A comparative carbon-13, nitrogen-15, and phosphorus-31 nuclear magnetic resonance study on the flavodoxins from Clostridium MP, Megasphaera elsdenii, and Azotobacter vinelandii

The flavodoxins from Megasphaera elsdenii, Clostridium MP, and Azotobacter vinelandii were studied by 13C, 15N, and 31P NMR techniques by using various selectivity enriched oxidized riboflavin 5'-phosphate (FMN) derivatives. It is shown that the pi electron distribution in protein-bound flavin differs from that of free flavin and depends also on the apoflavoprotein used. In the oxidized state Clostridium MP and M. elsdenii flavodoxins are very similar with respect to specific hydrogen bond interaction between FMN and the apoprotein and the electronic structure of flavin. A. vinelandii flavodoxin differs from these flavodoxins in both respects, but it also differs from Desulfovibrio vulgaris flavodoxin. The similarities between A. vinelandii and D. vulgaris flavodoxins are greater than the similarities with the other two flavodoxins. The differences in the pi electron distribution in the FMN of reduced flavodoxins from A. vinelandii and D. vulgaris are even greater, but the hydrogen bond patterns between the reduced flavins and the apoflavodoxins are very similar. In the reduced state all flavodoxins studied contain an ionized prosthetic group and the isoalloxazine ring is in a planar conformation. The results are compared with existing three-dimensional data and discussed with respect to the various possible mesomeric structures in protein-bound FMN. The results are also discussed in light of the proposed hypothesis that specific hydrogen bonding to the protein-bound flavin determines the specific biological activity of a particular flavoprotein.     

Purification and characterization of two isoforms of glucose 6-phosphate dehydrogenase (G6PDH) from Chlorella vulgaris C-27

Two kinds of isoforms of glucose 6-phosphate dehydrogenase (G6PDH) were purified from cells of a freezing-tolerant strain, Chlorella vulgaris C-27, by sequential steps of chromatography on five kinds of columns, including a HiTrap Blue column which showed excellent separation of the isoforms from each other. The two isoforms (G6PDH1 and G6PDH2) were purified up to 109-fold and 197-fold with specific activity of 14.4 and 26.0 U/mg-protein, respectively. G6PDH1 showed an apparent Mr of 200,000 with a subunit Mr of about 58,000, whereas G6PDH2 showed an apparent Mr of 450,000 with a subunit Mr of about 52,000. The kinetic parameters were measured and several enzymatic features of the isoforms, such as effects of metal ions on the enzyme activity, were clarified, which showed that the two isoforms were different from each other in many respects. Among the effective ions, Cd2+ showed marked stimulating effects on both isoforms. G6PDH1 and G6PDH2 seem to be a cytosolic and a chloroplastic type, respectively, as judged by their sensitivity to DTT, and also from the results of sequence similarity searches using their N-terminal and internal amino acid sequences.     

Isolation and characterization of multiple forms of rat liver UDP-glucuronate glucuronosyltransferase.

UDP-glucuronosyltransferase (EC 2.4.1.17) activity was solubilized from male Wistar rat liver microsomal fraction in Emulgen 911, and six fractions with the transferase activity were separated by chromatofocusing on PBE 94 (pH 9.4 to 6.0). Fraction I was further separated into Isoforms Ia, Ib and Ic by affinity chromatography on UDP-hexanolamine-Sepharose 4B. UDP-glucuronosyltransferase in Fraction III was further purified by rechromatofocusing (pH 8.7 to 7.5). UDP-glucuronosyltransferases in Fractions IV and V were purified by UDP-hexanolamine-Sepharose chromatography. The transferase isoforms in Fractions II, III, IV and V were finally purified by h.p.l.c. on a TSK G 3000 SW column. Purified UDP-glucuronosyltransferase Isoforms Ia (Mr 51,000), Ib (Mr 52,000), Ic (Mr 56,000), II (Mr 52,000), IV (Mr 53,000) and V (Mr 53,000) revealed single Coomassie Blue-stained bands on sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Isoform III enzyme showed two bands of Mr 52,000 and 53,000. Comparison of the amino acid compositions by the method of Cornish-Bowden [(1980) Anal. Biochem. 105, 233-238] suggested that all UDP-glucuronosyltransferase isoforms are structurally related. Reverse-phase h.p.l.c. of tryptic peptides of individual isoforms revealed distinct 'maps', indicating differences in primary protein structure. The two bands of Isoform III revealed distinct electrophoretic peptide maps after limited enzymic proteolysis. After reconstitution with phosphatidylcholine liposomes, the purified isoforms exhibited distinct but overlapping substrate specificities. Isoform V was specific for bilirubin glucuronidation, which was not inhibited by other aglycone substrates. Each isoform, except Ia, was identified as a glycoprotein by periodic acid/Schiff staining.     

The long and short flavodoxins: I. The role of the differentiating loop in apoflavodoxin structure and FMN binding

Flavodoxins are well known one-domain alpha/beta electron-transfer proteins that, according to the presence or absence of a approximately 20-residue loop splitting the fifth beta-strand of the central beta-sheet, have been classified in two groups: long and short-chain flavodoxins, respectively. Although the flavodoxins have been extensively used as models to study electron transfer, ligand binding, protein stability and folding issues, the role of the loop has not been investigated. We have constructed two shortened versions of the long-chain Anabaena flavodoxin in which the split beta-strand has been spliced to remove the original loop. The two variants have been carefully analyzed using various spectroscopic and hydrodynamic criteria, and one of them is clearly well folded, indicating that the long loop is a peripheral element of the structure of long flavodoxins. However, the removal of the loop (which is not in contact with the cofactor in the native structure) markedly decreases the affinity of the apoflavodoxin-FMN complex. This seems related to the fact that, in long flavodoxins, the adjacent tyrosine-bearing FMN binding loop (which is longer and thus more flexible than in short flavodoxins) is stabilized in its competent conformation by interactions with the excised loop. The modest role played by the long loop of long flavodoxins in the structure of these proteins (and in its conformational stability, see Lopez-Llano, J., Maldonado, S., Jain, S., Lostao, A., Godoy-Ruiz, R., Sanchez-Ruiz, Cortijo, M., Fernandez-Recio, J., and Sancho, J. (2004) J. Biol. Chem. 279, 47184-47191) opens the possibility that its conservation in so many species is related to a functional role yet to be discovered. In this respect, we discuss the possibility that the long loop is involved in the recognition of some flavodoxin partners. In addition, we report on a structural feature of flavodoxins that could indicate that the short flavodoxins derive from the long ones.     

In vitro translation, post-translational processing and secretion of pulmonary surfactant protein B precursors

Surfactant proteolipid SP-B is a hydrophobic protein of Mr = 8000 identified in organic solvent extracts of pulmonary surfactant. Analysis of the human SP-B RNA predicts that the active surfactant peptide is derived by proteolysis of an Mr = 40,000 precursor. In the present work, characteristics of synthesis, secretion and processing of SP-B were demonstrated in a pulmonary adenocarcinoma cell line by immunoprecipitation of radiolabelled precursors. Treatment of cells with tunicamycin resulted in synthesis and secretion of unglycosylated proSP-B of Mr = 39,000. Immunoprecipitation of protein produced by in vitro translation of human lung poly(A)+ RNA detected an Mr = 40,000 protein; the size discrepancy is likely related to cleavage of a leader signal sequence. Endoglycosidase-H-sensitive precursors of Mr = 41,000-43,000, pI = 5.1-5.4 were the first isoforms detected within the cells and were processed to endoglycosidase-H-resistant isoforms and secreted. Neuraminidase and endoglycosidase-F-sensitive forms of proSP-B were first detected in the media at 60 min as Mr = 42-46,000 isoforms with pI = 4.6-5.1. Proteolytically processed isoforms of proSP-B were detected primarily in the media and were generated by cleavage of an amino-terminal Mr = 16,000 peptide resulting in Mr = 27,000-33,000 isoforms (pH = 5.6-6.8). The Mr = 27,000-33,000 isoforms were sensitive to neuraminidase, resulting in isoforms with pH = 6.0-6.8. Digestion of the Mr = 27,000-33,000 peptide with endoglycosidase-F resulted in isoforms of Mr = 23,000, pH = 6.0-6.8. The endoglycosidase-F-resistant peptide of Mr = 16,000, pI = 4.2-4.4 was identified with an antiserum generated against synthetic peptides derived from the amino-terminal domain, as deduced from the SP-B DNA sequence. Further proteolytic processing of the Mr = 27,000-33,000 isoforms to the Mr = 8000 peptide detected in surfactant was not observed in this cell line. Thus, in the H441-4 cells (a cell line with morphologic features of Clara cells), SP-B is synthesized as a preproprotein which undergoes cleavage of a signal sequence and addition of asparagine-linked carbohydrate; proSP-B is secreted by processes which are independent of glycosylation. SP-B peptides of Mr = 27,000-33,000 and Mr = 16,000, representing carboxy and amino-terminal domains, accumulate in the media.     

Purification and characterization of multiple isoforms of tropomyosin from rat cultured cells

We have previously shown that rat cultured cells contain five isoforms of tropomyosin (Matsumura, F., Yamashiro-Matsumura, S., and Lin, J. J.-C. (1983) J. Biol. Chem. 258, 6636-6644) and that these tropomyosins are differentially expressed upon cell transformation (Matsumura, F., Lin, J. J.-C., Yamashiro-Matsumura, S., Thomas, G. P., and Topp, W. C. (1983) J. Biol. Chem. 258, 13954-13964). To examine functions of tropomyosin in microfilament organization, we have purified and partially separated the multiple isoforms of tropomyosin by chromatography on hydroxylapatite. Analyses of cross-linked dimers produced by air oxidation have revealed that all isoforms except the tropomyosin isoform with apparent Mr of 35,000 form homodimers. Although these tropomyosins share many properties characteristic of tropomyosin, structural analyses at a peptide level and immunological analyses have shown that the five isoforms can be classified into two groups, i.e. tropomyosins with higher apparent Mr (Mr = 40,000, 36,500, and 35,000) and tropomyosins with lower apparent Mr (Mr = 32,400 and 32,000). The low Mr tropomyosins show less ability for head-to-tail polymerization and lower affinity to actin than the high Mr tropomyosins. We suggest that these differences in properties may be related to the changes in microfilament organization observed in transformed cells.     

Characterization of three different flavodoxins from Azotobacter vinelandii

The flavodoxins from Azotobacter vinelandii cells grown N2-fixing and from cells grown on NH4OAc have been purified and characterized. The purified flavodoxins from these cells are a mixture of three different flavodoxins (Fld I, II, III) with different primary structures. The three proteins were separated by fast protein liquid chromatography; Fld I eluted at 0.38 M KCl, Fld II at 0.43 M KCl and Fld III at 0.45 M KCl. The most striking difference between the three flavodoxins was the midpoint potential (pH 7.0, 25 degrees C) of the semiquinone/hydroquinone couple, which was -320 mV for Fld I and -500 mV for the other two flavodoxins (Fld II and Fld III). All three flavodoxins were present in cells grown on NH4OAc. In cells grown on N2 as N source only Fld I and Fld II were found. The concentration of Fld II was 10-fold higher in N2-fixing cells than in cells grown on NH4OAc. Evidence has been obtained that Fld II is involved in electron transport to nitrogenase. As will be discussed, our observation that preparations of Azotobacter flavodoxin are heterogeneous, has consequences for the published data.     

Purification and characterization of hormone-regulated isoforms of the regulatory subunit of type II cAMP-dependent protein kinase from rat ovaries

The regulatory subunit (R-II) of cAMP-dependent protein kinase type II is induced in rat ovarian granulosa cells by the synergistic actions of estradiol and follicle-stimulating hormone. The R-II from rat ovaries was compared with R-II from rat heart, rat brain, bovine heart, and bovine brain using immunological methods, 8-N3[32P]cAMP photoaffinity labeling and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three isoforms of R-II were identified in rat ovarian cell extract (R-II54 Mr = 54,000, R-II52 Mr = 52,000, R-II51 Mr = 51,000), two isoforms of R-II in rat brain cell extract (Mr = 54,000, Mr = 52,000), and one isoform of R-II in rat heart cell extract (Mr = 54,000). Rat ovarian R-II54, heart R-II, and brain R-II (Mr = 54,000) were recognized by antiserum against rat heart R-II, whereas rat ovarian R-II52/R-II51 and rat brain R-II (Mr = 52,000) were not. In contrast, an antiserum raised against bovine heart R-II recognized all three isoforms of ovarian R-II as well as the lower molecular weight form of rat brain R-II. Ovarian types R-II52 and R-II51 but not R-II54 were increased selectively in granulosa cells by estradiol and follicle-stimulating hormone. In addition: 1) ovarian R-II52/51 subunits were purified to homogeneity and shown to recombine with C subunit from bovine heart to form a cAMP-dependent protein kinase; 2) pure R-II52/51 were not interconvertible to a higher molecular weight form by C subunit-dependent phosphorylation; 3) pure rat heart R-II (Mr = 54,000) and ovarian R-II52/51 exhibited distinct differences based on one- and two-dimensional peptide mapping; and 4) by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis pure R-II52/51 were resolved as three (rather than two) isoelectric variants which were clearly different from pure rat heart R-II54. Thus, the hormone-regulated form of R-II in rat ovarian granulosa cells appears to represent a gene product distinct from R-II54 in rat heart.     

Tenascin Mr 220,000 isoform expression correlates with corneal cell migration.

The three isoforms of chicken tenascin, an extracellular matrix glycoprotein, are generated by alternatively spliced fibronectin type III domains. The resulting proteins migrate as bands of Mr 220,000 (ten220), Mr 200,000 (ten200) and Mr 190,000 (ten190) on SDS-PAGE. We describe here two monoclonal antibodies, one specific for ten220 (mAb T17) and another that recognizes all isoforms (mAb T16). These were used to examine the differential expression of isoforms during development. Most impressive is the close correlation between ten220 expression and cell migration in the embryonic cornea. Initially (stage 18), ten190/200 can be detected within the corneal epithelium and along the basement membranes of the lens and sclera. Ten220 appears within the primary stroma immediately prior to the invasion by neural-crest-derived cells. This expression is maintained during the subsequent migration of fibroblasts from the conjunctiva into the primary stroma. With the completion of migration and the marked increase in matrix synthesis by corneal fibroblasts, ten220 disappears. Ten190/200 remains in the region adjoining the endothelium, the Bowman's membrane and the adjacent stroma. The cell-migration-associated isoform is isolated from extracts of embryonic tissues as a homohexamer. Low molecular weight forms appeared absent but a new tenascin band of Mr 210,000 could be detected in brain extracts which may be a new isoform. We conclude that the synthesis of tenascin isoforms is under tight developmental control and speculate that a function of the additional domains is to facilitate cell migration.     

Low Mr tropomyosin isoforms from chicken brain and intestinal epithelium have distinct actin-binding properties

Tropomyosin isoforms of the low Mr class were isolated from chicken intestinal epithelium and brain, and their physical and functional properties were characterized. Tropomyosin from each tissue contains four distinct polypeptides, all of about 32,000 daltons. In two-dimensional gels, brain tropomyosin contains two major and two minor polypeptides; the major epithelium isoforms coelectrophorese with the two minor brain isoforms. Conversely, only small amounts of the major brain isoforms are detected in the epithelium. Actin-binding properties of brain tropomyosin isoforms are distinct from those of the intestinal epithelium. At 2.5 mM MgCl2 and physiological ionic strength, the intestinal epithelial tropomyosin binds to filamentous actin with an apparent Ka of 8 X 10(6) M-1 whereas brain tropomyosin has an apparent Ka of 8 X 10(5) M-1. Tropomyosin from either tissue binds actin cooperatively with a Hill coefficient of 2.3 for intestinal epithelial cell and 1.95 for brain tropomyosin. Isoforms from both tissues exhibit reduced head-to-tail polymerizability as compared to muscle tropomyosin. The actin-binding properties of intestinal epithelial cell tropomyosin are therefore similar to those of the muscle tropomyosins even though the isoforms have lower molecular weight, a paracrystal structure, and reduced head-to-tail polymerizability typical of the other nonmuscle tropomyosins. These results indicate that a heterogeneity of functional properties may be expressed among the low Mr tropomyosin isoforms.     

The interaction of detergents with phospholipid vesicles: A spectrofluorimetric study

Megasphaera elsdenii and Clostridium MP flavodoxins have been investigated by photo-CIDNP techniques. Using time-resolved spectroscopy and external dyes carrying different charges it was possible to assign unambiguously the resonance lines in the NMR-spectra to tyrosine, tryptophan and methionine residues in the two proteins. The results show that Trp-91 in M.elsdenii and Trp-90 in Cl.MP flavodoxin are strongly immobilized and placed directly above the benzene subnucleus of the prosthetic group. The data further indicate that the active sites of the two flavodoxins are extremely similar.     

Purification and properties of different isoforms of bovine cathepsin B

A rapid purification procedure is described for cathepsin B from bovine liver. After preparation of crude lysosomal extracts, the method only involves DEAE Zeta-Prep-Disk chromatography, gel filtration, and fast protein liquid chromatography on Mono-S column. Two active peaks (P1 and P2) of cathepsin B were distinguished. Both presented uncleaved (relative mass (Mr) 30,000) and cleaved (Mr 25,000 + Mr 5000) chains, but different isoforms as revealed by isoelectrofocusing. These two different populations of cathepsin B isoforms nevertheless exhibited similar enzymatic properties. Km and kcat were 114 microM and 52 s-1, and 125 microM and 75 s-1, for hydrolysis of Z-Arg-Arg-NMec by P1 and P2, respectively. Both were rapidly inhibited by low concentrations of E-64 or leupeptin, but were unaffected by cathepsin-L-specific inhibitor Z-Phe-Phe-CHN2.     

Chromatographic separation of the isoforms of the ribosome inactivating protein, gelonin.

The three isoforms of gelonin were separated by affinity chromatography on concanavalin-A Sepharose into discrete components of Mr 31,500, 30,000 and 29,200. Their separation was achieved by apparent differences in interaction with the lectin due to variation in carbohydrate patterns. The Mr 30,000 component representing 67% of the total mixture was the most active in inhibiting protein synthesis in a cell free translation assay using rabbit reticulocyte lysates, although the other two were also active. An antibody prepared against the major fraction (Mr 30,000) reacted well with all three components, demonstrating immunological similarity. This purification may aid the structural elucidation of gelonin and preparation of hormonotoxins and immunotoxins.     

The base sequence of the nifF gene of Klebsiella pneumoniae and homology of the predicted amino acid sequence of its protein product to other flavodoxins.

The nucleotide sequence of a 629 base-pair segment of DNA spanning the nifF gene of Klebsiella pneumoniae is presented. The structural gene comprises 531 base-pairs (175 codons, excluding the translational initiator and terminator) encoding an acidic polypeptide of 18950 Da. The nifF product thus belongs to the long-chain class of flavodoxins. It shows some sequence homology to the short-chain flavodoxins from Desulfovibrio vulgaris, Clostridium MP and Megasphaera elsdenii, and much stronger homology to long-chain flavodoxins from Azotobacter vinelandii and Anacystis nidulans. The long chain flavodoxins thus seem to constitute a well-conserved sub-group. The homology with the A. vinelandii flavodoxin is particularly strong, which may reflect their common function in nitrogen fixation.     

The amino acid sequence of the Azotobacter vinelandii flavodoxin.

The amino acid sequence of a group II flavodoxin, the $\text{Azotobacter vinelandii}$ flavodoxin has been determined. The FMN-redox protein was shown to exist as a single polypeptide chain and to contain 179 amino acids. Despite the rather low amino acid sequence homology with the other flavodoxins sequenced, it is concluded that sequences of the group I and group II flavodoxins are homologous. The major differences between the group I and group II flavodoxins appears to be a lengthening in the C-terminal region in the group II flavodoxins.     

Characterization of bovine placental lactogen as a glycoprotein with N-linked and O-linked carbohydrate side chains

In a previous report we showed that purified bovine placental lactogen (bPL) exists in two isoforms in the 31,000-33,000 Mr range, each with at least five isoelectric variants differing in approximately 2 orders of magnitude in isoelectric points (pI) 4-6. The multiple isoelectric variants are unique to the bovine hormone. In an effort to determine the nature of these variants endo- and exoglycohydrolase digestions were conducted to determine if this hormone was glycosylated. Analysis of peptide/N-glycosidase F and endoglycosidase F digests of radioiodinated bPL on one-dimensional gel electrophoresis showed a Mr decrease from 31,000 to 24,000 and 33,000 to 26,000 for the two isoforms. Digestion with a mixture of neuraminidase plus mixed exoglycosidases resulted in a Mr decrease of 4,000. Digestion with neuraminidase resulted in a Mr decrease of 2,000. Further analysis of peptide/N-glycosidase F- and neuraminidase-treated bPL by two-dimensional gel electrophoresis showed the isoelectric variants shifted from pI 4.4-6.3 to 4.9-8.0. The sialic acid residues on the N-linkage are responsible for the pronounced acidic character of bPL, but do not account for the residual charge heterogeneity as the different isoelectric variants persist after sialic acid removal. The apparent Mr of the protein after removal of N-linked carbohydrate residues is similar to that of PRL and GH. These enzymatic digestion results demonstrate the presence of N-linked complex oligosaccharide residues attached to the beta-amide group of an asparagine residue. Analyses of the sugar content of the molecule were consistent with the presence of one biantennary N-linked and two O-linked carbohydrate chains.     

Redox potentials of algal and cyanobacterial flavodoxins.

The redox potentials of flavodoxins from the cyanobacteria Synechococcus PCC 6301 (formerly Anacystis nidulans) and Nostoc strain MAC, and from the red alga Chondrus crispus, were determined by potentiometric titration. For the oxidized-semiquinone interconversion the potentials at pH 7.0 of the three flavodoxins were between -210 and -235 mV, and these were pH-dependent over the range pH 6.9-8.2. For the semiquinone-reduced interconversion the potentials of the cyanobacterial flavodoxins were close to -414 mV, and that for the algal flavodoxin, -370 mV, is the highest reported in this group of flavoproteins.     

The neural type II regulatory subunit of cAMP-dependent protein kinase is present and regulated by hormones in the rat ovary

In this study purified isoforms of rat ovarian regulatory subunit of type II cAMP-dependent protein kinase (R-II) were compared with R-II purified from rat brain. A special neural form of R-II has been previously described in bovine brain. Analysis by one-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis resolved three isoforms of rat ovarian R-II (R-II54, Mr = 54,000; R-II52, Mr = 52,000; and R-II51, Mr = 51,000) compared to two R-II isoforms in rat brain (R-II54 and R-II52). Polychromatic silver-stained peptide maps of purified R-II subunits indicated that peptides generated from both rat ovarian R-II52 and R-II51 were similar (if not identical) to the peptides of the neural form, R-II52, purified from rat brain. These peptides differed markedly from those generated from R-II54 of either rat ovary, brain, or heart. Ovarian R-II52/51 photoaffinity labeled with 8-N3-[32P]cAMP and analyzed by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis was shown to consist of three (rather than two) isoelectric variants, which were similar to three variants resolved from rat brain R-II and clearly distinct from that of rat heart R-II54. An antibody which recognized both the R-II54 and R-II52/51 isoforms of rat ovarian extracts also recognized both forms of rat brain R-II (R-II54 and R-II52) and similar forms in extracts of rat adrenal and parotid glands. These results strongly suggest that the R-II52 isoform previously designated as a neural specific form of R-II is present in high concentrations in a nonneural tissue, the rat ovary.     

Fiber type-specific distribution of M-band proteins in chicken muscle

The functions of two myofibrillar proteins, myomesin (Mr 185,000) and M-protein (Mr 165,000), associated with the M-band are as yet unknown. To extend our knowledge of these proteins, we have examined chicken striated muscles with fast and slow contractile properties, e.g., pectoralis major, PLD, ALD, medial adductor, and lateral adductor, to determine the expression and isoform composition of myomesin and M-protein in various muscles and fiber types. The high molecular weight M-band proteins were characterized and quantitated using monoclonal antibodies in immunoblotting and double-antibody sandwich ELISA. Fiber specificity was determined by immuno- and enzyme histochemistry. In addition to the previously reported Mr 195,000 and 190,000 isoforms of myomesin in heart [Grove et al. (1985): J Cell Biol 101:1431], the Mr 185,000 myomesin in skeletal muscles may represent different isoforms in fast and slow muscles on the basis of distinctive degradation patterns. M-protein has the same molecular weight in striated chicken muscles and degradation patterns indicate only one isoform. The low quantities of M-protein in slow muscles were shown to be due to the absence of M-protein in two of the generally recognized slow fiber types, types I and III. Thus, M-protein was present only in fast type II fibers, whereas myomesin was ubiquitous in all fiber types. Whatever the causal relationship, M-protein appears to function in fast motor units composed of type II fibers.     

Modulation of actin-bundling activity of 55-kDa protein by multiple isoforms of tropomyosin

Cultured rat cells contain five isoforms of tropomyosin (Matsumura, F., Yamashiro-Matsumura, S., and Lin, J.J.-C. (1983) J. Biol. Chem. 258, 6636-6644). To explore the roles of the multiple tropomyosin isoforms in the microfilament organization of cultured cells, we have examined effects of tropomyosins on the bundling activity of the 55-kDa protein recently purified from HeLa cells (Yamashiro-Matsumura, S., and Matsumura, F. (1985) J. Biol. Chem. 260, 5087-5097). Maximum bundling of F-actin was observed at a molar ratio of 55-kDa protein to actin higher than 1:8. None of the isoforms of cultured rat cell tropomyosin significantly altered the F-actin-bundling activity of 55-kDa protein at this ratio, whereas skeletal muscle tropomyosin inhibited the bundling activity to about 50%. Also, cultured cell tropomyosins did not inhibit binding of 55-kDa protein to actin, whereas skeletal muscle tropomyosin inhibited it by 50%. The effect of 55-kDa protein on the binding of tropomyosin to actin varied with the isoform type of tropomyosin. Most (80%) of the tropomyosins with low Mr values (Mr 32,400 or 32,000) were caused to dissociate from actin by 55-kDa protein, but only 20% of tropomyosins with high Mr values (Mr 40,000 or 36,500) was dissociated from actin in these conditions. Immunofluorescence has shown that, while tropomyosin was localized in stress fibers, 55-kDa protein was found in microspikes as well as stress fibers, both of which are known to contain bundles of microfilaments. Therefore, we suggest that 55-kDa protein together with the multiple tropomyosin isoforms may regulate the formation of two types of actin-filament bundles, bundles containing tropomyosin and those without tropomyosin.