Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
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Gene/Protein
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Target Concepts:
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Query: EC:2.6.1.19 (
GABA transaminase
)
808
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Because of the importance of the inactivation of
GABA aminotransferase
to the design of anticonvulsant agents, a seemingly wide variety of inactivators has been investigated; all of the compounds, however, are analogues of GABA, beta-alanine, or delta-aminovaleric acid, which are substrates for the enzyme. Relatively minor modifications in the inactivator structures result in major differences in inactivation mechanisms and enzyme adduct structures. Compounds that inactivate
GABA aminotransferase
by a Michael addition mechanism, leading to modification of an active-site residue are Class I inactivators. Those that proceed by an enamine mechanism and give ternary adducts are Class II inactivators. Class III inactivators modify only the PLP cofactor; if the inactivation involves aromatization of the inactivator, it is a Class IIIA inactivation, and if no aromatization is involved, then it is a Class IIIB inactivation. The last class of inactivators (Class IV) are not classified on the basis of the mechanism, but, rather, that they require the enzyme to be in the
PMP
form. There appears to be no trend in partition ratio values when comparing Class I with Class II inactivators. Class III inactivations alter only the cofactor, so it may be possible for these adducts to diffuse slowly out of the active site; reactivation of the apoenzyme would require additional PLP. These inactivators also inactivate a variety of other PLP-dependent enzymes. At this point there does not seem to be a therapeutic advantage of one class of inactivators over another, although the only current example of these inactivators to be useful clinically is gamma-vinyl GABA (vigabatrin), a Class I inactivator recently approved for the drug market in France and the U.K. There is a mechanistic significance, however, for one class over another. If labeling of an active-site amino acid residue is desired, then Class I inactivators should be selected; desire for attachment of the inactivator to both the protein and the cofactor or just to the cofactor would determine whether Class II or Class III inactivators would be chosen. The classification presented here should allow us to think about inactivator structures in terms of their mechanistic potential and, as a result of this, should afford us the opportunity to be able to make predictions regarding inactivation mechanisms for hypothetical new structural classes of inactivators. Since the different mechanistic pathways lead to different types of enzyme adducts, inactivator design may be driven by the class of adduct that is desired.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Design of potential anticonvulsant agents: mechanistic classification of GABA aminotransferase inactivators. 268 82
(Z)-4-Amino-2-fluorobut-2-enoic acid (1) is shown to be a mechanism-based inactivator of pig brain
gamma-aminobutyric acid aminotransferase
. Approximately 750 inactivator molecules are consumed prior to complete enzyme inactivation. Concurrent with enzyme inactivation is the release of 708 +/- 79 fluoride ions; transamination occurs 737 +/- 15 times per inactivation event. Inactivation of [3H]pyridoxal 5'-phosphate ([3H]PLP) reconstituted
GABA aminotransferase
by 1 followed by denaturation releases [3H]
PMP
with no radioactivity remaining attached to the protein. A similar experiment carried out with 4-amino-5-fluoropent-2-enoic acid [Silverman, R. B., Invergo, B. J., & Mathew, J. (1986) J. Med. Chem. 29, 1840-1846] as the inactivator produces no [3H]
PMP
; rather, another radioactive species is released. These results support an inactivation mechanism for 1 that involves normal catalytic isomerization followed by active site nucleophilic attack on the activated Michael acceptor. A general hypothesis for predicting the inactivation mechanism (Michael addition vs enamine addition) of
GABA aminotransferase
inactivators is proposed.
...
PMID:Inactivation of gamma-aminobutyric acid aminotransferase by (Z)-4-amino-2-fluorobut-2-enoic acid. 339 Apr 32
A homogeneous
4-aminobutyrate aminotransferase
isolated from pig brain exhibits a kcat = 9.6 s-1 and contains only 1 mol of pyridoxal-5-P/mol of dimer. The equilibrium dissociation constant for pyridoxal-5-P tightly bound to the enzyme is 1 nM. Spectrophotometric titrations reveal that the enzyme binds a second molecule of pyridoxal-5-P with a KD = 3 microM. The reaction of enzyme containing 1 pyridoxal-5-P/dimer with the inhibitors NaBH4 and DL-gabaculine was studied by observing changes in the absorption spectrum of the bound coenzyme and by monitoring loss of catalytic activity. The native enzyme is inactivated by both inhibitors. Incubation of the resultant P-pyridoxyl aminotransferase and m-anthraniyl-
PMP
-aminotransferase with excess pyridoxal-5-P at 25 degrees C restores full catalytic activity. It is postulated that the dimeric enzyme contains two classes of catalytic binding sites, and that the binding site characterized by a weak affinity for pyridoxal-5-P (KD = 3 microM) becomes functional after specific chemical modification of the molecule of cofactor tightly bound to the protein (KD - 1 nM).
...
PMID:4-Aminobutyrate aminotransferase. The presence of nonequivalent binding sites. 745 92
The mechanism of inactivation of
gamma-aminobutyric acid aminotransferase
(
GABA-AT
) by L-3-chloroalanine hydroxamate (1) was investigated. Inactivation of [3H]PLP-reconstituted
GABA-AT
with 1 followed by denaturation gave no
PMP
or enamine adduct to the PLP; however, a new unknown metabolite was observed which was identical to the metabolite formed upon inactivation of
GABA-AT
by L-cycloserine. Time-dependent inactivation occurs, but the kinetics are second order; the rate of inactivation increases with time. After inactivation occurs the addition of fresh enzyme results in a faster rate of inactivation than prior to the initial inactivation. This indicates that the actual inactivator is generated from L-3-chloroalanine hydroxamate, and is not L-3-chloroalanine hydroxamate itself. Added gabaculine-inactivated enzyme to fresh enzyme does not increase the rate of inactivation, suggesting that the conversion of L-3-chloroalanine hydroxamate to the active form is not catalyzed by peripheral amino acid residues. L-3-Chloroalanine hydroxamate was shown to undergo buffer-catalyzed cyclization to L-cycloserine, which is the actual inactivator of
GABA-AT
.
...
PMID:Inactivation of gamma-aminobutyric acid aminotransferase by L-3-chloroalanine hydroxamate. 861 42
