Myosin-light-chain phosphatase

Smooth muscle tissue is mostly made of actin and myosin, two proteins that interact together to produce muscle contraction and relaxation. Myosin II, also known as conventional myosin, has two heavy chains that consist of the head and tail domains and four light chains (two per head) that bind to the heavy chains in the “neck” region. When the muscle needs to contract, calcium ions flow into the cytosol from the sarcoplasmic reticulum, where they activate calmodulin, which in turn activates myosin light-chain kinase (MLC kinase). MLC kinase phosphorylates the myosin light chain (MLC20) at the Ser-19 residue. This phosphorylation causes a conformational change in the myosin, activating crossbridge cycling and causing the muscle to contract. Because myosin undergoes a conformational change, the muscle will stay contracted even if calcium and activated MLC kinase concentrations are brought to normal levels. The conformational change must be undone to relax the muscle. When myosin phosphatase binds to myosin, it removes the phosphate group. Without the group, the myosin reverts to its original conformation, in which it cannot interact with the actin and hold the muscle tense, so the muscle relaxes. The muscle will remain in this relaxed position until myosin is phosphorylated by MLC kinase and undergoes a conformational change. ==Structure==

Myosin phosphatase is made of three subunits. The catalytic subunit, PP1, is one of the more important Ser/Thr phosphatases in eukaryotic cells, as it plays a role in glycogen metabolism, intracellular transport, protein synthesis, and cell division as well as smooth muscle contraction. Because it is so important to basic cellular functions, and because there are far fewer protein phosphatases than kinases in cells, PP1’s structure and function is highly conserved (though the specific isoform used in myosin phosphatase is the δ isoform, PP1δ). PP1 works by using two manganese ions as catalysts for the dephosphorylation (see below). Surrounding these ions is a Y-shaped cleft with three grooves: a hydrophobic, an acidic, and a C-terminal groove. When PP1 is not bonded to any other subunit, it is not particularly specific. However, when it bonds to the second subunit of myosin phosphatase, MYPT1 (MW ~130 kDa), this catalytic cleft changes configuration. This results in a dramatic increase in myosin specificity. Thus, it is clear that MYPT1 has great regulatory power over PP1 and myosin phosphatase, even without the presence of other activators or inhibitors. The third subunit, M20 (not to be confused with MLC20, the critical regulatory subunit of myosin), is the smallest and most mysterious subunit. Currently little is known about M20, except that it is not necessary for catalysis, as removing the subunit does not affect turnover or selectivity. While some believe it could have regulatory function, nothing has been determined yet. ==Mechanism==

The mechanism of removing the phosphate from Ser-19 is very similar to other dephosphorylation reactions in the cell, such as the activation of glycogen synthase. Myosin's regulatory subunit MLC20 binds to both the hydrophobic and acid grooves of PP1 and MYPT1, the regulatory site on myosin phosphatase. Once in the proper configuration, both the phyosphorylated serine and a free water molecule are stabilized by the hydrogen-bonding residues in the active site, as well as the positively charged ions (which interact strongly with the negative phosphate group). His-125 (on myosin phosphatase) donates a proton to Ser-19 MLC20), and the water molecule attacks the phosphorus atom. After shuffling protons to stabilize (which happens rapidly compared to the attack on phosphorus), the phosphate and alcohol are formed, and both leave the active site. ==Regulation and Human Health==

The regulatory pathways of MLC kinase have been well-established, but until the late 1980s, it was assumed that myosin phosphatase was not regulated, and contraction/relaxation was entirely dependent on MLC kinase activity. RhoA GTP activates Rho-kinase, which phosphorylates the MYPT1 at two major inhibitory sites, Thr-696 and Thr-866. This fully demonstrates the value of the MYPT1, not only to increase reaction rate and specificity, but also to greatly slow down the reaction. However, when telokin is added, it effectively undoes the effect of Rho-kinase, even though it does not dephosphorylate MYPT1. ==See also==