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Enzyme
Compound
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Target Concepts:
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Query: EC:1.5.1.3 (
dihydrofolate reductase
)
5,819
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
High speed centrifugal supernatant fractions of homogenates of a number of trypanosomatids were assayed for thymidylate synthase (5,10-methylene-tetrahydrofolate: dUMP C-methyltransferase, EC 2.1.1.45) activity using the method of Lomax and Greenberg (1967) J. Biol. Chem. 242, 109-113). Similar activities were detected in Crithidia fasciculata, Crithidia oncopelti, the blood forms of Trypanosoma brucei, Trypansoma congolense and Trypanosoma lewisi and the blood, intracellular and culture forms of Trypanosoma cruzi, suggesting that all species synthesize at least some thymidylate de novo. The properties of the activities in C. fasciculata and the three forms of T. cruzi were compared with those of the isofunctional bacterial and mammalian enzymes. The trypanosotamid enzyme was inhibited by
Mg2+
, was much more sensitive to mercaptoethanol, had higher apparent Km values for substrate (dUMP) and cofactor (tetrahydrofolate), had a higher apparent molecular weight and was markedly more sensitive to inhibition by suramin. It is, therefore a possible target for chemotherapeutic attack, either on its own or in combination with a
dihydrofolate reductase
inhibitor. No evidence was obtained for the regulation of the trypanosomatid enzyme, either by its product, dTMP, or by dTDP or dTTp. This result agrees with previous studies which suggested that in trypanosomatids, the level of dTMP was regulated, at least in part, by a catabolic pathway consisting of a thymidylate phosphatase and a thymidine phosphorylase which degraded the excess of dTMP to thymine.
...
PMID:Presence and properties of thymidylate synthase in trypanosomatids. 1 96
Drug-monoclonal antibody conjugates have been evaluated for their specificity and toxicity towards tumour cells in vitro and in vivo; however, few studies have investigated their mode of entry into cells and mechanism of action. In this study the uptake and toxic effect of three different Methotrexate-monoclonal antibody (MTX-MoAb) conjugates (MTX-anti-transferrin receptor (TFR), MTX-anti-Ly-2.1 and MTX-anti-L3T4) were examined and compared with free MTX. It was concluded that MTX and these MTX-MoAb conjugates gain entry into tumour cells and are processed by different mechanisms, considering the following results: alterations in temperature had a greater effect on the toxicity of MTX-MoAb than on MTX; in addition, MTX and MTX-MoAb had different rates of action on cells; the specific MTX transport inhibitor, p-chloromercuribenzene sulphonate (pCMS), reduced MTX toxicity but had no effect on specific MTX-MoAb conjugates; the concentration of various ions (Ca2+,
Mg2+
and Mn2+) effected the entry of MTX-MoAb but had no effect on free MTX. MTX enters by its own carrier mechanism, while MTX-MoAb conjugates enter by endocytosis with release of MTX at the lysosomal membrane, demonstrated by the ability of chloroquine and NH4Cl (which inhibit lysosomal function) to inhibit the action of MTX-MoAb but not MTX. Therefore, these MTX-MoAb conjugates are not degraded at the surface but bind to their receptor and then enter the cell by endocytosis as one entity; the MTX-MoAb conjugates are then degraded within the lysosomes, resulting in the release of free MTX into the cytoplasm where it acts on
dihydrofolate reductase
(
DHFR
) to inhibit cell metabolism.
...
PMID:The mode of action of methotrexate-monoclonal antibody conjugates. 361 Feb 18
Ligand-induced conformational changes of GroEL alone and with bound rhodanese, citrate synthase, or
dihydrofolate reductase
were studied by limited proteolysis. Similar digestion patterns of GroEL, with or without bound substrate polypeptide, were obtained in the absence and presence of the chaperonin ligands, K+,
Mg2+
, or ATP. The rates of formation and degradation of the six produced proteolytic fragments were significantly different, however. Strikingly, only with
Mg2+
/ATP or K+/
Mg2+
/ATP an additional fragment of approximately 25 kDa was generated during digestion of GroEL alone or with bound rhodanese or
dihydrofolate reductase
, but not with bound citrate synthase. Most of the trypsin-sensitive sites in GroEL were localized in the flexible apical domain, which contains the putative polypeptide-binding region. Our data indicate that subtle structural changes in the trypsin-sensitive regions of GroEL occur as a result of the binding of the chaperonin ligands. However, these structural changes are influenced by the GroEL substrate polypeptides.
...
PMID:Ligand-induced conformational changes of GroEL are dependent on the bound substrate polypeptide. 866 87
For use of ribozymes in vivo, it is desirable to select functional ribozymes in the cellular environment (in the presence of inhibitory factors and limited concentrations of mandatory
Mg2+
ions, etc.). As a first step toward this goal, we developed a new screening system for detection in vivo of an active ribozyme from pools of active and inactive ribozymes using the gene for
dihydrofolate reductase
(
DHFR
) as a selective marker. In our
DHFR
expression vector, the sequence encoding either the active or the inactive ribozyme was connected to the
DHFR
gene. The plasmid was designed such that, when the ribozyme was active, the rate of production of
DHFR
was high enough to endow resistance to trimethoprim (TMP). We demonstrated that the active ribozyme did indeed cleave the primary transcript in vivo, whereas the inactive ribozyme had no cleavage activity. Cells that harbored the active-ribozyme-coding plasmid grew faster in the presence of a fixed concentration of TMP than the corresponding cells that harbored the inactive-ribozyme-coding plasmid. Consequently, when cells were transformed by a mixture that consisted of active- and inactive-ribozyme-coding plasmids at a ratio of 1:1, (i) mainly those cells that harbored active ribozymes survived in the presence of TMP and (ii) both active- and inactive-ribozyme-harboring cells grew at an identical rate in the absence of TMP, a demonstration of a positive selection system in vivo. If the background "noise" can be removed completely in the future, the selection system might usefully complement existing selection systems in vitro.
...
PMID:Discrimination of a single base change in a ribozyme using the gene for dihydrofolate reductase as a selective marker in Escherichia coli. 901 92
Previous investigation has shown that at 22 degrees C and in the presence of the chaperonin GroEL, the slowest step in the refolding of Escherichia coli
dihydrofolate reductase
(EcDHFR) reflects release of a late folding intermediate from the cavity of GroEL (Clark AC, Frieden C, 1997, J Mol Biol 268:512-525). In this paper, we investigate the effects of potassium, magnesium, and MgADP on the release of the EcDHFR late folding intermediate from GroEL. The data demonstrate that GroEL consists of at least two conformational states, with apparent rate constants for EcDHFR release that differ by four- to fivefold. In the absence of potassium, magnesium, and ADP, approximately 80-90% of GroEL resides in the form with the faster rate of release.
Magnesium
and potassium both shift the distribution of GroEL forms toward the form with the slower release rate, though cooperativity for the magnesium-induced transition is observed only in the presence of potassium. MgADP at low concentrations (0-50 microM) shifts the distribution of GroEL forms toward the form with the faster release rate, and this effect is also potassium dependent. Nearly identical results were obtained with a GroEL mutant that forms only a single ring, demonstrating that these effects occur within a single toroid of GroEL. In the presence of saturating magnesium, potassium, and MgADP, the apparent rate constant for the release of EcDHFR from wild-type GroEL at 22 degrees C reaches a limiting value of 0.014 s(-1). For the single ring mutant of GroEL, the rate of EcDHFR release under the same conditions reaches a limiting value of 0.024 s(-1), suggesting that inter-ring negative cooperativity exists for MgADP-induced substrate release. The data suggest that MgADP preferentially binds to one conformation of GroEL, that with the faster apparent rate constant for EcDHFR release, and induces a conformational change leading to more rapid release of substrate protein.
...
PMID:Cooperative effects of potassium, magnesium, and magnesium-ADP on the release of Escherichia coli dihydrofolate reductase from the chaperonin GroEL. 1054 63
