Interaction of bacterial flagellum filaments with skeletal muscle myosin.

Interaction of isolated bacterial flagellum filaments (BFF) and intact flagella from E. coli MS 1350 and B. brevis G.-B.p+ with rabbit skeletal myosin was studied. BFF were shown to coprecipitate with myosin (but not with isolated myosin rod) at low ionic strength, that is, under conditions of myosin aggregation. The data of electron microscopy indicate that filaments of intact bacterial flagella interact with isolated myosin heads (myosin subfragment 1, S1), and this interaction is fully prevented by addition of Mg2+ -ATP. Addition of BFF inhibited both K+ -EDTA- and Ca2+ -ATPase activity of skeletal muscle myosin, but had no effect on its Mg2+ -ATPase activity. Monomeric flagellin did not coprecipitate with myosin and had no effect on its ATPase activities. BFF were shown to compete with F-actin in myosin binding. It is concluded that BFF interact with myosin heads and affect their ATPase activity. Thus, BFF composed of a single protein flagellin are in many respects similar to actin filaments. Common origin of actin and flagellin may be a reason for this similarity.

Polymerization of bacteriophage T4 tail sheath protein mutants truncated at the C-termini.

Gene 18 of bacteriophage T4 encodes the contractile protein of the tail sheath. Previous work has shown that the full-length recombinant gene product (gp) 18 of 658 amino acid residues assembles in Escherichia coli cells into a long polysheath structure. However, the gp18 mutants truncated at the N-termini form insoluble aggregates similar to inclusion bodies. In this study, six plasmid vectors expressing the recombinant gp18 proteins truncated at the C-termini have been constructed. The CDelta58, CDelta129, CDelta152, C[g1]72, CDelta248, and CDelta287 proteins contain 600, 529, 506, 486, 410, and 371 residues of the full-length gp18 molecule, respectively. All the recombinant proteins were soluble and, except for the CDelta287 mutant, were assembled into polysheath-related structures. Electron microscopy of negatively stained purified proteins was performed and the resulting images were analyzed by computing their Fourier transforms. The CDelta58 and CDelta129 mutants, in addition to forming common contracted-type polysheath structures, assembled into thinner filaments that we called "noncontracted polysheaths" (NCP). The CDelta152, CDelta172, and CDelta248 proteins assembled into the NCP type only. Image processing showed that the NCP filaments significantly differ from both extended sheaths of T4 particle and polysheaths. The structure of the NCP filaments might correspond to the transitional helices postulated by Moody (J. Mol. Biol., 1973, 80, 613-636) that appeared during the process of tail contraction. Our results suggest that a short region at the C-terminus of the CDelta129 protein determines the contractile properties of the gp18 molecule. The shortest, the CDelta287 protein, does not assemble into regular structures, thus indicating that a sequence's stretch at the C-end of the CDelta248 mutant might be responsible for polymerization of gp18.

Properties of recombinant bacteriophage T4 tail sheath protein and its deletion fragments.

A vector for expression of recombinant bacteriophage T4 tail sheath protein (gp18) under control of phage T7 promoter in Escherichia coli cells has been constructed. The entire length recombinant gp18 (659 amino acids) polymerizes in vivo into extended polysheaths. To study gp18 folding mechanisms, six vectors for expression of deletion mutants have been constructed. Three proteins--1N, 2N, and 3N--contain, respectively, 268, 316, and 372 amino acids of the gp18 N-tail region. The other three fragments--1C, 2C, and 3C--contain, respectively, 455, 356, and 288 amino acids of the gp18 C-tail. The fragments 1N, 2N, 1C, 2C, and 3C form insoluble aggregates during expression. However, fragment 3N accumulates in soluble form in the cellular cytoplasm and does not form polymeric structures; this has allowed an effective purification method to be developed for it. The interaction of monoclonal antibodies against recombinant gp18 with protein fragments and with phage sheath before and after contraction has been studied. The fragment 3N seems to be a stable domain of native phage sheath gp18.

[Organization of biochemical systems]. / Organizatsiia biokhimicheskikh sistem.

Own and literature data on molecular organization of biological system from a single enzymatic complex to a large association of metabolon type are reviewed with emphasis on characterization of forces involved in the process of aggregation of protein molecules and a role of shaperons in organization of some complexes. Possible mechanism of chaperon transport along cytoskeleton structures is suggested. Problems of a theory of metabolon organization of enzymes and a role of an anchor in coordination of action of multienzyme complexes are discussed.

[Calorimetric study of stable complexes of myosin subfragment I with adenosine diphosphate and phosphate analogs]. / Kalorimetricheskie issledovaniia stabil'nykh kompleksov subfragmenta 1 miozina s analogami adenozindifosfata i fosfata.

This short review is concerned with the application of the method of differential scanning calorimetry to study the conformational changes of isolated myosin head (myosin subfragment 1, S1) caused by the formation of the S1 complexes with Mg(2+)-ADP and P(i) analogues such as orthovanadate (V), aluminium fluoride (AIF4-) or beryllium fluoride (BeFx). These changes of the whole S1 molecule are reflected in a significant increase of S1 thermal stability and in a pronounced increase of the cooperativity of the thermal denaturation. Since the complexes S1-ADP-V, S1-ADP-AIF4- and S1-ADP-BeFx are stable analogues of the S1**-ADP-P(i) transition state of the S1-catalyzed ATP hydrolysis, it is concluded that DSC studies with these complexes offer a new and promising approach to investigate the structural changes which occur in the myosin head during Mg(2+)-ATPase reaction.

A study on the mechanism of polymerisation of Bacillus brevis flagellin.

Optical properties of intact flagellin and of modified-on-tyrosine flagellin incapable of self-assembly have been studied by the circular dichroism (CD) method. The CD spectra of both flagellins do not change and virtually coincide within the pH range from 2.9 to 10.0. In the presence of polyethylene glycol (PEG) and ammonium sulfate which accelerate flagellin polymerization, the character of the CD spectra changes and depends on pH. The increase in the PEG content to 20% and that in the ammonium sulfate content to 1 M over the pH range from 4.3 to 10.0 results in a significant rise of the molar ellipticity at 222 nm ([theta]222) of both flagellins. However, [theta]222 does not reach values typical for bacterial flagella. The results obtained are discussed with respect to conformational changes in the flagellin molecule during polymerization.

Effects of nucleotide binding on thermal transitions and domain structure of myosin subfragment 1.

The thermal unfolding and domain structure of myosin subfragment 1 (S1) from rabbit skeletal muscles and their changes induced by nucleotide binding were studied by differential scanning calorimetry. The binding of ADP to S1 practically does not influence the position of the thermal transition (maximum at 47.2 degrees C), while the binding of the non-hydrolysable analogue of ATP, adenosine 5'-[beta, gamma-imido]triphosphate (AdoPP[NH]P) to S1, or trapping of ADP in S1 by orthovanadate (Vi), shift the maximum of the heat adsorption curve for S1 up to 53.2 and 56.1 degrees C, respectively. Such an increase of S1 thermostability in the complexes S1-AdoPP[NH]P and S1-ADP-Vi is confirmed by results of turbidity and tryptophan fluorescence measurements. The total heat adsorption curves for S1 and its complexes with nucleotides were decomposed into elementary peaks corresponding to the melting of structural domains in the S1 molecule. Quantitative analysis of the data shows that the domain structure of S1 in the complexes S1-AdoPP[NH]P and S1-ADP-Vi is similar and differs radically from that of nucleotide-free S1 and S1 in the S1-ADP complex. These data are the first direct evidence that the S1 molecule can be in two main conformations which may correspond to different states during the ATP hydrolysis: one of them corresponds to nucleotide-free S1 and to the complex S1-ADP, and the other corresponds to the intermediate complexes S1-ATP and S1-ADP-Pi. Surprisingly it turned out that the domain structure of S1 with ADP trapped by p-phenylene-N, N'-dimaleimide (pPDM) thiol cross-linking almost does not differ from that of the nucleotide-free S1. This means that pPDM-cross-linked S1 in contrast to S1-AdoPP[NH]P and S1-ADP-Vi can not be considered a structural analogue of the intermediate complexes S1-ATP and S1-ADP-Pi.