Abstract
We expressed the small subunit of smooth muscle myosin light chain phosphatase (MPs) in Escherichia coli, and have studied its molecular properties as well as its interaction with the targeting subunit (MPt). MPs (M(r) = 18,500) has an anomalously low electrophoretic mobility, running with an apparent M(r) of approximately 21,000 in sodium dodecyl sulfate-gel electrophoresis. CD spectroscopy shows that it is approximately 45% alpha-helix and undergoes a cooperative temperature-induced unfolding with a transition midpoint of 73 degrees C. Limited proteolysis rapidly degrades MPs to a stable C-terminal fragment (M(r) = 10,000) that retains most of the helical content. Rotary shadowing electron microscopy reveals that it is an elongated protein with two domains. Sedimentation velocity measurements show that recombinant MPt (M(r) = 107,000), intact MPs, and the 10-kDa MPs fragment are all dimeric, and that MPs and MPt form a complex with a molar mass consistent with a 1:1 heterodimer. Sequence analysis predicts that regions in the C-terminal portions of both MPs and MPt have high probabilities for coiled coil formation. A synthetic peptide from a region of MPs encompassing residues 77-116 was found to be 100% alpha-helical, dimeric, and formed a complex with MPt with a molecular mass corresponding to a heterodimer. Based on these results, we propose that MPs is an elongated molecule with an N-terminal head and a C-terminal stalk domain. It dimerizes via a coiled coil interaction in the stalk domain, and interacts with MPt via heterodimeric coiled coil formation. Since other proteins with known regulatory function toward MP also have predicted coiled coil regions, our results suggest that these regulatory proteins target MP via the same coiled coil strand exchange mechanism with MPt.
Highlights
We expressed the small subunit of smooth muscle myosin light chain phosphatase (MPs) in Escherichia coli, and have studied its molecular properties as well as its interaction with the targeting subunit (MPt)
Sedimentation velocity measurements show that recombinant MPt (Mr ؍107,000), intact MPs, and the 10-kDa MPs fragment are all dimeric, and that MPs and MPt form a complex with a molar mass consistent with a 1:1 heterodimer
Initial Characterization—The electrophoretic mobility of recombinant MPs on SDS-PAGE is identical to that of MPs from the MP holoenzyme purified from chicken gizzards (Fig. 1, lanes 2 and 1)
Summary
A synthetic peptide from a region of MPs encompassing residues 77–116 was found to be 100% ␣-helical, dimeric, and formed a complex with MPt with a molecular mass corresponding to a heterodimer Based on these results, we propose that MPs is an elongated molecule with an N-terminal head and a C-terminal stalk domain. Since other proteins with known regulatory function toward MP have predicted coiled coil regions, our results suggest that these regulatory proteins target MP via the same coiled coil strand exchange mechanism with MPt. Contraction of smooth muscle is regulated by phosphorylation of myosin regulatory light chain. A peptide corresponding to a sequence in MPs with high predicted probability for coiled coil formation was found to mimic MPs with respect to self-dimerization and heterodimeric complexation with MPt. It is proposed that MPs and some of the MP regulatory proteins interact with MPt via coiled coil exchange, a mechanism that may be relevant in other signal transduction processes
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