Balraj Mittal

Interaction of the enteropathogenic Escherichia coli protein, translocated intimin receptor (Tir), with focal adhesion proteins

When enteropathogenic Escherichia coli (EPEC) attach and infect host cells, they induce a cytoskeletal rearrangement and the formation of cytoplasmic columns of actin filaments called pedestals. The attached EPEC and pedestals move over the surface of the host cell in an actin-dependent reaction [Sanger et al., 1996: Cell Motil Cytoskeleton 34:279-287]. The discovery that EPEC inserts the protein, translocated intimin receptor (Tir), into the membrane of host cells, where it binds the EPEC outer membrane protein, intimin [Kenny et al., 1997: Cell 91:511-520], suggests Tir serves two functions: tethering the bacteria to the host cell and providing a direct connection to the hosts cytoskeleton. The sequence of Tir predicts a protein of 56.8 kD with three domains separated by two predicted trans-membrane spanning regions. A GST-fusion protein of the N-terminal 233 amino acids of Tir (Tir1) binds to alpha-actinin, talin, and vinculin from cell extracts. GST-Tir1 also coprecipitates purified forms of alpha-actinin, talin, and vinculin while GST alone does not bind these three focal adhesion proteins. Biotinylated probes of these three proteins also bound Tir1 cleaved from GST. Similar associations of alpha-actinin, talin, and vinculin were also detected with the C-terminus of Tir, i.e., Tir3, the last 217 amino acids. Antibody staining of EPEC-infected cultured cells reveals the presence of focal adhesion proteins beneath the attached bacteria. Our experiments support a model in which the cytoplasmic domains of Tir recruit a number of focal adhesion proteins that can bind actin filaments to form pedestals. Since pedestals also contain villin, tropomyosin and myosin II [Sanger et al., 1996: Cell Motil. Cytoskeleton 34:279-287], the pedestals appear to be a novel structure sharing properties of both focal adhesions and microvilli.

Observations of Microfilament Bundles in Living Cells Microinjected with Fluorescently Labelled Contractile Proteins

SUMMARY Fluorescently labelled contractile proteins (alpha-actinin and filamin) were used to study the dynamic nature of three types of microfilament bundles: myofibrils, stress fibres and polygonal networks. Cultured muscle and non-muscle cells that were microinjected with fluorescent alpha-actinin rapidly incorporated the labelled protein into Z-bands, stress fibre densities and the polygonal foci. Living, injected cells were then observed for varying periods of time, and changes in orientation and periodicity of the myofibrils, stress fibres and polygonal networks were recorded. Permeabilized cells were also reacted with fluorescently labelled proteins and with contractile protein antibodies in order to analyse further the changes taking place in the myofibrils and stress fibres. In both living cardiac myocytes and living skeletal muscle myotubes, contractile myofibrils were present in the same cell with non-contractile nascent myofibrils. The periodicities of small Z-bodies in the nascent non-contractile myofibrils were shorter than the Z-band spacings in the contractile myofibrils, yet both types of myofibrils contained muscle myosin. Over a period of 24 h, a nascent myofibril in a living, microinjected myotube was observed to grow from Z-body spacings of 0.9–1.3 μm to full sarcomere spacings (2.3 μm). During the same time, nascent myofibrils appeared de novo and Z-band alignment became more ordered in the fully formed myofibrils. Stress fibres were not observed to undergo the predictable type of growth seen in myofibrils, but stress fibre periodicities did change in some fibres; some shortened while others lengthened. The orientation of fibres shifted in cytoplasm of both mobile cells and stationary cells. Attachment plaques and foci also changed position and in some cases subdivided and/or disappeared. Models of stress fibres and polygonal networks are presented that suggest that the changes in the periodicities of the dense bodies in stress fibres and the distances between polygonal foci are related to the movement of the interdigitating actin and myosin filaments.

Targeting of cardiac muscle titin fragments to the Z-bands and dense bodies of living muscle and non-muscle cells.

A 6.5-kb N-terminal region of embryonic chick cardiac titin, including the region previously reported as part of the protein zeugmatin, has been sequenced, further demonstrating that zeugmatin is part of the N-terminal region of titin, and not a separate Z-band protein. This Z-band region of cardiac titin, from both 7- and 19-day embryos as well as from adult animals, was found to contain six different small motifs, termed z-repeats [Gautel et al., 1996: J. Cell Sci. 109:2747-2754], of approximately 45 amino acids each sandwiched between flanking regions containing Ig domains. Fragments of Z-band titin, linked to GFP, were expressed in cultured cardiomyocytes to determine which regions were responsible for Z-band targeting. Transfections of primary cultures of embryonic chick cardiomyocytes demonstrated that the z-repeats play the major role in targeting titin fragments to the Z-band. Similar transfections of skeletal myotubes and non-muscle cells lead to the localization of these cardiac z-repeats in the Z-bands of the myofibrils and the dense bodies of the stress fibers. Over-expression of these z-repeat constructs in either muscle or non-muscle cells lead to the loss of the myofibrils or stress fibers, respectively. The transfection experiments also indicated that small domains of a protein, 40 to 50 amino acids, can be studied for their localization properties in living cells if a suitable linker is placed between these small domains and the much larger 28 kDa GFP protein.

Incorporation of fluorescently labeled actin and tropomyosin into muscle cells

The two major proteins in the I-bands of skeletal muscle, actin and tropomyosin, were each labeled with fluorescent dyes and microinjected into cultured cardiac myocytes and skeletal muscle myotubes. Actin was incorporated along the entire length of the I-band in both types of muscle cells. In the myotubes, the incorporation was uniform, whereas in cardiac myocytes twice as much actin was incorporated in the Z-bands as in any other area of the I-band. Labeled tropomyosin that had been prepared from skeletal or smooth muscle was incorporated in a doublet in the I-band with an absence of incorporation in the Z-band. Tropomyosin prepared from brain was incorporated in a similar pattern in the I-bands of cardiac myocytes but was not incorporated in myotubes. These results in living muscle cells contrast with the patterns obtained when labeled actin and tropomyosin are added to isolated myofibrils. Labeled tropomyosins do not bind to any region of the isolated myofibrils, and labeled actin binds to A-bands. Thus, only living skeletal and cardiac muscle cells incorporate exogenous actin and tropomyosin in patterns expected from their known myofibrillar localization. These experiments demonstrate that in contrast to the isolated myofibrils, myofibrils in living cells are dynamic structures that are able to exchange actin and tropomyosin molecules for corresponding labeled molecules. The known overlap of actin filaments in cardiac Z-bands but not in skeletal muscle Z-bands accounts for the different patterns of actin incorporation in these cells. The ability of cardiac myocytes and non-muscle cells but not skeletal myotubes to incorporate brain tropomyosin may reflect differences in the relative actin-binding affinities of non-muscle tropomyosin and the respective native tropomyosins. The implications of these results for myofibrillogenesis are presented.

Partial characterization of zeugmatin indicates that it is part of the Z-band region of titin.

Zeugmatin is a muscle specific protein discovered by Maher et al. [1985: J. Cell Biol. 101:1871-1883] to be in Z-Bands of muscle and in the dense bodies of smooth muscle. Maher et al. [1985] generated a zeugmatin specific monoclonal antibody, McAb20, and then used immunoaffinity chromatography to isolate a 600-800 kD protein. During myofibrillogenesis of embryonic cardiac muscle, zeugmatin is detected in fully formed Z-bands in the mature myofibrils but not in the Z-bodies of premyofibrils [Rhee et al., 1994: Cell Motil. Cytoskeleton 28:1-24]. Rhee et al. [1994] have postulated that zeugmatin may be responsible for the fusion of the alpha-actinin containing Z-bodies to form the solid Z-Bands of the mature myofibrils. The current studies were undertaken to characterize the properties of zeugmatin. The McAb20 was used to probe a chicken heart lamba gt11 expression library, and three unique positive clones of 1.1, 1.4, and 1.7 kB were isolated. These were inserted into pcDNA3, sequenced, and assembled into a 1.8 kB ORF. A 60% identity with N-terminal region of the human cardiac titin sequence was revealed at the amino acid level. This region of the 1.8 kB zeugmatin sequence is located entirely in the Z-band region of the human cardiac titin molecule. The 1.1 kB clone of zeugmatin was subcloned into pTrcHisC and expressed in bacteria. Bacterial lysates were prepared and run over nickel columns to isolate a 46 kD fusion protein. This fusion protein formed a complex with purified alpha-actinin that could be immunoprecipitated with the zeugmatin specific antibody, McAb 20. The 1.1 kB sequence was transfected into non-muscle cell lines, PtK2 and REF. Twenty-four hours after transfection, the 46 kD zeugmatin peptide, not present in control non-muscle cells, was localized in focal adhesions and in a punctate pattern along the stress fibers. Double immunofluorescence staining revealed that zeugmatin colocalized with the alpha-actinin in the dense bodies and focal contacts of the stress fibers. At longer time points, as the transfected cells accumulated more truncated zeugmatin molecules, the cells lost adhesion plaques and stress fibers, and became detached from the substratum. Our results indicate the zeugmatin is part of the titin molecule that is located within the Z-band and that this section of the titin molecule anchors the actin crosslinking alpha-actinin molecules.

Myotilin dynamics in cardiac and skeletal muscle cells

Myotilin cDNA has been cloned for the first time from chicken muscles and sequenced. Ectopically expressed chicken and human YFP‐myotilin fusion proteins localized in avian muscle cells in the Z‐bodies of premyofibrils and the Z‐bands of mature myofibrils. Fluorescence recovery after photobleaching experiments demonstrated that chicken and human myotilin were equally dynamic with 100% mobile fraction in premyofibrils and Z‐bands of mature myofibrils. Seven myotilin mutants cDNAs (S55F, S55I, T57I, S60C, S60F, S95I, R405K) with known muscular dystrophy association localized in mature myofibrils in the same way as normal myotilin without affecting the formation and maintenance of myofibrils. N‐ and C‐terminal halves of human myotilin were cloned and expressed as YFP fusions in myotubes and cardiomyocytes. N‐terminal myotilin (aa 1–250) localized weakly in Z‐bands with a high level of unincorporated protein and no adverse effect on myofibril structure. C‐terminal myotilin (aa 251–498) localized in Z‐bands and in aggregates. Formation of aggregated C‐terminal myotilin was accompanied by the loss of Z‐band localization of C‐terminal myotilin and partial or complete loss of alpha‐actinin from the Z‐bands. In regions of myotubes with high concentrations of myotilin aggregates there were no alpha‐actinin positive Z‐bands or organized F‐actin. The dynamics of the C‐terminal‐myotilin and N‐terminal myotilin fragments differed significantly from each other and from full‐length myotilin. In contrast, no significant changes in dynamics were detected after expression in myotubes of myotilin mutants with single amino acid changes known to be associated with myopathies.

Arg/Abl-binding protein, a Z-body and Z-band protein, binds sarcomeric, costameric, and signaling molecules.

ArgBP2 (Arg/Abl‐Binding Protein) is expressed at high levels in the heart and is localized in the Z‐bands of mature myofibrils. ArgBP2 is a member of a small family of proteins that also includes vinexin and CAP (c‐Cbl‐associated protein), all characterized by having one sorbin homology (SOHO) domain and three C‐terminal SH3 domains. Antibodies directed against ArgBP2 also react with the Z‐bodies of myofibril precursors: premyofibrils and nascent myofibrils. Expression in cardiomyocytes of plasmids encoding Yellow Fluorescent Protein (YFP) fused to either full length ArgBP2, the SOHO, mid‐ArgBP or the SH3 domains of ArgBP2 led to Z‐band targeting of the fusion proteins, whereas an N‐terminal fragment lacking these domains did not target to Z‐bands. Although ArgBP2 is not found in skeletal muscle cells, YFP‐ArgBP2 did target to Z‐bodies and Z‐bands in cultured myotubes. GST‐ArgBP2‐SH3 bound actin, α‐actinin and vinculin proteins in blot overlays, cosedimentation assays, and EM negative staining techniques. Over‐expression of ArgBP2 and ArgBP2‐SH3 domains, but not YFP alone, led to loss of myofibrils in cardiomyocytes. Fluorescence recovery after photobleaching was used to measure the rapid dynamics of both the full length and some truncated versions of ArgBP2. Our results indicate that ArgBP2 may play an important role in the assembly and maintenance of myofibrils in cardiomyocytes.

Use of Fluorescently Labeled Probes to Analyze Cell Division in Living Cells

Despite all that has been learned about cytokinesis over the last 100 years, * the challenges of identifying the essential molecules involved and of understanding how this important process is initiated and controlled are still unmet. One approach to investigating the process is to microinject living cells with fluorescent probes for particular proteins and monitor dividing cells with video-enhanced imaging technique~.~** The changing intracellular distributions of the proteins can be correlated with the stages of division in single cells. We have microinjected trace amounts of fluorescent probes for actin: and intermediate filaments into PtK, and gerbil fibroma cells and recorded the changes that occurred when those cells divided. We have also exposed these cells to the fluorescent membrane probe 3,3 dihexyloxacarbocyanine iodide (DiOC,( 3)) to examine the relationship of membranes to the mitotic spindle and cytokinetic furrow. Although the contractile force of cytokinesis is known to be actin-myosin based (see ref. 2), it is not known when actin and myosin first become positioned in the cortex where the furrow will form. The question of whether these proteins are recruited from a soluble cytoplasmic pool or migrate in the cortex from the poles to the equator is unanswered. In addition, there are reports that a~t in ~ and myosinL4 are not always present at higher concentrations in the cleavage furrow, as opposed to the cortex outside the furrow of cultured cells. Although these reports disagree with other localization studies5-20 on similar cells, they suggest that actin and myosin are uniformly distributed in the cortex and are locally stimulated to contract in the equatorial cortex. By examining these and other proteins in living cells, some of the problems associated with the use of fixed cells can be avoided, and proteins (and membranes) can be visualized in single cells through all the stages of cell division. Our results suggest that the partitioning of cytoplasm by the mitotic spindle that results in the exclusion of most membranes and intact networks of intermediate filaments9 and allows the concentration of soluble proteins6 may lead to the release from the anaphase spindle of cleavage initiating molecules that diffuse to the equatorial cortex and cause the assembly of the cytokinetic f~rrow. ~~ -~

The myosin filament XV assembly: contributions of 195 residue segments of the myosin rod and the eight C-terminal residues

SummaryA mixture of two peptides of approximately Mr 13 000 has been isolated from a papain digest of LC2 deficient myosin. The peptides assemble into highly ordered aggregates which in one view are made up of strands of pairs of dots with an average side to side spacing of 13.0 nm and an average axial repeat of 9.0 nm. In another view there are strands of single dots with a side-to-side spacing of 7.8 nm and an axial repeat of 9.1 nm. From N-terminal peptide sequencing, the two peptides have been shown to come from regions of the myosin rod displaced by 195 residues. We have shown that either peptide alone can assemble to form the same aggregates. The 195 residue displacement of the Mr 13 000 peptides corresponds closely to the 196 residue repeat of charges along the myosin rod. This finding permits us to designate 195 residue segments of the myosin rod and to relate assembly characteristics directly to the similar 195 residue segments and 196 residue charge repeat. The most C-terminal 195 residue segment carries information for assembly into helical strands. The contiguous 195 residue segment, in major part, carries information for the unipolar assembly, characteristic of the assembly in each half of the myosin filament. The next contiguous 195 residue segment, in major part, carries information for bipolar assembly which is characteristic of the bare zone region of the filament; and for the transition from the bipolar bare zone to unipolar assembly. The effect of the eight C-terminal residues of the myosin rod on the assembly of the contiguous 195 residues has also been studied. The entire fragment of 195 + eight C-terminal residues assembled to form helical strands with an axial repeat of 30 nm. Successive deletion of charged residues changed the axial repeat of the helical strands suggesting that the charged residues at the C-terminus are involved in determining the pitch in the helical assembly of the contiguous 195 residues.