Enzymes calmodulin

An example for the reversible association of activator proteins with an enzyme is the Ca -calmodulin dependent enzymes. Calmodulin is a Ca -binding protein which can activate target enzymes, e.g. phosphorylase kinase (see 6.7.1 and 7.4) in its Ca -boimd form. Another example for activating proteins is the cyclins (see chapter 14). The cyc-lins are activators of protein kinases that regulate the cell cycle. 

This widespread protein, of molecular weight about 17 000, regulates the activity of a number of calcium dependent enzymes.Calmodulin binds four Ca, apparently with the induction of sequential conformational changes, as shown by studies involving NMR, fluorescence, and Raman spectroscopy, The Raman studies confirmed that the... 

Meador, W.E., Means, A.R., Quiocho, F.A. Target enzyme recognition by calmodulin 2.4 A stmcture of a calmodulin-peptide complex. Science 257 1251-1255, 1992. 

Nonrepetitive but well-defined structures of this type form many important features of enzyme active sites. In some cases, a particular arrangement of coil structure providing a specific type of functional site recurs in several functionally related proteins. The peptide loop that binds iron-sulfur clusters in both ferredoxin and high potential iron protein is one example. Another is the central loop portion of the E—F hand structure that binds a calcium ion in several calcium-binding proteins, including calmodulin, carp parvalbumin, troponin C, and the intestinal calcium-binding protein. This loop, shown in Figure 6.26, connects two short a-helices. The calcium ion nestles into the pocket formed by this structure. 

The anthrax toxin is a tripartite toxin and consists ofthe binding component protective antigen (PA), the lethal factor (LF), which is a metalloprotease, and the edema factor (EF), which is a calmodulin-dependent adenylyl-cyclase. Both enzyme components are translocated via PA into target cells. PA is activated by furin-induced cleavage and forms heptamers, which are similar to the binding components of C2 toxin and iota toxin. In the low pH compartment of endosomes, the heptamers form pores to allow translocation of LF and EF. LF cleaves six of the seven MEKs (MAPK-kinases) thereby inhibiting these enzymes. The functional consequence is the blockade of the MAPK pathways that control cell proliferation, differentiation, inflammation, stress response, and survival. Whether this is the reason for the LT-induced cell death of macrophages is not clear [1]. 

A constitutive enzyme binding to caveolin-1 in the plasma membrane, mainly in endothelial cells. It is activated in the presence of Ca2+ and calmodulin. 

All NOS isoforms utilize L-arginine as the substrate, and molecular oxygen and reduced nicotinamide adenine dinucleotide phosphate (NADPH) as cosubstrates. Flavin adenine dinucleotide (FMN), flavin mononucleotide (FAD), and (6R)-5,6,7,8-tetrahydro-L-biopterin (BH4) are cofactors of the enzyme. All NOS isoforms contain heme and bind calmodulin. In nNOS and eNOS,... 

Similar to nNOS, Ca2+-activated calmodulin is important for the regulation of eNOS activity. However, several other proteins interact with eNOS and regulate its activity. Heat shock protein 90 (hsp90) is found associated with eNOS and probably acts as an allosteric modulator that activates the enzyme. Caveolin-1 binds eNOS and directs it to caveolae. Caveolin-1 is viewed as an inhibitor of eNOS activity, which is being replaced by CaM upon activation of endothelial cells [2]. 

The regulatory light chains from vertebrate forms of myosin-II undergo reversible phosphorylation by a calmodulin dependent enzyme called myosin light chain... 

In addition to its effects on enzymes and ion transport, Ca /calmodulin regulates the activity of many structural elements in cells. These include the actin-myosin complex of smooth muscle, which is under (3-adrenergic control, and various microfilament-medi-ated processes in noncontractile cells, including cell motility, cell conformation changes, mitosis, granule release, and endocytosis. 

Table 43-4. Enzymes and proteins regulated by calcium or calmodulin.

So far, it has been established from in vitro studies that the enzyme undergoes phosphorylation, a process that changes the conformation of the enzyme protein and leads to an increase in its activity. This involves Ca +/calmodulin-dependent protein kinase II and cAMP-dependent protein kinase which suggests a role for both intracellular Ca + and enzyme phosphorylation in the activation of tryptophan hydroxylase. Indeed, enzyme purified from brain tissue innervated by rostrally projecting 5-HT neurons, that have been stimulated previously in vivo, has a higher activity than that derived from unstimulated tissue but this increase rests on the presence of Ca + in the incubation medium. Also, when incubated under conditions which are appropriate for phosphorylation, the of tryptophan hydroxylase for its co-factor and substrate is reduced whereas its Fmax is increased unless the enzyme is purified from neurons that have been stimulated in vivo, suggesting that the neuronal depolarisation in vivo has already caused phosphorylation of the enzyme. This is supported by evidence that the enzyme activation caused by neuronal depolarisation is blocked by a Ca +/calmodulin protein kinase inhibitor. However, whereas depolarisation... 

The Ca transport ATPase of the surface membrane is a Ca -calmodulin-dependent enzyme of approximately 138-kDa mass that is structurally distinct from the sarcoplasmic reticulum Ca -ATPase, but shares with it some similarities in the mechanism of Ca translocation [2,3,34]. In both enzymes the Ca -dependent phosphorylation of an aspartyl-carboxyl-group by ATP leads to the formation of an acyl phosphate intermediate that provides the coupling between ATP hydrolysis and Ca translocation. 

There are at least five distinct isoforms of plasma membrane Ca -ATPases in mammalian tissues that differ in distribution and C-terminal sequences [34]. The molecular weight of these enzymes is in the range of 127 300-134683 (Table I) and they all contain calmodulin-binding domains [3], in contrast to the much smaller ( 110kDa) SERCA enzymes that are calmodulin independent. 

FIGURE 8.11 Multiple signal-transduction pathways initiated by calmodulin. Calmodulin bound to Ca2+ interacts and activates many enzymes, opening up a wide range of possible cellular responses. Abbreviations MAP-2, microtubule-associated protein 2 NO, nitric oxide Tau, tubulin assembly unit. 

Lead also has been shown to substitute for calcium in the activation of calmodulin, but this requires higher levels of lead than does the activation of protein kinase C. Nevertheless, the affinity of lead for calmodulin is higher than that of calcium. Once activated, calmodulin regulates the activity of certain enzymes and transporters. For example, it activates c-AMP phosphodiesterase to hydrolyze and terminate the action of cAMP, another second messenger (Bressler and Goldstein 1991 Goldstein 1993 Goering 1993). 

Upon entering the smooth muscle cell, Ca++ ions bind with calmodulin, an intracellular protein with a chemical structure similar to that of troponin. The resulting Ca++-calmodulin complex binds to and activates myosin kinase. This activated enzyme then phosphorylates myosin. Crossbridge cycling in smooth muscle may take place only when myosin has been phosphorylated. 

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