Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
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Target Concepts:
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Query: UMLS:C0023418 (
leukemia
)
93,477
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The basis for the antitumor activities of the exocyclic amino nucleosides 4-amino-(ARPP) and 4-methoxy-8-(D-ribofuranosylamino)pyrimido[5,4-d]pyrimidine (MRPP) was investigated. The primary target of these nucleosides appeared to be 5-phospho-alpha-D-ribofuranose-1-pyrophosphate (PRPP) synthetase. MRPP-5'-monophosphate was a competitive inhibitor (Ki = 40 microM) of the activation of this enzyme by the cofactor inorganic phosphate (K alpha = 2.2 mM). Consequently, ARPP and MRPP treatment of WI-L2 cultures rapidly inhibited both de novo pyrimidine and purine synthesis as well as the nucleotide salvage reactions dependent on PRPP, ARPP or MRPP treatment completely prevented [14C]bicarbonate incorporation into acid-soluble pyrimidine and purine nucleotides. The rate of salvage of [8-14C]hypoxanthine to form IMP was decreased by 85%. Treatment of cells with these agents caused a 50% reduction in the steady-state level of PRPP. When the capacity of the treated cells for sustained synthesis of PRPP was examined by adenine incorporation, the rate of adenine uptake was inhibited by greater than 50%. In vivo treatment of BDF1 mice with a single dose of ARPP (173 mg/kg) or MRPP (62 mg/kg) extended the mean life span of the mice, which had been inoculated intraperitoneally 1 day earlier with 1 x 10(6) L1210 murine
leukemia
cells, by 62 and 82% respectively. These studies indicate that MRPP and ARPP inhibit
PRPP synthetase
, and that
PRPP synthetase
may be a viable target in the development of certain antitumor agents.
...
PMID:Inhibition of phosphoribosylpyrophosphate synthetase by 4-methoxy-(MRPP) and 4-amino-8-(D-ribofuranosylamino) pyrimido[5,4-d]pyrimidine (ARPP). 247 82
1. APP is activated by adenosine kinase to its 5'-phosphate (APP-MP). 2. APP-MP inhibits
PRPP synthetase
, and depletes cellular PRPP and purine and pyrimidine nucleotides. 3. APP inhibits synthesis of DNA and RNA, and blocks cells in G1 phase of the cell cycle. 4. APP retains full activity against MDR cells. 5. APP is equally active against quiescent and proliferating CHO cells. 6. APP has only weak activity against L1210
leukemia
in vivo, but has substantial activity against mammary carcinoma 16/c. 7. In vitro, APP has a relatively high ratio of solid tumor:
leukemia
activity.
...
PMID:Biochemical pharmacology and antitumor properties of 4-amino-8-[beta-D-ribofuranosylamino]pyrimido-[5,4-d]pyrimidine. 256 Mar 25
Phosphoribosylpyrophosphate (PRPP) is essential for the formation of both purine and pyrimidine nucleotides as well as for the active nucleotide form of some chemotherapeutic agents. The formation of PRPP is catalyzed by by enzyme
PRPP synthetase
, and many different compounds are known to affect the activity of this enzyme. This report examines the effects of endogenous purine and pyrimidine nucleotides, nucleosides, and several analogs of these compounds on the activity of
PRPP synthetase
from different types of normal and leukemic white blood cells (i.e. normal lymphocytes, normal granulocytes, phytohemagglutinin-stimulated lymphocytes, and acute and chronic leukemic cells). Our results show that the effect varied with each individual compound, and the magnitude of the effect was dependent on the source of the enzyme. Since it appears possible to differentially affect
PRPP synthetase
activity from the different types of leukemic cells, this enzyme may be a potential target site in the chemotherapy of
leukemia
.
...
PMID:Regulation of phosphoribosylpyrophosphate synthetase by endogenous purine and pyrimidine compounds and synthetic analogs in normal and leukemic white blood cells. 628 31
Although gout and hyperuricaemia are usually thought of as conditions of indulgent male middle age, in addition to the well-known uricosuria of the newborn, there is much of importance for the paediatric nephrologist in this field. Children and infants may present chronically with stones or acutely with renal failure from crystal nephropathy, as a result of inherited deficiencies of the purine salvage enzymes hypoxanthine-guanine phosphoribosyltransferase (HPRT) and adenine phosphoribosyltransferase (APRT) or of the catabolic enzyme xanthine dehydrogenase (XDH). Genetic purine overproduction in
phosphoribosylpyrophosphate synthetase
superactivity, or secondary to glycogen storage disease, can also present in infancy with renal complications. Children with APRT deficiency may be difficult to distinguish from those with HPRT deficiency because the insoluble product excreted, 2,8-dihydroxyadenine (2,8-DHA), is chemically very similar to uric acid. Moreover, because of the high uric acid clearance prior to puberty, hyperuricosuria rather than hyperuricaemia may provide the only clue to purine overproduction in childhood. Hyperuricaemic renal failure may be seen also in treated childhood
leukaemia
and lymphoma, and iatrogenic xanthine nephropathy is a potential complication of allopurinol therapy in these conditions. The latter is also an under-recognised complication of treatment in the Lesch-Nyhan syndrome or partial HPRT deficiency. The possibility of renal complications in these three situations is enhanced by infection, the use of uricosuric antibiotics and dehydration consequent upon fever, vomiting or diarrhoea. Disorders of urate transport in the renal tubule may also present in childhood. A kindred with X-linked hereditary nephrolithiasis, renal urate wasting and renal failure has been identified, but in general, the various rare types of net tubular wasting of urate into the urine are recessive and relatively benign, being found incidentally or presenting as colic from crystalluria. However, the opposite condition of a dominantly inherited increase in net urate reabsorption is far from benign, presenting as familial renal failure, with hyperuricaemia either preceding renal dysfunction or disproportionate to it. Paediatricians need to be aware of the lower plasma urate concentrations in children compared with adults when assessing plasma urate concentrations in childhood and infancy, so that early hyperuricosuria is not missed. This is of importance because most of the conditions mentioned above can be treated successfully using carefully controlled doses of allopurinol or means to render urate more soluble in the urine. Xanthine and 2,8-DHA are extremely insoluble at any pH. Whilst 2,8-DHA formation can also be controlled by allopurinol, alkali is contraindicated. A high fluid, low purine intake is the only possible therapy for XDH deficiency.
...
PMID:Gout, uric acid and purine metabolism in paediatric nephrology. 843 71
Most of the primates, unlike other mammals, have mutations in urate oxidase gene and cannot catabolize urate in the bodies. In addition to the genetic defects, some human subjects have various abnormalities in urate metabolism. Urate metabolism abnormalities are classified into two categories, hyperuricemia and hypouricemia. Usually, the urate pool size of an adult male is about 1,200 mg, and 700 mg urate is produced daily. The production is balanced by the excretion of urate into urine (500 mg) and intestine (200 mg). If this balance is disturbed, either hyperuricemia or hypouricemia occurs. According to the mechanisms, hyperuricemia is classified into overproduction and underexcretion, and hypouricemia into underproduction and overexcretion. Overproduction of ruate is caused by
PRPP synthetase
superactivity, HPRT deficiency,
leukemia
and alcohol ingestion. Underexcretion of urate is caused by renal insufficiency and treatment by diuretics. Underproduction of urate is caused by xanthine dehydrogenase deficiency, purine nucleoside deficiency and allopurinol treatment. Overexcretion of urine is caused by familial renal hypouricemia, Fanconi's syndrome, diabetes mellitus and treatments with benzbromarone and probenecid. All of these conditions are classified, according to other aspects, into primary and secondary, and genetic and non-genetic abnormalities.
...
PMID:[Abnormalities in urate metabolism: concept and classification]. 897 99
