Myosin light chains of guinea-pig striated muscles. Similarities and differences with rat myosin light chains

1. Myosin light chains of guinea-pig striated muscles have been screened by two-dimensional gel electrophoresis and compared to rat myosin light chains. 2. The fast type light chains 1F and 3F, slow type light chains 1S and 2S, and embryonic type light chain 1E are shown to differ in the two rodents; only the fast type light chains 2F co-electrophorese on the gel. 3. In guinea-pig, as in rat, ventricle muscle light chains appear the same as the 1S and 2S light chains and atrial light chain type 1 the same as the 1E light chain. We show that this embryonic light chain of guinea-pig myosin is difficult to identify and may be confused with the adult 1F light chain.     

Regulatory light chains in myosins.

Scallop myosin molecules contain two moles of regulatory light chains and two moles of light chains with unknown function. Removal of one of the regulatory light chains by treatment with EDTA is accompanied by the complete loss of the calcium dependence of the actin-activated ATPase activity and by the loss of one of the two calcium binding sites on the intact molecule. Such desensitized preparations recombine with one mole of regulatory light chain and regain calcium regulation and calcium binding. The second regulatory light chain may be selectively obtained from EDTA-treated scallop muscles by treatment with the Ellman reagent (5,5′-dithiobis(2-nitrobenzoic acid)): treatment with this reagent, however, leads to an irreversible loss of ATPase activity. The light chains obtained by treatment with EDTA and then DTNB are identical in composition and function. A different light chain fraction obtained by subsequent treatment with guanidine-HCl does not bind to desensitized or intact myoflbrils and has no effect on ATPase activity.Regulatory light chains which bind to desensitized scallop myofibrils with high affinity and restore calcium control were found in a number of molluscan and vertebrate myosins, including Mercenaria, Spisula, squid, lobster tail, beef heart, chicken gizzard, frog and rabbit. Although these myosins all have a similar subunit structure and contain about two moles of regulatory light chain, only scallop myosin or myofibrils can be desensitized by treatment with EDTA.There appear to be two classes of regulatory light chains. The regulatory light chains of molluscs and of vertebrate smooth muscles restore full calcium binding and also resensitize purified scallop myosin. The regulatory light chains from vertebrate striated, cardiac, and the fast decapod muscles, on the other hand, have no effect on calcium binding and do not resensitize purified scallop myosin unless the myosin is complexed with actin. The latter class of light chains is found in muscles where in vitro functional tests failed to detect myosin-linked regulation.     

Shedding a little light on light chains

Myosin II regulatory light chains have an important role in the organization and function of the contractile machinery at cytokinesis. Two recent reports provide new insights into these important proteins.     

An allotypic marker on chicken immunoglobulin light chains.

The first chicken immunoglobulin light (L) chain allotypic specificity (L-1.1) to be described that was present on IgM, 7S Ig, Fab, and L chains was detected by radioimmunoassay. The gene controlling the expression of L-1.1 is inherited in a simple Mendelian fashion at an autosomal locus and is unlinked to a constant region heavy chain locus, four blood group loci and three loci determining lymphocyte cell surface alloantigens.     

Myosin subunit interactions. Localization of the alkali light chains

Myosin homodimers, molecules containing either the A1 or the A2 light chain, do not exchange their light chains under conditions approximating physiological temperature and ionic strength. Myosin heterodimers, molecules containing both A1 and A2 light chains, are therefore formed at the time of synthesis rather than by a labile subunit exchange. Antibodies specific for the amino-terminal region of the alkali light chains were used to localize these subunits in myosin by immunoelectron microscopy. The close proximity of the alkali light chain to the 5,5'-dithiobis-(2-nitrobenzoic acid) light chain in the "neck" region of the myosin head is consistent with the finding that the 5,5'-dithiobis-(2-nitrobenzoic acid) light chain influences subunit interactions between the alkali light chain and heavy chain in vertebrate skeletal muscle myosin.     

Phosphorylation of vertebrate nonmuscle and smooth muscle myosin heavy chains and light chains

In this article we review the various amino acids present in vertebrate nonmuscle and smooth muscle myosin that can undergo phosphorylation. The sites for phosphorylation in the 20 kD myosin light chain include serine-19 and threonine-18 which are substrates for myosin light chain kinase and serine-1 and/or-2 and threonine-9 which are substrates for protein kinase C. The sites in vertebrate smooth muscle and nonmuscle myosin heavy chains that can be phosphorylated by protein kinase C and casein kinase II are also summarized.Original data indicating that treatment of human T-lymphocytes (Jurkat cell line) with phorbol 12-myristate 13-acetate results in phosphorylation of both the 20 kD myosin light chain as well as the 200 kD myosin heavy chain is presented. We identified the amino acids phosphorylated in the human T-lymphocytes myosin light chains as serine-1 or serine-2 and in the myosin heavy chains as serine-1917 by 1-dimensional isoelectric focusing of tryptic phosphopeptides. Untreated T-lymphocytes contain phosphate in the serine-19 residue of teh myosin light chain and in a residue tentatively identified as serine-1944 in the myosin heavy chain.Abbreviations MLC myosin light chain - MHC myosin heavy chain - Tris tris(hydroxymethyl)aminomethane - EGTA [ethylenebis(oxyethylenenitrilo)]tetraacetic acid - EDTA ethylenediaminetetraacetate - TPCK N-tosyl-L-phenylalanine chloromethyl ketone - PMA phorbol 12-myristate 13-acetate     

Precursor sequence of MOPC-315 mouse immunoglobulin heavy and light chains.

Partially purified mRNA coding for the MOPC-315 heavy (alpha) or light (lambda 2) immunoglobulin chain was translated in a nuclease-treated reticulocyte lysate containing 20 labeled amino acids. Radiolabeled precursor heavy and light chains, purified by immunoprecipitation and preparative gel electrophoresis, were subjected to Edman degradation. The labeled phenylthiohydantoin derivatives obtained in each degradative cycle were identified and quantitated by high pressure liquid chromatography. Both heavy and light chain precursor segments were hydrophobic in nature; however, they were not homolgous in sequence. To establish whether COOH-terminal proteolytic processing of the heavy chain might also be occurring during secretion, the cyanogen bromide peptides of the heavy chain precursor were compared to those of the mature secreted heavy chain. The results indicated that the COOH termini of the two chains were identical.     

Investigation of immunological relationships among myosin light chains and troponin C.

Two classes of myosin light chains can be distinguished functionally: those that restore calcium regulation to "desensitized" scallop myofibrils, and those that do not (Kendrick-Jones, J., et al. (1976), J. Mol. Biol. 104, 747--775). Despite this functional classification, chemical analyses reveal few patterns unique to regulatory light chains, and, indeed, sequence comparisons suggest structural similarities between both classes of myosin subunits (Collins, J. H. (1977), Nature (London) 259, 699--700; Kendrick-Jones, J., and Jakes, R. (1977), in International Symposium on Myocardial Failure at Tegernsee, Riecker, G., and Boehringer, Ed., Munich, West Germany, Springer-Verlag, pp. 28--40). Immunological assays using antisera to regulatory and to nonregulatory light chains showed no correlation between antigenic activity and the presence or absence of regulatory function. Weak cross-reactivity was observed, however, among myosin light chains and troponin C, consistent with the suggestion made on the basis of sequence homologies that these subunits contain similar structural domains (Weeds, A. G., and McLachlan, A. D. (1974), Nature (London) 252, 646--649). Unexpectedly, the strongest cross-reactivity observed was that between the vertebrate myosin alkali 1 and DTNB light chains.     

Conformationally altered aortic myosin light chains

Aorta smooth myosin contains two types of light chain, LC20 and LC17, which fold together with the N-terminal region of each heavy chain to form the globular head region of myosin. We demonstrate an altered conformation of LC20 after its separation from heavy chain by high concentrations of urea, on the basis of the following evidende: 1) A polyclonal antibody against LC20 was not able to recognize this conformationally altered form; 2) Myosin reconstituted from heavy chains and urea-dissociated light chains exhibited extremely low ATPase activity. Circular dichroism unfolding profiles showed that light chains dissociated from heavy chains by SDS appeared to be more stable than those generated by urea dissociation.     

Clathrin light chains are calcium-binding proteins

Clathrin light chains have been purified to near homogeneity. When analyzed by sodium dodecyl sulfate gel electrophoresis followed by silver stain for proteins, no bands corresponding to light chains were detected. As calmodulin and troponin C are known to behave in the same manner on silver staining, the possibility that clathrin light chains were Ca2+-binding proteins was investigated. Light chains fixed to nitrocellulose filters were found to bind 45Ca2+ in the presence of 5 mM Mg2+. The Ca2+-binding capacity of the light chains was further investigated, using gel filtration and equilibrium dialysis. The light chains were shown to bind, in the presence of 3 mM Mg2+, 1 mol of Ca2+ per mol of light chain with a Kd of 25-55 microM. Nitrocellulose binding and gel filtration studies showed that light chains present in triskelions are still capable of binding Ca2+, in this case with a calculated Kd of 45 microM.     

Temporal relationship of translation and glycosylation of immunoglobulin heavy and light chains.

The initial glycosylation of MPC 11 gamma 2b heavy chains occurs quantitatively in vivo when the nascent heavy chains reach a size of approximately 38 000 daltons. Nonglycosylated, completed MPC 11 heavy chains cannot be glycosylated in these cells. Other classes of mouse heavy chains (i.e., mu, alpha, and gamma 1) also appear to be glycosylated as nascent chains; nonglycosylated, completed heavy chains cannot be glycosylated by the cell in any of these cases. In contrast, variant MPC 11 cells synthesizing a heavy chain with a carboxy-terminal deletion appear to glycosylate some heavy chains prior to chain completion and some heavy chains after chain completion and release from the polysomes. Similar to the variant MPC 11 cells, MOPC 46B cells (which synthesize a kappa light chain containing an oligosaccharide attached to an asparagine located 28 residues from the amino terminus) glycosylate the majority of light chains after prior to chain completion but also some light chains after chain completion and release from the polysomes. In addition, it appears that, although completed MOPC 46B light chains can be glycosylated if they are present in a monomeric form, they cannot be glycosylated if they are present in a covalent dimeric form.