Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:2.7.1.1 (
hexokinase
)
5,274
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The ATPase cycle of GroE chaperonins has been examined by transient kinetics to dissect partial reactions in complexes where GroEL is asymmetrically loaded with nucleotides. The occupation of one heptameric ring by ADP does not inhibit the loading of the other with ATP nor does it prevent the consequent structural rearrangement to the "open" state. However, ADP binding completely inhibits ATP hydrolysis in the asymmetric complex, i.e. ATP cannot by hydrolysed when ADP is bound to the other ring. This non-competitive inhibition of the ATPase by ADP is consistent with a ring-switching, or "two-stroke", mechanism of the type: ATP:GroEL --> ADP:GroEL --> ADP:GroEL:ATP --> GroEL:ATP --> GroEL:ADP, i.e. with respect to the GroEL rings, ATP turns over in an alternating fashion. When the ATP-stabilized, "open" state is challenged with
hexokinase
and glucose, to quench the free ATP, the open state relaxes slowly (0.44 s-1) back to the apo (or closed) conformation. This rate, however, is three times faster than the hydrolytic step, showing that bound ATP is not committed to hydrolysis. When
GroES
is bound to the GroEL:ATP complex and the system is quenched in the same way, approximately half of the bound ATP undergoes hydrolysis on the chaperonin complex showing that the co-protein increases the degree of commitment. Thus, non-competitive inhibition of ATP hydrolysis, combined with the ability of the co-protein to block ligand exchange between rings has the effect of imposing a reciprocating cycle of reactions with ATP hydrolysing, and
GroES
binding, on each of the GroEL rings in turn. Taken together, these data imply that the dominant, productive steady state reaction in vivo is: GroEL:ATP:
GroES
--> GroEL:ADP:
GroES
--> ATP:GroEL:ADP:
GroES
--> ATP:GroEL:ADP -->
GroES
:ATP:GroEL:ADP -->
GroES
:ATP:GroEL for a hemi-cycle, and that significant inhibi tion of hydrolysis may arise through the formation of a dead-end ADP:GroEL:ATP:
GroES
complex.
...
PMID:Asymmetry, commitment and inhibition in the GroE ATPase cycle impose alternating functions on the two GroEL rings. 957 Oct 49
The double ring chaperonin GroEL binds unfolded protein, ATP, and
GroES
to the same ring, generating the cis ternary complex in which folding occurs within the cavity capped by
GroES
(cis folding). The functional role of ATP, however, remains unclear since several reports have indicated that ADP and AMPPNP (5'-adenylyl-beta,gamma-imidodiphosphate) are also able to support the formation of the cis ternary complex and the cis folding. To minimize the effect of contaminated ATP and adenylate kinase, we have included
hexokinase
plus glucose in the reaction mixtures and obtained new results. In ADP and AMPPNP,
GroES
bound quickly to GroEL but bound very slowly to the GroEL loaded with unfolded rhodanese or malate dehydrogenase. ADP was unable to support the formation of cis ternary complex and cis folding. AMPPNP supported cis folding of malate dehydrogenase to some extent but not cis folding of rhodanese. In the absence of
hexokinase
, apparent cis folding of rhodanese and malate dehydrogenase was observed in ADP and AMPPNP. Thus, the exclusive role of ATP in generation of the cis ternary complex is now evident.
...
PMID:Discrimination of ATP, ADP, and AMPPNP by chaperonin GroEL: hexokinase treatment revealed the exclusive role of ATP. 1273 70
