Actin hydrolyzing

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PyrogaUol has been cited for use in photosensitive compositions. It is used in the form of sulfonate esters of quinonediazides which hydrolyze when exposed to actinic light to Hberate the acid which, in turn, catalyzes further reaction of novolak resins (60). 

Figure 14.13 Stmcture of G-actin. Two a/P-domains, (red and green) bind an ATP molecuie between them. Tbis ATP is hydrolyzed when the actin monomer polymerizes to F-actin.

ATP is hydrolyzed in at least two consecutive steps on F-actin, viz. cleavage of the y-phosphoester bond, followed by Pj release, according to the following scheme ... 

In the three-dimensional stmcture of actin, the environment of the phosphate moiety of the nucleotide appears roughly the same when CaADP or CaATP is bound. This observation argues against two different conformations. The reason why this is so is unclear. However, it must be stressed that the three-dimensional stmcture is derived from X-ray diffraction of crystals of the DNasel-actin complex, which, like G-actin, is unable to hydrolyze ATP. The conformation obtained may therefore correspond to G-actin frozen in the G-ATP state independently of the bound nucleotide. Stmctural studies in conjunction with site-directed mutagenesis experiments should eventually solve this problem. 

Actin is a 42 kDa bent dumbbell-shaped globular monomer which is found in most eukaryotic cells. It is the primary protein of the thin (or actin) filaments. Also, by mass or molarity, actin is the largest constituent of the contractile apparatus, actually reaching millimolar concentrations. Actins from different sources seem to be more similar than myosins from the same sources. Actin binds ATP which is hydrolyzed to ADP, if the monomeric actin polymerizes. The backbone structure of the actin filament is a helix formed by two linear strands of polymerized actins like two strings of actin beads entwined. 

Because the equilibrium constant is close to one, this also means that the free energy does not change much when ATP is hydrolyzed. Most of the fall in free energy is associated with ATP binding to myosin as the equilibrium constant for this step is about 10 ° M. The binding energy is used to dissociate myosin from actin. 

The simplest mechanism to explain the much faster rate of dissociation of actomyosin-S-1 by ATP than that of ATP cleavage is that actin activates the myosin ATPase by accelerating the rate at which ADP and Pj are released. That is when ATP is added to actomyosin-S-1, ATP rapidly binds and dissociates actomyosin, myosin ATPase then hydrolyzes ATP to form myosin-ADP.Pj, this state then reattaches to actin and phosphate is released much faster from actomyosin. ADP.Pj than it is from myosin.ADP.Pj, as shown in the scheme below ... 

When smooth muscle myosin is bound to F-actin in the absence of other muscle proteins such as tropomyosin, there is no detectable ATPase activity. This absence of activity is quite unlike the situation described for striated muscle myosin and F-actin, which has abundant ATPase activity. Smooth muscle myosin contains fight chains that prevent the binding of the myosin head to F-actin they must be phosphorylated before they allow F-actin to activate myosin ATPase. The ATPase activity then attained hydrolyzes ATP about tenfold more slowly than the corresponding activity in skeletal muscle. The phosphate on the myosin fight chains may form a chelate with the Ca bound to the tropomyosin-TpC-actin complex, leading to an increased rate of formation of cross-bridges between the myosin heads and actin. The phosphorylation of fight chains initiates the attachment-detachment contraction cycle of smooth muscle. 

F -ATPase Driven Nanomotors. Another type of biological driven engine is that of Fi-adenosine triphosphate synthease (Fi-ATPase) which hydrolyzes the ATP in the surrounding medium. Kinosita Jr. et al. observed the rotation of an actin filament attached to the Fi - ATPase motor. Later, Montemagno followed with the incorporation of a nickel nanorod with the Fi-ATPase motor. The outcome was the rotation of the... 

Actin, the most abundant protein in eukaryotic cells, is the protein component of the microfilaments (actin filaments). Actin occurs in two forms—a monomolecular form (C actin, globular actin) and a polymer (F actin, filamentous actin). G actin is an asymmetrical molecule with a mass of 42 kDa, consisting of two domains. As the ionic strength increases, G actin aggregates reversibly to form F actin, a helical homopolymer. G actin carries a firmly bound ATP molecule that is slowly hydrolyzed in F actin to form ADR Actin therefore also has enzyme properties (ATPase activity). 

Elongation is the repetitive addition reactions of actin-ATP (Fig. 2). The actin-bound ATP is hydrolyzed during/after monomer addition to filaments, forming polymer-bound ADP and releasing orthophosphate. The kinetics of elongation conform to that predicted by the following rate law ... 

The interaction between actin and myosin, like that between all proteins and ligands, involves weak bonds. When ATP is not bound to myosin, a face on the myosin head group binds tightly to actin (Fig. 5-33). When ATP binds to myosin and is hydrolyzed to ADP and phosphate, a coordinated and cyclic series of conformational changes occurs in which myosin releases the F-actin subunit and binds another subunit farther along the thin filament. 

The cycle has four major steps (Fig. 5-33). In step (l), ATP binds to myosin and a cleft in the myosin molecule opens, disrupting the actin-myosin interaction so that the bound actin is released. ATP is then hydrolyzed in step (2), causing a conformational change in the protein to a high-energy state that moves the myosin head and changes its orientation in relation to the actin thin filament. Myosin then binds weakly to an F-actin subunit... 

Each tubulin dimer binds one molecule of GTP strongly in the a subunit and a second molecule of GTP or GDP more loosely in the P subunit. In this respect, tubulin resembles actin, whose subunits are about the same size. However, there is little sequence similarity. Labile microtubules of cytoplasm can be formed or disassembled very rapidly. GTP is essential for the fast growth of these microtubules and is hydrolyzed to GDP in the process.320 However, nonhydro-lyzable analogs of GTP, such as the one containing the linkage P-CH2-P between the terminal and central phosphorus atoms of the GTP, also support polymerization.321 Since microtubules have a distinct polarity, the two ends have different tubulin surfaces exposed, and polymerization and depolymerization can occur at different rates at the two ends. As a consequence, microtubules often grow at one end and disassemble... 

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