Myosin VI is an unconventional myosin that may play a role in vesicular membrane traffic through actin rich regions of the cytoplasm in eukaryotic cells. In this study we have cloned and sequenced a cDNA encoding a chicken intestinal brush border myosin VI. Polyclonal antisera were raised to bacterially expressed fragments of this myosin VI. The affinity purified antibodies were highly specific for myosin VI by immunoblotting and immunoprecipitation and were used to study the localization of the protein by immunofluorescence and immunoelectron microscopy. It was found that in NRK and A431 cells, myosin VI was associated with both the Golgi complex and the leading, ruffling edge of the cell as well as being present in a cytosolic pool. In A431 cells in which cell surface ruffling was stimulated by EGF, myosin VI was phosphorylated and recruited into the newly formed ruffles along with ezrin and myosin V. In vitro experiments suggested that a p21-activated kinase (PAK) might be the kinase responsible for phosphorylation in the motor domain. These results strongly support a role for myosin VI in membrane traffic on secretory and endocytic pathways.
Abnormal smooth muscle contraction may contribute to diseases such as asthma and hypertension. Alterations to myosin light chain kinase or phosphatase change the phosphorylation level of the 20-kDa myosin regulatory light chain (MRLC), increasing Ca 2؉ sensitivity and basal tone. One Rho family GTPase-dependent kinase, Rho-associated kinase (ROK or p160 ROCK ) can induce Ca
2؉-independent contraction of Triton-skinned smooth muscle by phosphorylating MRLC and/or myosin light chain phosphatase. We show that another Rho family GTPase-dependent kinase, p21-activated protein kinase (PAK), induces Triton-skinned smooth muscle contracts independently of calcium to 62 ؎ 12% (n ؍ 10) of the value observed in presence of calcium. Remarkably, PAK and ROK use different molecular mechanisms to achieve the Ca 2؉ -independent contraction. Like ROK and myosin light chain kinase, PAK phosphorylates MRLC at serine 19 in vitro. However, PAK-induced contraction correlates with enhanced phosphorylation of caldesmon and desmin but not MRLC. The level of MRLC phosphorylation remains similar to that in relaxed muscle fibers (absence of GST-mPAK3 and calcium) even as the force induced by GST-mPAK3 increases from 26 to 70%. Thus, PAK uncouples force generation from MRLC phosphorylation. These data support a model of PAK-induced contraction in which myosin phosphorylation is at least complemented through regulation of thin filament proteins. Because ROK and PAK homologues are present in smooth muscle, they may work in parallel to regulate smooth muscle contraction.
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