Enzymes allosteric regulations

The main differences between direct allosteric control of an enzyme (allosteric regulator interacts directly with the enzyme to be regulated) and control through covalent modification are ... 

Allosteric regulation acts to modulate enzymes situated at key steps in metabolic pathways. Consider as an illustration the following pathway, where A is the precursor for formation of an end product, F, in a sequence of five enzyme-catalyzed reactions ... 

Metabolic regulation is achieved via regulating enzyme activity in three prominent ways allosteric regulation, covalent modi-... 

The hydrolysis of fructose-1,6-bisphosphate to fructose-6-phosphate (Eigure 23.7), like all phosphate ester hydrolyses, is a thermodynamically favorable (exergonic) reaction under standard-state conditions (AG° = —16.7 kj/mol). Under physiological conditions in the liver, the reaction is also exergonic (AG = —8.6 kJ/mol). Fructose-1,6-bisphosphatase is an allosterically regulated enzyme. Citrate stimulates bisphosphatase activity, hut fructose-2,6-bisphosphate is a potent allosteric inhibitor. / MP also inhibits the bisphosphatase the inhibition by / MP is enhanced by fructose-2,6-bisphosphate. 

In die metabolic pathway to an amino add several steps are involved. Each step is die result of an enzymatic activity. The key enzymatic activity (usually die first enzyme in the synthesis) is regulated by one of its products (usually die end product, eg die amino add). If die concentration of die amino add is too high die enzymatic activity is decreased by interaction of die inhibitor with the regulatory site of die enzyme (allosteric enzyme). This phenomenon is called feedback inhibition. 

This reaction is followed by another phosphorylation with ATP catalyzed by the enzyme phosphofructoki-nase (phosphofructokinase-1), forming fructose 1,6-bisphosphate. The phosphofructokinase reaction may be considered to be functionally irreversible under physiologic conditions it is both inducible and subject to allosteric regulation and has a major role in regulating the rate of glycolysis. Fructose 1,6-bisphosphate is cleaved by aldolase (fructose 1,6-bisphosphate aldolase) into two triose phosphates, glyceraldehyde 3-phosphate and dihydroxyacetone phosphate. Glyceraldehyde 3-phosphate and dihydroxyacetone phosphate are inter-converted by the enzyme phosphotriose isomerase. 

Changes in enzyme levels and allosteric regulation of carbamoyl phosphate synthase by A -acetylglutamate regulate urea biosynthesis. 

Aiming at a computer-based description of cellular metabolism, we briefly summarize some characteristic rate equations associated with competitive and allosteric regulation. Starting with irreversible Michaelis Menten kinetics, the most common types of feedback inhibition are depicted in Fig. 9. Allowing all possible associations between the enzyme and the inhibitor shown in Fig. 9, the total enzyme concentration Er can be expressed as... 

To account for positive cooperativity and sigmoidal rate equations, a number of theoretical models for allosteric regulation have been developed. Common to most models is the assumption (and requirement) that enzymes act as multimers and exhibit interactions between the units. We briefly mention the most... 

Figure 11. Allosteric regulation A conformational change of the active site of an enzyme induced by reversible binding of an effector molecule (A). The model of Monod, Wyman, and Changeux (B) Cooperativity in the MWC is induced by a shift of the equilibrium between the T and R state upon binding of the receptor. Note that the sequential dissociation constants Kr and KR do not change. The T and R states of the enzyme differ in their catalytic properties for substrates. Both plots are adapted from Ref. 140. See color insert.

Phosphorylase was studied in depth. The enzyme from muscle was different from that catalyzing the same reaction in liver. Muscle phosphorylase but not that from liver, was activated by AMP, an early example of enzyme regulation by a ligand which was not a substrate. [Allosteric regulation was not postulated until the work of Jacob and... 

Allosteric regulators bind to the target enzyme in a non-covalent manner. An entirely different enzyme control mechanism is covalent modification. Here, the conformation of the enzyme protein, and thereby its activity, is changed by the... 

Where the pathway generates an allosteric regulator, the opportunity for feedback or indeed feed-forward control arises. Feedback control is exerted by a product of the pathway and acts to switch off a key control enzyme when the concentration of the product reaches a threshold. This indicates the cell contains enough of that particular... 

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