell-free extracts of the tubercidin-resistant variants, as well as of two adenosine-resistant mutants of Chinese hamster ovary cells, phosphorylated adenosine, tubercidin, pyrazofurin, or tricyclic nucleoside in the presence of ATP at less than 1% of the rate of extracts of wild-type cells. However, addition of phosphoribosyl pyrophosphate stimulated the conversion of adenosine to nucleotides 40-fold. Similarly, intact adenosine kinase-deficient cells failed to phosphorylate the adenosine analogs, but still converted adenosine to nucleotides at 5-10% the rate observed with wild-type cells. Phosphorylation of adenosine and tubercidin in wild-type cells was inhibited by substrate at concentration above 5-10 microM. In contrast, the rate of conversion of adenosine to nucleotides by adenosine kinase-deficient cells increased linearly up to a concentration of 400 microM adenosine, with the consequence that, at this concentration, these cells took up adenosine almost as rapidly as wild-type cells. Adenosine uptake by these kinase-deficient cells was inhibited by adenine and 5'-deoxyadenosine, and was largely abolished in mutants devoid also of adenine phosphoribosyltransferase. We conclude that adenosine is converted to nucleotides in adenosine kinase-deficient cells via adenine. Indirect evidence implicates 5'-methylthioadenosine phosphorylase as the enzyme responsible for the degradation of adenosine to adenine.     

Genetic analysis of nucleoside transport in Leishmania donovani.

Genetic dissection of nucleoside transport in Leishmania donovani indicates that the insect vector form of these parasites possesses two biochemically distinct nucleoside transport systems. The first transports inosine, guanosine, and formycin B, and the second transports pyrimidine nucleosides and the adenosine analogs, formycin A and tubercidin. Adenosine is transported by both systems. A mutant, FBD5, isolated by virtue of its resistance to growth inhibition by 5 microM formycin B, cannot efficiently transport inosine, guanosine, or formycin B. This cell line is also cross-resistant to growth inhibition by a spectrum of cytotoxic analogs of inosine and guanosine. A second parasite mutant, TUBA5, isolated for its resistance to 20 microM tubercidin, cannot take up from the culture medium radiolabeled tubercidin, formycin A, uridine, cytidine, or thymidine. Both the FBD5 and the TUBA5 cell lines have about a 50% reduced capacity to take up adenosine, indicating that adenosine is transported by both systems. A tubercidin-resistant clonal derivative of FBD5, FBD5-TUB, has acquired the combined biochemical phenotype of each single mutant. The wild-type and mutant cell lines transport purine bases and uracil with equal efficiency. Mutational analysis of the relative growth sensitivities to cytotoxic nucleoside analogs and the selective capacities to take up exogenous radiolabeled nucleosides from the culture medium have enabled us to define genetically the multiplicity and substrate specificities of the nucleoside transport systems in L. donovani promastigotes.     

Sodium-dependent nucleoside transport in mouse lymphocytes, human monocytes, and hamster macrophages and peritoneal exudate cells.

Mouse splenocytes and hamster peritoneal exudate cells (PEC), including macrophages, were shown to contain a predominantly Na(+)-dependent and inhibitor (6-[(4-nitrobenzyl)-mercapto]purine ribonucleoside, NBMPR)-resistant transport system for adenosine and other nucleosides. Adenosine (1 microM) was transported about equally in mouse thymocytes and human monocytes from peripheral blood by a Na(+)-dependent system and the NBMPR-sensitive facilitated diffusion system. Hamster PEC also transported inosine, tubercidin, formycin B, uridine, and thymidine in a NBMPR-insensitive manner. With the exception of formycin B, all nucleosides were phosphorylated intracellularly to varying degree, adenosine being almost fully phosphorylated. During the time course of routine experiments (30 s) formycin B was concentrated twofold over external medium levels (1 microM) without any drop-off in the transport rate. On the basis of metabolic studies it was estimated that uridine and tubercidin were also transported against a concentration gradient. Inosine, guanosine, 2'-deoxyadenosine, tubercidin, formycin B, and the pyrimidines uridine, thymidine, and cytidine (all 100 microM) inhibited transport of adenosine and inosine about 50-100%, while 3'-deoxyinosine showed weak inhibitory action. Transport of thymidine was strongly inhibited by nucleosides except by 3'-deoxyinosine. The Na(+)-dependent, active, and concentration transport system appears to be a feature of many immune-type cells, and its presence offers particular conceptual possibilities for the therapy of infections located in these cells.     

Diphtheria toxin resistance in human lymphoblast lines

Stable mutants (Dip^r), highly resistant to diphtheria toxin have been selected from a sensitive human lymphoblast line. A second human lymphoblast line, HH-4 (and its derivative TK6-1) were found to be highly resistant to diphtheria toxin without any previous selection, suggesting the presence of the Dip^r allele in the human population. The resistance of protein synthesis in extracts of mutant cells to diphtheria toxin indicates that the genetic lesion in the resistant lines examined involved an alteration in the protein synthesis. In comparison to sensitive cells, the mutant cell extracts contained reduced (30–40%) levels of ADP-ribosylatable elongation factor-2 activity suggesting that the lesion presumably affects elongation factor-2 in such cells. The biochemical phenotype of these mutants appears similar to that of the Dip^rIIb class of mutants of Chinese hamster cells (4,6) which behave codominantly in hybrids.     

Codominant and recessive 9-beta-D-arabinofuranosyladenine-resistant mutations of baby hamster cells

9-beta-D-Arabinosyladenine (araA)-resistant mutants of baby hamster kidney (BHK) cells can be classified into 3 classes. In order to gain a better understanding of the mechanism(s) of resistance and the biochemical basis of cytotoxicity of various purine nucleosides, cell hybrids of the mutant and wild-type cells were made and analyzed. The class I araA-resistant, adenosine-kinase-deficient (AK-) allele was shown to be recessive to the wild-type araA-sensitive (AK+) gene. The class II mutant allele, which encodes an altered ribonucleoside diphosphate reductase, was shown to be codominant. The class III mutants show multiple phenotypes, araAr/dAdor/adenosine sensitive (Ados) and alteration in AK activity. The araA- and dAdo-resistant alleles of araS10d, ara-16c, and ara-19a in class III mutant/wild-type hybrid cells are all recessive to the wild-type allele, consistent with a common mechanism of resistance. In contrast the Ados allele of ara-S10d is dominant while those of ara-16c and ara-19a are recessive. The difference may be a reflection of two distinct mechanisms of enhanced Ado sensitivity or, alternatively, it suggests that the sensitivity of the hybrids to Ado is highly dependent on the level of AK activity.     

Mutants of CHO cells resistant to the protein synthesis inhibitors, cryptopleurine and tylocrebrine: genetic and biochemical evidence for common site of action of emetine, cryptopleurine, tylocrebine, and tubulosine

Stable mutants resistant to the protein synthesis inhibitors cryptopleurine and tylocrebine can be isolated in Chinese hamster ovary (CHO) cells, in a single step. The frequency of occurrence of cryptopleurine (CryR) and tylocrebrine (TylR) resistant mutants in normal and mutagenized cell populations is similar to that observed for emetine resistant (EmtR) mutants. The CryR, TylR, and EmtR mutants exhibit strikingly similar cross-resistance to the three drugs used for selection, to tubulosine and also to two emetine derivatives cephaeline and dehydroemetine, based on assays of in vivo cytotoxicity and on assays of protein synthesis in cell-free extracts. The identity of cross-resistance patterns of the CryR, TylR, and EmtR mutants indicates that the resistance to all these compounds results from the same primary lesion, which in the case of EmtR cells has been shown to affect the 40S ribosomal subunit. This conclusion is strongly supported by the failure of EmtR, TylR, and CryR mutants to complement each other in somatic cell hybrids. Based on these results it is suggested that the above group of compounds possesses common structural determinants which are responsible for their activity. The above mutants, however, do not show any cross-resistance to other inhibitors of protein synthesis such as cycloheximide, trichodermin, anisomycin, pactamycin, and sparsomycin, either in vivo or in vitro, indicating that the site of action of these inhibitors is different from that of the emetine-like compounds.     

Inhibition of purine nucleoside phosphorylase and mitogen-stimulated transformation in immunocompetent murine spleen cells by formycin B.

Formycin B inhibits competitively purine nucleoside phosphorylase activity in murine spleen cell extracts. It also inhibits inosine phosphorolysis by intact spleen cells. Differentiation and proliferation of these cells, stimulated by concanavalin A or lipopolysaccharide, are appreciably reduced by culture with formycin B. Appreciable inhibition occurs at concentrations of formycin B which do not alter cell viability. The transformation of lipopolysaccharide-stimulated cells is more sensitive to inhibition by formycin B than that of concanavalin A-stimulated cells. Characterization of this system should increase our understanding of the relationship between purine nucleoside phosphorylase activity and immune responses.     

Purine excretion by mammalian cells deficient in adenosine kinase

An adenosine kinaseless (AK^?) mutant of the mouse fibroblast line 3T6 has been obtained in cell culture by evolution of resistance to 6-thio-methylpurine ribonucleoside and tubercidin. The mutant excretes purines (xanthine and hypoxanthine) into the culture medium. Human or mouse cells lacking hypoxanthine-guanine phosphoribosyl transferase (HPT^?) excrete increased amounts of purines, but a human cell mutant lacking both HPT and AK excretes considerably more hypoxanthine. The difference in hypoxanthine excretion between the HPT^? mutant and the HPT^? AK^? mutant originates from the adenosine normally reutilized through the activity of adenosine kinase. The activity of adenosine kinase is essential to retard the adenosine cycle and to prevent cellular loss of purines.     

Kinase-negative mutants of S49 mouse lymphoma cells carry a trans-dominant mutation affecting expression of cAMP-dependent protein kinase.

Kinase-negative mutants of S49 mouse lymphoma cells are pleiotropically negative for all known cAMP-mediated responses of S49 cells and yield cell extracts which are deficient in cAMP binding activity and devoid of cAMP-dependent protein kinase activity. In hybrids between kinase-negative and wild-type cells, the mutant phenotype is dominant: the tetraploid hybrids have reduced cAMP-binding activity and undetectable cAMP-dependent kinase activity. The mutant phenotype is attributable to neither a soluble inhibitor of kinase catalytic subunit, nor a defective kinase regulatory subunit acting as an inhibitor, nor a defective catalytic subunit which sequesters regulatory subunits in inactive complexes. We propose that these mutants carry trans-dominant lesions in a regulatory locus responsible for setting intracellular levels of kinase expression.     

Biological and biochemical characterisation of purine analogue resistant clones of V79 Chinese hamster cells

Purine analogue resistant clones have been selected from the closely related Chinese hamster lines V79A and V79S. Clones were of either spontaneous origin or induced by EMS or ultraviolet light. The majority of clones selected in 8-azaguanine showed stable cross resistance to 6-thioguanine. Clones derived from V79A and selected for 6-thioguanine resistance were cross resistant to 8-azaguanine: however a group of 6-thioguanine resistant mutants selected from V79S cells were 8-azaguanine sensitive. All clones except two were unable to grow in HAT medium. The two exceptions were 8-azaguanine resistant, showed partial sensitivity to 6-thioguanine, and also differed in other biochemical characteristics. HGPRT activity was measurable in extracts of all clones under standard conditions. In many clones, HGPRT activity increased as the hypoxanthine concentration was reduced. Whole cell uptake of [14C] hypoxanthine was low in all cases examined and was not modified by incubation in the presence of amethopterin. The heat sensitivity and electrophoretic mobility of HGPRT in extracts of some clones was compared to that in wild-type extracts. All clones tested except one, which was consistently HAT positive, showed enhanced heat sensitivity and reduced electrophoretic mobility. None of the mutants reverted spontaneously at detectable frequency but some could be induced to revert by EMS. The presence of measurable enzyme with altered properties in all clones suggests that these revertable drug resistant clones represent missense mutants.     

Biochemical genetic analysis of formycin B action in Leishmania donovani

Formycin B is cytotoxic toward Leishmania and is a potential chemotherapeutic agent for leishmaniasis. In order to determine the mechanism of action of formycin B, we have isolated and characterized clonal populations of formycin B-resistant Leishmania donovani. These formycin B-resistant clones are also cross-resistant to formycin A and allopurinol riboside-mediated growth inhibition. Incubation of the formycin B-resistant cells with [3H]formycin B indicates that, unlike wild type cells, the resistant populations cannot accumulate phosphorylated metabolites of exogenous [3H]formycin B. This is due to a defective transport system for formycin B in the resistant cells. However, wild type and mutant cells incorporate [3H]formycin A equally efficiently into [3H]formycin A-containing nucleotides and into RNA. These data suggest that formycin B cytotoxicity in Leishmania is not mediated by its incorporation as the adenosine analog into RNA. A plausible alternative hypothesis is proposed for the mechanism of action of the pyrazolo (4,3-d)pyrimidine C-nucleosides based upon depletion of an essential intracellular metabolite.     

Codominant expression of a mutation affecting the cAMP-dependent protein kinase catalytic subunit in somatic cell hybrids of LLC-PK1 cells

The LLC-PK1 mutant cell lines FIB4 and FIB6 are affected in the catalytic (C) subunit of cAMP-dependent protein kinase (cAMP-PK) such that they possess less than 10% parental activity. However, by Western blot analysis they were shown to possess normal levels of C subunit protein. Somatic cell hybrids were derived between mutant and LLC-PK1 cells, and examined for complementation of the cAMP-PK lesion. Codominant expression of mutant and normal alleles was observed, in that somatic cell hybrids between FIB4 and LLC-PK1, and between FIB6 and LLC-PK1 cells, exhibited cAMP-PK activity 60-75% that of LLC-PK1 cells, intermediate between mutant and normal parental cell lines. The cAMP-PK of the FIB6 x LLC-PK1 and FIB4 x LLC-PK1 hybrids was examined by ion exchange chromatography. In contrast to the FIB6 and FIB4 mutants which lack an active Type I cAMP-PK, the hybrids retained levels of active Type I cAMP-PK greater than 30% that of LLC-PK1, concomitant with the retention of catalytic activity. It was concluded that the loss of Type I kinase in the FIB6 and FIB4 mutants is most likely a consequence of the lesion in the cAMP-PK C subunit. All somatic cell hybrids examined showed levels of cAMP-PK C subunit (as determined by Western blot analysis), and in vivo regulation of cAMP-PK activation (in response to hormonal or nonreceptor-mediated stimulation of adenylate cyclase), completely comparable to those of the parental LLC-PK1 cells. Hence, no aberrant regulation of either cAMP-PK subunit levels or cAMP-PK activities was evident in the somatic cells hybrids. All data were consistent with the hypothesis that FIB4 and FIB6 contain a structural mutation affecting the cAMP-PK catalytic subunit that is expressed phenotypically in the presence of the normal allele.     

Pactamycin resistance in CHO cells: Morphological changes induced by the drug in the wild-type and mutant cells

Stable mutants resistant to pactamycin (Pac^R), a polypeptide chain initiation inhibitor, have been selected in a single step in Chinese hamster ovary (CHO) cells. The sensitivity of protein synthesis in mutant cell extracts to pactamycin indicates that resistance involves an alteration in the permeability of this drug. The failure of Pac^R mutants to show cross-resistance to other compounds provides further indication that the lesion is presumably specific for pactamycin. Cell hybrids formed between Pac^R × Pac^S lines show intermediate sensitivity towards pactamycin, suggesting that the Pac^R lesion behaves codominantly under these conditions. In the presence of subinhibitory concentrations of pactamycin, CHO cells, which are normally short, polygonal and disoriented, became greatly elongated and aligned themselves in parallel fashion to produce highly oriented colony morphologies, reminiscent of normal diploid fibroblasts. This effect of pactamycin on cellular morphology was seen much more clearly with the Pac^R mutants, although somewhat higher concentrations of the drug were required to produce this change.     

Abnormal regulation of de novo purine synthesis and purine salvage in a cultured mouse T-cell lymphoma mutant partially deficient in adenylosuccinate synthetase.

The isolation and characterization of a mutant murine T-cell lymphoma (S49) with altered purine metabolism is described. This mutant, AU-100, was isolated from a mutagenized population of S49 cells by virtue of its resistance to 0.1 mM 6-azauridine in semisolid agarose. The AU-100 cells are resistant to adenosine mediated cytotoxicity but are extraordinarily sensitive to killing by guanosine. High performance liquid chromatography of AU-100 cell extracts has demonstrated that intracellular levels of GTP, IMP, and GMP are all elevated about 3-fold over those levels found in wild type cells. The AU-100 cells also contain an elevated intracellular level of pyrophosphoribosylphosphate (PPriboseP), which as in wild type cells is diminished by incubation of AU-100 cells with adenosine. However AU-100 cells synthesize purines de novo at a rate less than 35% of that found in wild type cells. In other growth rate experiments, the AU-100 cell line was shown to be resistant to 6-thioguanine and 6-mercaptopurine. Levels of hypoxanthine-guanine phosphoribosyltransferase (HGPRTase) measured in AU-100 cell extracts, however, are 50-66% greater than those levels of HGPRTase found in wild type cell extracts. Nevertheless this mutant S49 cell line cannot efficiently incorporate labeled hypoxanthine into nucleotides since the salvage enzyme HGPRTase is inhibited in vivo. The AU-100 cell line was found to be 80% deficient in adenylosuccinate synthetase, but these cells are not auxotrophic for adenosine or other purines. The significant alterations in the control of purine de novo and salvage metabolism caused by the defect in adenylosuccinate synthetase are mediated by the resulting increased levels of guanosine nucleotides.     

An adenosine kinase mutation in baby hamster kidney cells causing increased sensitivity to adenosine

A class of aravinosyladenine (araA)-resistant mutants of baby hamster kidney (BHK 21/C13) cells exhibits multiple phenotypes: resistance to araA and deoxyadenosine, extreme sensitivity to adenosine (Ado) and varying degrees of deficiency in adenosine kinase (AK) activity. One of these Ado^s/araA^r strains, ara-S10d, was isolated without mutagenesis and was shown to possess about 59% level of the wild-type AK activity. The AK from ara-S10d had an altered K_m and pH optimum and was stimulated by K⁺ cations. A number of Ado^s to Ado^r revertants were isolated from araS10d, and in all of the 7 examined, the AK activity was reduced to a nondetectable level. The altered kinetic parameters of the AK enzyme in ara-S10d cells suggest a mutation of the AK gene that leads to the synthesis of an altered enzyme. The loss of AK activity in the Ado^r revertants suggests an association of the enhanced Ado sensitivity to the AK mutation.     

Immunochemical and catalytic characteristics of adenosine kinase from Leishmania donovani

Polyclonal antibodies to homogeneous preparation of adenosine kinase from Leishmania donovani were raised in rabbit. The antiserum was inhibitory and precipitated enzyme activity from both homogeneous and partially purified adenosine kinase from the parasite. However, the antiserum did not immunoprecipitate adenosine kinase of other higher eukaryotic sources tested so far. Immunoblot analysis of extracts from L. donovani and other sources revealed specific reaction of the antiserum with only the parasite enzyme. Under similar conditions, the enzyme monophosphorylated adenosine and 7-amino-3[beta-D-ribofuranosyl]-1H-pyrazolo[4,3-d]pyrimidine (formycin A) with almost equal efficiency, exhibiting Km values of 16 and 24 microM, respectively. The turnover number (Kcat) of the enzyme with both adenosine and formycin A was 24 s-1, whereas Kcat/Km yielded values of 1.5 and 1.0 microM-1 s-1, respectively. Substrate competition experiments indicated strong inhibition of [3H]formycin A phosphorylation by adenosine. In contrast, [3H]adenosine phosphorylation was insensitive to formycin A except at very high concentrations. The inhibitions of [3H]formycin A and [3H]adenosine phosphorylation by adenosine and formycin A were noncompetitive with respect to each other. Of the two nucleosides, adenosine was found to be effective in eluting the enzyme from the 5'-AMP Sepharose 4B column. Phosphorylation of [3H]formycin A was strongly inhibited by N-ethylmaleimide at concentrations which exerted minimal effect on [3H]adenosine phosphorylation. Adenosine exclusively, but not formycin A, protected the enzyme from N-ethylmaleimide-mediated inactivation. Taken together the results suggest that (a) adenosine kinase from L. donovani is immunologically distinct and (b) the enzyme possibly has two discrete catalytically active nucleoside interacting sites.