Interaction between PEVK-titin and actin filaments: origin of a viscous force component in cardiac myofibrils.

The giant muscle protein titin contains a unique sequence, the PEVK domain, the elastic properties of which contribute to the mechanical behavior of relaxed cardiomyocytes. Here, human N2-B-cardiac PEVK was expressed in Escherichia coli and tested-along with recombinant cardiac titin constructs containing immunoglobulin-like or fibronectin-like domains-for a possible interaction with actin filaments. In the actomyosin in vitro motility assay, only the PEVK construct inhibited actin filament sliding over myosin. The slowdown occurred in a concentration-dependent manner and was accompanied by an increase in the number of stationary actin filaments. High [Ca(2+)] reversed the PEVK effect. PEVK concentrations >/=10 microgram/mL caused actin bundling. Actin-PEVK association was found also in actin fluorescence binding assays without myosin at physiological ionic strength. In cosedimentation assays, PEVK-titin interacted weakly with actin at 0 degrees C, but more strongly at 30 degrees C, suggesting involvement of hydrophobic interactions. To probe the interaction in a more physiological environment, nonactivated cardiac myofibrils were stretched quickly, and force was measured during the subsequent hold period. The observed force decline could be fit with a three-order exponential-decay function, which revealed an initial rapid-decay component (time constant, 4 to 5 ms) making up 30% to 50% of the whole decay amplitude. The rapid, viscous decay component, but not the slower decay components, decreased greatly and immediately on actin extraction with Ca(2+)-independent gelsolin fragment, both at physiological sarcomere lengths and beyond actin-myosin overlap. Steady-state passive force dropped only after longer exposure to gelsolin. We conclude that interaction between PEVK-titin and actin occurs in the sarcomere and may cause viscous drag during diastolic stretch of cardiac myofibrils. The interaction could also oppose shortening during contraction.

Structure of a genetically engineered molecular motor.

Molecular motors move unidirectionally along polymer tracks, producing movement and force in an ATP-dependent fashion. They achieve this by amplifying small conformational changes in the nucleotide-binding region into force-generating movements of larger protein domains. We present the 2.8 A resolution crystal structure of an artificial actin-based motor. By combining the catalytic domain of myosin II with a 130 A conformational amplifier consisting of repeats 1 and 2 of alpha-actinin, we demonstrate that it is possible to genetically engineer single-polypeptide molecular motors with precisely defined lever arm lengths and specific motile properties. Furthermore, our structure shows the consequences of mutating a conserved salt bridge in the nucleotide-binding region. Disruption of this salt bridge, which is known to severely inhibit ATP hydrolysis activity, appears to interfere with formation of myosin's catalytically active 'closed' conformation. Finally, we describe the structure of alpha-actinin repeats 1 and 2 as being composed of two rigid, triple-helical bundles linked by an uninterrupted alpha-helix. This fold is very similar to the previously described structures of alpha-actinin repeats 2 and 3, and alpha-spectrin repeats 16 and 17.

Role of the salt-bridge between switch-1 and switch-2 of Dictyostelium myosin.

Motifs N2 and N3, also referred to as switch-1 and switch-2, form part of the active site of molecular motors such as myosins and kinesins. In the case of myosin, N3 is thought to act as a gamma-phosphate sensor and moves almost 6 A relative to N2 during the catalysed turnover of ATP, opening and closing the active site surrounding the gamma-phosphate. The closed form seems to be necessary for hydrolysis and is stabilised by the formation of a salt-bridge between an arginine residue in N2 and a glutamate residue in N3. We examined the role of this salt-bridge in Dictyostelium discoideum myosin. Myosin motor domains with mutations E459R or R238E, that block salt-bridge formation, show defects in nucleotide-binding, reduced rates of ATP hydrolysis and a tenfold reduction in actin affinity. Inversion of the salt-bridge in double-mutant M765-IS eliminates most of the defects observed for the single mutants. With the exception of a 2,500-fold higher KMvalue for ATP, the double-mutant displayed enzymatic and functional properties very similar to those of the wild-type protein. Our results reveal that, independent of its orientation, the salt-bridge is required to support efficient ATP hydrolysis, normal communication between different functional regions of the myosin head, and motor function.

Rabbit skeletal muscle alpha alpha-tropomyosin expressed in baculovirus-infected insect cells possesses the authentic N-terminus structure and functions.

When expressed in E. coli, skeletal muscle alpha-tropomyosin has an unacetylated N-terminus. Unacetylated alpha-tropomyosin lacks important functions; this is non-polymerizable and has a low affinity to actin. In the present work, in order to obtain fully functional recombinant alpha-tropomyosin, rabbit skeletal muscle alpha-tropomyosin (alpha-tropomyosin BV) has been expressed in baculovirus-infected insect cells. alpha-TropomyosinBV was not distinguishable from the authentic tropomyosin, not only in functional properties but also in blocked N-terminus. To know the N-terminus structure of alpha-tropomyosinBV, the N-terminal segment six amino acids long, MDAIKK, has been specifically and efficiently removed from alpha-tropomyosinBV by use of an immobilized proteolytic enzyme system based on E. coli cell bodies which carry the ompT gene product, a proteolytic enzyme localized on the outer cell wall of E. coli. The structure of recombinant alpha-tropomyosinBV was shown to be identical to the authentic protein by electrospray mass spectrometry and protein sequencing analysis. Additionally, electrospray mass spectrometry indicated a single phosphorylation not only in alpha- but also beta-tropomyosin chains in the rabbit skeletal muscle. The differentiated susceptibilities of potential ompT cleavage sites are indicative of a non-coiled-coil conformation of the N-terminus of alpha-tropomyosin.

Reconstitution of rabbit skeletal muscle troponin from the recombinant subunits all expressed in and purified from E. coli.

Three subunits of rabbit skeletal muscle troponin were expressed in and purified from Escherichia coli. The procedures were optimized, and the reconstituted troponin complex is highly homogeneous, stable, and obtainable in large quantities, allowing us to conduct crystallization studies of the troponin complex. The three subunits expressed and purified are beta-TnT(N'-208), TnI(C64A, C133S), and the wild type TnC. beta-TnT(N'-208) is a 25 kDa fragment of beta-troponin T, which consists of 208 amino acids and lacks 58 residues in the N-terminal variable region. TnI(C64A, C133S) is a mutant troponin I, in which Cys-64 and Cys-133 are replaced by Ala and Ser, respectively. Each subunit was separately expressed in E. coli, purified by column chromatography including HPLC, and reassembled to form troponin complex. The reconstituted troponin complex was not distinguishable from authentic troponin prepared from rabbit skeletal muscle; the acto-S1 ATPase rate, as well as the superprecipitation, was calcium-sensitive. Small flat crystals up to 0.2 mm long have been reproducibly obtained in preliminary crystallization trials.