Fesselin: a novel synaptopodin-like actin binding protein from muscle tissue.

A novel actin binding protein has been isolated from chicken gizzard muscle. When isolated, a pair of proteins with apparent molecular weights of 79 kDa and 103 kDa are obtained; both proteins have a pI near 9.3. Peptide mapping indicates that these proteins are related. Antibodies against this protein cross-reacted with proteins from other smooth muscle containing tissues as well as skeletal and heart muscle. Traces of cross-reactive material were also detected in brain and kidney tissue. The affinity of this protein for actin is ca. 1x10(6) M(-1). Interestingly, this actin binding protein is a potent actin-bundling agent. A partial sequence analysis confirmed that there were no previously reported homologues in smooth muscle. However, considerable homology was found with the protein synaptopodin that is found in nervous tissue and kidney but is absent from muscle tissue. It is likely that the new protein is a member of the synaptopodin family. We call the smooth muscle actin binding protein fesselin.

Caldesmon: binding to actin and myosin and effects on elementary steps in the ATPase cycle.

The actin binding protein caldesmon inhibits the actin-activation of myosin ATPase activity. The steps in the cycle of ATP hydrolysis that caldesmon could inhibit include: (1) the binding of myosin to actin, (2) the transition between any two actin-myosin states and (3) the distribution between inactive and active states of actin. The analysis of these possibilities is complicated because caldesmon binds to both myosin and actin and because each caldesmon molecule binds to several actin monomers. This paper reviews procedures for analysing these interactions and summarizes current information on the stability and dynamics of the interaction of caldesmon with actin and myosin. Possible effects of caldesmon on transitions within the ATPase cycle of actomyosin are also discussed.

Relationship between stability and function for isolated domains of troponin C.

Results of spectroscopic thermal and chemical denaturation studies and calcium binding studies are presented for a series of five recombinant chicken troponin C fragments. They were designed to assess the effects of domain isolation, N-helix, and D/E linker helix on stability and calcium affinity. Four of the fragments include the N-terminal regulatory domain and one the C-terminal domain. For the regulatory domain, deletion of the N-helix or the D/E linker decreases the stability of the apo form as measured by delta GN-->U,25. Separation of the domains also decreases the stability. Differences in values of delta GN-->U,25 derived from urea and guanidine hydrochloride studies allowed an estimation of the electrostatic component of the free energy of unfolding. Our measurements provide the first quantitative estimate of the stability for the apo-C-domain (delta GN-->U,25 = -1.8 kcal/mol) which was obtained using the interaction free energy formalism of Schellman. There is an inverse correlation between calcium affinity, binding cooperativity, and stability for all of these homologously structured fragments. The calcium affinity and cooperativity are highest for the unstructured C-domain and lowest for the N-domain which has the highest stability. In view of the direct effects on the folding stability of the apo-N-domain, the N-helix and the bilobed domain organization of TnC are necessarily involved in the fine-tuning of the affinity and cooperativity of calcium binding. Though not directly involved in calcium coordination, these structural features are important for signal transmission by troponin C in the troponin complex.

Interaction of troponin C and troponin C fragments with troponin I and the troponin I inhibitory peptide.

We have quantitated the interactions of two rabbit skeletal troponin C fragments with troponin I and the troponin I inhibitory peptide. The calcium binding properties of the fragments and the ability of the fragments to exert control in the regulated actomyosin ATPase assay have also been studied. The N- and C-terminal divalent metal binding domains of rabbit skeletal troponin C, residues 1-97 and residues 98-159, respectively, were prepared by specific cleavage at cysteine-98 and separation by gel exclusion chromatography. Both of the troponin C fragments bind calcium. The calcium affinity of the weak sites within the N-terminal fragment is about an order of magnitude greater than is reported for these sites in troponin C, suggesting interaction between the calcium-saturated strong sites and the weak sites. Stoichiometric binding (1:1) of the troponin I inhibitory peptide to each fragment and to troponin C increased the calcium affinities of the fragments and troponin C. Complex formation was detected by fluorescence quenching or enhancement using dansyl-labeled troponin C (and fragments) or tryptophan-labeled troponin I inhibitory peptide. The troponin C fragments bind to troponin I with 1:1 stoichiometry and approximately equal affinities (1.6 x 10(6) M-1) which are decreased 4-fold in the presence of magnesium versus calcium. These calcium effects are much smaller than is observed for troponin C. The summed free energies for the binding of the troponin C fragments to troponin I are much larger than the free energy of binding troponin C. This suggests a large positive interaction free energy for troponin C binding to troponin I relative to the fragments.(ABSTRACT TRUNCATED AT 250 WORDS)