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Query: EC:3.1.3.5 (
5'-nucleotidase
)
3,167
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The present state of investigations on molecular and cellular mechanisms of cardioprotective effects of
phosphocreatine
(PCr) is reviewed. The protective effect of PCr is manifested as significant improvement of heart contractile function recovery, lowering of diastolic pressure elevation and myocardial enzymes release during postischemic reperfusion as well as better preservation of high energy phosphates in comparison with control. Data from multidisciplinary studies using physico-chemical, physiological, pharmacological etc. approaches suggest that one of the key mechanisms of PCr action is its interaction with the sarcolemmal membrane. The authors own data obtained with the use of spin-labeled ESR-probe incorporated into the isolated sarcolemmal vesicles provide direct evidence in favor of the ordering effect of PCr sarcolemmal phospholipid packing with essential involvement of Ca2+ ions. PCr transform membrane phospholipids into more structured gel-like state. The results of biomedical studies suggest that the mechanism of this protective action is complex and includes at least four components: 1) inhibition of lysophosphoglyceride accumulation in the ischemic myocardium and preservation of cardiac cell sarcolemma structure via zwitterionic interaction with PCr molecules; ii) extracellular action consisting in inhibition of platelet aggregation via ADP removal in the extracellular creatine kinase reaction and increasing plasticity of red blood cells; iii) PCr penetration into cells maintenance of high local ATP levels is possible; iiii) inhibition of adenine nucleotide degradation at the step of
5'-nucleotidase
reaction in cardiac cell sarcolemma.
...
PMID:[Molecular and cellular aspects of the cardioprotective mechanism of phosphocreatine]. 129 51
Changes in
5'-nucleotidase
activity were calculated on the basis of alterations in ATP, ADP,
phosphocreatine
, Pi, Mg2+, IMP and AMP, determined by using 31P n.m.r. spectroscopy and h.p.l.c., during isoprenaline infusion, graded hypoxia and graded underperfusion in isolated rat heart. Calculated activity changes were compared with the total efflux of purines (adenosine + inosine + hypoxanthine) in order to assess the involvement of various 5'-nucleotidases in formation of adenosine. Purine efflux exhibited an exponential relation with cytosolic [AMP] during isoprenaline infusion and hypoxia (r = 0.92 and 0.95 respectively), supporting allosteric activation of
5'-nucleotidase
under these conditions. Purine efflux displayed a linear relation with cytosolic [AMP] during graded ischaemia (r = 0.96), supporting substrate regulation in the ischaemic heart. The calculated activities of membrane-bound ecto-5'-nucleotidase were similar to the observed relations between purine efflux and cytosolic [AMP] in all hearts. The calculated activities of the ATP-activated cytosolic and lysosomal enzymes and of the ATP-inhibited cytosolic
5'-nucleotidase
could not explain the observed release of purines under the conditions examined. These results indicate that the kinetic characteristics of the membrane-bound ecto-enzyme are consistent with an important role in the formation of extracellular adenosine, whereas the characteristics of the other 5'-nucleotidases are inconsistent with roles in adenosine formation under the conditions of the present study.
...
PMID:5'-Nucleotidase activity and adenosine formation in stimulated, hypoxic and underperfused rat heart. 254 75
The uptake of 32P-
phosphocreatine
by control and ischemic isolated perfused rat hearts has been studied. The rate of
phosphocreatine
(PCr) uptake by the hearts after 35 minutes of ischemia was two times that in control hearts at 0.5-10 mM PCr in the perfusate. At 10 mM PCr in the perfusate, this rate was 182 nmoles/min/g dry weight. The
5'-nucleotidase
and phosphatase activities were found in the crude plasma membrane fraction of rat heart. The pH-dependence of these enzymes was examined. The
5'-nucleotidase
activity decreased with a drop in pH from 8.0 to 6.0. The phosphatase activity in the crude plasma membrane fraction of rat heart was increased 2-fold with a decrease in pH from 8.0 to 6.0. The
5'-nucleotidase
activity was inhibited by 10 mM PCr in the presence of 5 mM Mg2+. This inhibition was pH-dependent with a maximum (58%) at pH 6.0. The inhibition of phosphatase activity by PCr was independent of pH and reached 20% in the presence of 10 mM PCr. Some feasible mechanisms of the protective effect of PCr on ischemic myocardium are discussed.
...
PMID:[Possible mechanism of the protective effect of phosphocreatine on the ischemic myocardium]. 301 Nov 27
3-Phosphono-2-imino-1-methyl-4-oxoimidazolidine (PIMOI), AMP and p-nitrophenyl phosphate (pNPP) were dephosphorylated in the presence of rat heart cytosol at 37 degrees C pH 6.3 at the rates of 0.71, 0.45 and 1.07 mumol/mg X h, respectively. When mixed together, these compounds inhibited the hydrolysis of each other, which points to the participation of common enzyme(s) in this process. The inhibitor of
5'-nucleotidase
(alpha,beta-methylene)-ADP, did not affect PIMOI cleavage and moderately inhibited AMP hydrolysis (by ADP, did not affect PIMOI cleavage and moderately inhibited AMP hydrolysis (by 30-50%), thus suggesting that acidic phosphatases are responsible for PIMOI and AMP hydrolysis under these conditions (pH 6.3).
Phosphocreatine
(PCr) and phosphocyclocreatine (PcCr) were stable to hydrolysis by the cytosolic fraction. However, addition of AMP to the medium containing PCr or PcCr resulted in AMP phosphorylation down to ATP due to the effects of these phosphagens and, probably, of microcontaminations of ATP. This was followed by gradual disappearance of PCr or PcCr and by accumulation of Pi as a result of the "ATPase" activity in the cytosol. The hydrolysis of AMP, PIMOI and p-NPP was sensitive to sulfhydryl reagents [5,5'-dithio-bis-(2-nitrobenzoate) and, in part, 2,4-dinitro-fluorobenzene] and fluoride ion. Thus, PIMOI is a competitive substrate of acidic phosphatases in heart cytosol with respect to AMP and p-NPP. This may partly explain the protective effect of PIMOI on ischemic myocardium.
...
PMID:[3-Phosphono-2-imino-4-oxoimidazoline--a competitive substrate of AMP-dephosphorylating enzymes from the cytosol fraction of the rat heart]. 359 90
Creatine phosphate
does not inhibit
5'-nucleotidase
preparations from rat, dog or guinea-pig hearts. Previously reported inhibitory effects must have been due to contaminants present in some commercial preparations of creatine phosphate.
...
PMID:Creatine phosphate inhibition of heart 5'-nucleotidase appears due to contaminants. 631 31
The hydrolysis of AMP to adenosine during acute coronary underperfusion is temporarily beneficial to myocardial survival yet may cause tissue injury during sustained underperfusion because of depletion of adenine nucleotides. We hypothesized that the enzyme mediating AMP hydrolysis,
5'-nucleotidase
(5'-NT), is downregulated during sustained coronary underperfusion to prevent excessive loss of nucleotides. Langendorff-perfused rabbit hearts were subjected to two successive, identical 45-min periods of underperfusion (4-5% of baseline flow) separated by 20 min of reperfusion. Although coronary venous lactate efflux was comparable in the two periods, total coronary purine efflux during the second period of underperfusion was attenuated by 75%. Phosphorus nuclear magnetic resonance data showed that ATP fell 46% in the first period but fell only another 10% in the second period.
Phosphocreatine
levels fell comparably (75-78%) during both periods of underperfusion. Analysis using a mathematical model describing the kinetics of myocardial energetics revealed that the combined data set was best described by a lower activity of 5'-NT (52% decrease in maximal reaction velocity) during the second period of under-perfusion. Additional time course experiments showed that the decrease in 5'-NT activity was slow in onset, requiring approximately 20 min of underperfusion. The decrease in 5'-NT activity during sustained underperfusion may benefit tissue survival by limiting the depletion of myocardial adenine nucleotides. In conclusion, at the onset of coronary underperfusion, there is a high activity of 5'-NT, but later during sustained under-perfusion, 5'-NT is downregulated, resulting in decreased AMP hydrolysis to adenosine.
...
PMID:Downregulation of 5'-nucleotidase in rabbit heart during coronary underperfusion. 948 57
