Determination of the 1-ethyl-3-[(3-dimethylamino)propyl]-carbodiimide- induced cross-link between the beta and epsilon subunits of Escherichia coli F1-ATPase. (25/172)

The zero-length cross-link between the inhibitory epsilon subunit and one of three catalytic beta subunits of Escherichia coli F1-ATPase (alpha 3 beta 3 gamma delta epsilon), induced by a water-soluble carbodiimide, 1-ethyl-3-[(3-dimethylamino) propyl]-carbodiimide (EDC), has been determined at the amino acid level. Lability of cross-linked beta-epsilon to base suggested an ester cross-link rather than the expected amide. A 10-kDa cross-linked CNBr fragment derived from beta-epsilon was identified by electrophoresis on high percentage polyacrylamide gels. Sequence analysis of this peptide revealed the constituent peptides to be Asp-380 to Met-431 of beta and Glu-96 to Met-138 of epsilon. Glu-381 of beta was absent from cycle 2 indicating that it was one of the cross-linked residues, but no potential cross-linked residue in epsilon was identified in this analysis. A form of epsilon containing a methionine residue in place of Val-112 (epsilon V112M) was produced by site-directed mutagenesis. epsilon V112M was incorporated into F1-ATPase which was then cross-linked with EDC. An 8-kDa cross-linked CNBr fragment of beta-epsilon V112M was shown to contain the peptide of epsilon between residues Glu-96 and Met-112 and the peptide of beta between residues Asp-380 and Met-431. Again residue Glu-381 of beta was notably reduced and no missing residue from the epsilon peptide could be identified, but the peptide sequence limited the possible choices to Ser-106, Ser-107, or Ser-108. Furthermore, an epsilon mutant in which Ser-108 was replaced by cysteine could no longer be cross-linked to a beta subunit in F1-ATPase by EDC. Both mutant forms of epsilon supported growth of an uncC-deficient E. coli strain and inhibited F1-ATPase. These results indicate that the EDC-induced cross-link between the beta and epsilon subunits of F1-ATPase is an ester linkage between beta-Glu-381 and, likely, epsilon-Ser-108. As these residues must be located immediately adjacent to one another in F1-ATPase, our results define a site of subunit-subunit contact between beta and epsilon.  (+info)

The PSI-E subunit of photosystem I binds ferredoxin:NADP+ oxidoreductase. (26/172)

A photosystem I complex containing the polypeptides PSI-A to PSI-L, light-harvesting complex I and ferredoxin:NADP+ oxidoreductase has been isolated from barley using the non-ionic detergent n-decyl-beta-D-maltopyranoside. The ratio between bound ferredoxin:NADP+ oxidoreductase and P700 is 0.4 +/- 0.2. The complex is highly active in catalyzing light-induced transfer of electrons from plastocyanin to NADP+ at rates of 280 +/- 150 and 1800 +/- 800 mumol NADPH/(mg chl.h), without and in the presence of saturating amounts of exogenously added ferredoxin:NADP+ oxidoreductase, respectively. Endogenously bound ferredoxin:NADP+ oxidoreductase interacts with the PSI-E subunit as demonstrated by cross-linking experiments using two different types of cross-linkers and identification of the products by Western blotting and the use of monospecific antibodies.  (+info)

Involvement of caldesmon at the actin-myosin interface. (27/172)

Addition of myosin subfragment 1 (S-1) to the actin-caldesmon binary complex, which forms bundles of actin filaments resulted in the formation of actin/caldesmon-decorated filaments [Harricane, Bonet-Kerrache, Cavadore & Mornet (1991) Eur. J. Biochem. 196, 219-224]. The present data provide further evidence that caldesmon and S-1 compete for a common actin-binding region and demonstrate that a change occurs in the actin-myosin interface induced by caldesmon. S-1 digested by trypsin, which has an actin affinity 100-fold weaker than that of native S-1, was efficiently removed from actin by caldesmon, but not completely dissociated. This particular ternary complex was stabilized by chemical cross-linking with carbodi-imide, which does not have any spacer arm, and revealed contact interfaces between the different protein components. Cross-linking experiments showed that the presence of caldesmon had no effect on stabilization of actin-(20 kDa domain), whereas the actin-(50 kDa domain) covalent association was significantly decreased, to the point of being virtually abolished.  (+info)

Activation of ATPase activity of 14S dynein from Tetrahymena cilia by microtubules. (28/172)

The ATPase activity of 14S dynein was activated by the presence of microtubule-associated-protein-free microtubules. The activation was 2.5-3.5 fold at 10 mg microtubule/ml, and the activity increased further with increasing microtubule concentration. The microtubule-14S-dynein complex, microtubule bundles with 14S dynein, was treated with a zero-length chemical cross-linker, 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC). The ATPase activity of the complex responded to EDC in a biphasic, concentration-dependent manner and, at most, it was enhanced 5-10 fold. The complex treated with EDC was no longer unbundled by addition of ATP, as revealed by electron-microscopic observation. Several ATP analogues, which support in vitro microtubule translocation mediated by 14S dynein, were turned over faster by this mechanochemical enzyme in the presence of microtubules than in their absence. However, some ATP analogues which do not support the translocation were also turned over faster in the presence of microtubules. Thus, microtubule-dynein motility and substrate-turnover activation are not tightly coupled, which indicates that all three major motor systems, actin- heavy-meromyosin, microtubule-kinesin [Shimizu, T., Furusawa, K., Ohashi, S., Toyoshima, Y. Y., Okuno, M., Malik, F. & Vale, R. D. (1991) J. Cell Biol. 112, 1189-1197] and microtubule-dynein, have this characteristic property in common.  (+info)

Regulation of the actin-myosin interaction by titin. (29/172)

Titin is known to interact with actin thin filaments within the I-band region of striated muscle sarcomeres. In this study, we have used a titin fragment of 800 kDa (T800) purified from striated skeletal muscle to measure the effect of this interaction on the functional properties of the actin-myosin complex. MALDI-TOF MS revealed that T800 contains the entire titin PEVK (Pro, Glu, Val, Lys-rich) domain. In the presence of tropomyosin-troponin, T800 increased the sliding velocity (both average and maximum values) of actin filaments on heavy-meromyosin (HMM)-coated surfaces and dramatically decreased the number of stationary filaments. These results were correlated with a 30% reduction in actin-activated HMM ATPase activity and with an inhibition of HMM binding to actin N-terminal residues as shown by chemical cross-linking. At the same time, T800 did not affect the efficiency of the Ca(2+)-controlled on/off switch, nor did it alter the overall binding energetics of HMM to actin, as revealed by cosedimentation experiments. These data are consistent with a competitive effect of PEVK domain-containing T800 on the electrostatic contacts at the actin-HMM interface. They also suggest that titin may participate in the regulation of the active tension generated by the actin-myosin complex.  (+info)

Differential light chain assembly influences outer arm dynein motor function. (30/172)

Tctex1 and Tctex2 were originally described as potential distorters/sterility factors in the non-Mendelian transmission of t-haplotypes in mice. These proteins have since been identified as subunits of cytoplasmic and/or axonemal dyneins. Within the Chlamydomonas flagellum, Tctex1 is a subunit of inner arm I1. We have now identified a second Tctex1-related protein (here termed LC9) in Chlamydomonas. LC9 copurifies with outer arm dynein in sucrose density gradients and is missing only in those strains completely lacking this motor. Zero-length cross-linking of purified outer arm dynein indicates that LC9 interacts directly with both the IC1 and IC2 intermediate chains. Immunoblot analysis revealed that LC2, LC6, and LC9 are missing in an IC2 mutant strain (oda6-r88) that can assemble outer arms but exhibits significantly reduced flagellar beat frequency. This defect is unlikely to be due to lack of LC6, because an LC6 null mutant (oda13) exhibits only a minor swimming abnormality. Using an LC2 null mutant (oda12-1), we find that although some outer arm dynein components assemble in the absence of LC2, they are nonfunctional. In contrast, dyneins from oda6-r88, which also lack LC2, retain some activity. Furthermore, we observed a synthetic assembly defect in an oda6-r88 oda12-1 double mutant. These data suggest that LC2, LC6, and LC9 have different roles in outer arm assembly and are required for wild-type motor function in the Chlamydomonas flagellum.  (+info)

Effect of nucleotide on interaction of the 567-578 segment of myosin heavy chain with actin. (31/172)

To probe the effect of nucleotide on the formation of ionic contacts between actin and the 567-578 residue loop of the heavy chain of rabbit skeletal muscle myosin subfragment 1 (S1), the complexes between F-actin and proteolytic derivatives of S1 were submitted to chemical cross-linking with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide. We have shown that in the absence of nucleotide both 45 kDa and 5 kDa tryptic derivatives of the central 50 kDa heavy chain fragment of S1 can be cross-linked to actin, whereas in the presence of MgADP.AlF4, only the 5 kDa fragment is involved in cross-linking reaction. By the identification of the N-terminal sequence of the 5-kDa fragment, we have found that trypsin splits the 50 kDa heavy chain fragment between Lys-572 and Gly-573, the residues located within the 567-578 loop. Using S1 preparations cleaved with elastase, we could show that the residue of 567-578 loop that can be cross-linked to actin in the presence of MgADP.AlF4 is Lys-574. The observed nucleotide-dependent changes of the actin-subfragment 1 interface indicate that the 567-578 residue loop of skeletal muscle myosin participates in the communication between the nucleotide and actin binding sites.  (+info)

Interaction between G-actin and myosin subfragment-1 probed by covalent cross-linking. (32/172)

The topography of rapid equilibrium complexes formed between G-actin and myosin subfragment-1, which are the first kinetic intermediates in the polymerization process into F-acto-S1 filaments, has been probed by chemical cross-linking. In the absence of ATP, cross-linking of G-actin-S1 complexes by 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide (EDC) yielded a major 165-170-kDa and a fainter 200-205-kDa doublet polypeptide. The actin:S1 molar ratio was 1 in the EDC-cross-linked complexes, using either double labeling techniques or the method combining EDC + N-hydroxysuccinimide. Chemical cleavages of the covalently cross-linked complexes by formic acid and N-hydroxylamine (Sutoh, K. (1983) Biochemistry 22, 1579-1585) showed that in the main cross-linked 165-kDa polypeptide, the 1-12 acidic N-terminal region of actin was covalently linked to the lysine-rich region connecting the central 50-kDa domain to the C-terminal 20-kDa domain of S1, as in F-acto-S1 complexes. G-actin, but not F-actin, was covalently cross-linked to S1 by N,N'-paraphenylenedimaleimide (p-PDM). A major 195-kDa and a minor 165-kDa polypeptide were obtained, could be separated from actin and S1 by DEAE-cellulose chromatography, and did not exhibit actin-activated Mg-ATPase activity. Both EDC-cross-linked and p-PDM-cross-linked complexes between G-actin and S1 could be incorporated into F-acto-S1 decorated filaments. The C-terminal cysteine 374 of actin is involved in the p-PDM cross-linked 195-kDa complex. Accordingly, a covalent photocross-linked 200-kDa conjugate was formed between S1 heavy chain and benzophenone-G-actin, obtained by covalent modification of Cys374 by benzophenonemaleimide (Tao, T., Lamkin, M., and Scheiner, C. J. (1985) Arch. Biochem. Biophys. 240, 627-634). These results demonstrate that (i) G-actin-S1 and F-actin-S1 complexes display a large similarity in the EDC-cross-linked electrostatic close contacts and (ii) a change in the environment of Cys374 is linked to the polymerization into F-actin-S1 decorated filaments.  (+info)