Horst Hinssen

Microinjection of actin-binding proteins and actin antibodies demonstrates involvement of nuclear actin in transcription of lampbrush chromosomes

Nuclei of amphibian oocytes contain large amounts of actin, mostly in unpolymerized or short-polymer form. When antibodies to actin or actin-binding proteins (fragmin and the actin modulator from mammalian smooth muscle) are injected into nuclei of living oocytes of Pleurodeles waltlii, transcription of the lampbrush chromosomes, but not of the rRNA genes, is inhibited. When transcription is repressed by drugs or RNA is digested by microinjection of RNAase into oocyte nuclei, an extensive meshwork of actin filament bundles is seen in association with the isolated lampbrush chromosomes. These observations indicate a close relationship between the state of nuclear actin and transcriptional activity and suggest that nuclear actin may be involved in transcriptional events concerning protein-coding genes.

Damped elastic recoil of the titin spring in myofibrils of human myocardium

The giant protein titin functions as a molecular spring in muscle and is responsible for most of the passive tension of myocardium. Because the titin spring is extended during diastolic stretch, it will recoil elastically during systole and potentially may influence the overall shortening behavior of cardiac muscle. Here, titin elastic recoil was quantified in single human heart myofibrils by using a high-speed charge-coupled device-line camera and a nanonewtonrange force sensor. Application of a slack-test protocol revealed that the passive shortening velocity (Vp) of nonactivated cardiomyofibrils depends on: (i) initial sarcomere length, (ii) release-step amplitude, and (iii) temperature. Selective digestion of titin, with low doses of trypsin, decelerated myofibrillar passive recoil and eventually stopped it. Selective extraction of actin filaments with a Ca2+-independent gelsolin fragment greatly reduced the dependency of Vp on release-step size and temperature. These results are explained by the presence of viscous forces opposing myofibrillar passive recoil that are caused mainly by weak actin–titin interactions. Thus, Vp is determined by two distinct factors: titin elastic recoil and internal viscous drag forces. The recoil could be modeled as that of a damped entropic spring consisting of independent worm-like chains. The functional importance of myofibrillar elastic recoil was addressed by comparing instantaneous Vp to unloaded shortening velocity, which was measured in demembranated, fully Ca2+-activated, human cardiac fibers. Titin-driven passive recoil was much faster than active unloaded shortening velocity in early phases of isotonic contraction. Damped myofibrillar elastic recoil could help accelerate active contraction speed of human myocardium during early systolic shortening.

The vasodilator-stimulated phosphoprotein promotes actin polymerisation through direct binding to monomeric actin

The vasodilator‐stimulated phosphoprotein (VASP) functions as a cellular regulator of actin dynamics. VASP may initialise actin polymerisation, suggesting a direct interaction with monomeric actin. The present study demonstrates that VASP directly binds to actin monomers and that complex formation depends on a conserved four amino acid motif in the EVH2 domain. Point mutations within this motif drastically weaken VASP/G‐actin interactions, thereby abolishing any actin‐nucleating activity of VASP. Additionally, actin nucleation was found to depend on VASP oligomerisation since VASP monomers fail to induce the formation of actin filaments. Phosphorylation negatively affects VASP/G‐actin interactions preventing VASP‐induced actin filament formation.

Kettin, a major source of myofibrillar stiffness in Drosophila indirect flight muscle

Kettin is a high molecular mass protein of insect muscle that in the sarcomeres binds to actin and α-actinin. To investigate kettins functional role, we combined immunolabeling experiments with mechanical and biochemical studies on indirect flight muscle (IFM) myofibrils of Drosophila melanogaster. Micrographs of stretched IFM sarcomeres labeled with kettin antibodies revealed staining of the Z-disc periphery. After extraction of the kettin-associated actin, the A-band edges were also stained. In contrast, the staining pattern of projectin, another IFM–I-band protein, was not altered by actin removal. Force measurements were performed on single IFM myofibrils to establish the passive length-tension relationship and record passive stiffness. Stiffness decreased within seconds during gelsolin incubation and to a similar degree upon kettin digestion with μ-calpain. Immunoblotting demonstrated the presence of kettin isoforms in normal Drosophila IFM myofibrils and in myofibrils from an actin-null mutant. Dotblot analysis revealed binding of COOH-terminal kettin domains to myosin. We conclude that kettin is attached not only to actin but also to the end of the thick filament. Kettin along with projectin may constitute the elastic filament system of insect IFM and determine the muscles high stiffness necessary for stretch activation. Possibly, the two proteins modulate myofibrillar stiffness by expressing different size isoforms.

A Ca2+-dependent actin modulator from vertebrate smooth muscle

A protein of M r ≈ 85 000 has been isolated and purified from pig stomach smooth muscle that modulates the polymer state of actin in a Ca2+‐dependent manner. When added either to preformed F‐actin filaments or to G‐actin, prior to polymerisation, the modulator induces the formation of shorter filaments. The average filament length in the presence of the modulator is directly dependent on its molar ratio to actin indicating a stoichiometric rather than a catalytic type of interaction. When mixed with G‐actin the modulator forms a stable complex with two actin monomers; this complex is presumed to act as a potent nucleus for actin polymerisation. The dynamics of the interaction with F‐actin suggests a direct severing of actin filaments by the modulator via a binding to intrafilamentous actins.

The Ca(2+)-induced conformational change of gelsolin is located in the carboxyl-terminal half of the molecule.

We have purified the two functionally distinct domains of gelsolin, a Ca(2+)-dependent actin binding protein, by proteolytic cleavage and characterized their size and shape in solution by dynamic light scattering. In the absence of calcium we obtained the same translational diffusion coefficient for both fragments which are of approximately equal molecular mass. The frictional ratio fo/fexp (1.33-1.39) is similar to the value as obtained for intact gelsolin (1.37) in aqueous solution (Patkowski, A., J. Seils, H. Hinssen, and T. Dorfmüller. 1990. Biopolymers. 30:427-435), indicating a similar molecular shape for the native protein as well as for the two subdomains. Upon addition of Ca2+ the translational diffusion coefficient of the carboxyl-terminal half decreased by almost 10%, while there was no change observed for the amino terminus. This result indicates that the ligand-induced conformational change as seen for intact gelsolin is probably located on the carboxyl-terminal domain of the protein. Since gelsolin has binding sites in both domains, and the isolated amino terminus binds and severs actin in a calcium-independent manner, our results suggests that the structural transition in the carboxyl-terminal part of intact gelsolin also affects the actin binding properties of the amino-terminal half.

CONFORMATIONAL CHANGES IN ACTIN INDUCED BY ITS INTERACTION WITH GELSOLIN

Actin cleaved by the protease from Escherichia coli A2 strain between Gly42 and Val43 (ECP-actin) is no longer polymerizable when it contains Ca2+ as a tightly bound cation, but polymerizes when Mg2+ is bound. We have investigated the interactions of gelsolin with this actin with regard to conformational changes in the actin molecule induced by the binding of gelsolin. ECP-(Ca)actin interacts with gelsolin in a manner similar to that in which it reacts with intact actin, and forms a stoichiometric 2:1 complex. Despite the nonpolymerizability of ECP-(Ca)actin, this complex can act as a nucleus for the polymerization of intact actin, thus indicating that upon interaction with gelsolin, ECP-(Ca)actin undergoes a conformational change that enables its interaction with another actin monomer. By gel filtration and fluorometry it was shown that the binding of at least one of the ECP-cleaved actins to gelsolin is considerably weaker than of intact actin, suggesting that conformational changes in subdomain 2 of actin monomer may directly or allosterically affect actin-gelsolin interactions. On the other hand, interaction with gelsolin changes the conformation of actin within the DNase I-binding loop, as indicated by inhibition of limited proteolysis of actin by ECP and subtilisin. Cross-linking experiments with gelsolin-nucleated actin filaments using N,N-phenylene-bismaleimide (which cross-links adjacent actin monomers between Cys374 and Lys191) reveal that gelsolin causes a significant increase in the yield of the 115-kDa cross-linking product, confirming the evidence that gelsolin stabilizes or changes the conformation of the C-terminal region of the actin molecule, and these changes are propagated from the capped end along the filament. These results allow us to conclude that nucleation of actin polymerization by gelsolin is promoted by conformational changes within subdomain 2 and at the C-terminus of the actin monomer.

Nebulin is a thin filament protein of the cardiac muscle of the agnathans.

Nebulin is an integral protein of skeletal muscle thin filaments and probably acts as a ruler for the thin filament length. Cardiac muscles of higher vertebrates have been shown earlier to lack nebulin. Instead in human and chicken cardiac muscle the much smaller protein nebulette replaces nebulin. Since nebulette is confined to the Z-disc region of the sarcomere and does not span the whole thin filament length, it must have functions significantly different from those assumed for nebulin. We have investigated nebulin in skeletal and cardiac muscles of the agnathans (lamprey, hagfish), elasmobranchs (shark), chondrosts (sturgeon) and teleosts (trout, eel) by SDS-PAGE and immunodetection methods. Among these, lamprey and hagfish cardiac muscles are unique in that both contain full-length nebulin identical in molecular mass to the nebulin of the respective body muscle. Using immunofluorescence microscopy, lamprey cardiac nebulin was localised in the I-band of the sarcomere, the same as for nebulin in skeletal muscle. In contrast to this, all gnathostome species investigated lacked nebulin in cardiac muscles, while it was present in the respective skeletal muscles. This clearly shows that nebulin is not exclusively present in skeletal muscles of chordates. The findings also demonstrate a rare case of dramatic size reduction of a protein during evolution.

Ca-dependent regulation of Na+-selective channels via actin cytoskeleton modification in leukemia cells

With the use of the patch‐clamp technique, physiological mechanisms of Na+ channel regulation involving submembranous actin rearrangements were examined in human myeloid leukemia K562 cells. We found that the actin‐severing protein gelsolin applied to cytoplasmic surface of membrane fragments at a high level of [Ca2+]i (1 μM) increased drastically the activity of Na‐selective channels of 12 pS unitary conductance. In the experiments on intact cells, the elevation of [Ca2+]i using the ionophore 4Br‐A23187 also resulted in Na+ channel activation. Addition of actin to the cytoplasmic surface of membrane patches reduced this activity to background level, likely due to actin polymerization. Our data imply that Ca‐dependent modulations of the actin cytoskeleton may represent one of the general mechanisms of channel regulation and cell signalling.

Sodium Channel Activity in Leukemia Cells Is Directly Controlled by Actin Polymerization

The actin cytoskeleton has been shown to be involved in the regulation of sodium-selective channels in non-excitable cells. However, the molecular mechanisms underlying the changes in channel function remain to be defined. In the present work, inside-out patch experiments were employed to elucidate the role of submembranous actin dynamics in the control of sodium channels in human myeloid leukemia K562 cells. We found that the application of cytochalasin D to the cytoplasmic surface of membrane fragments resulted in activation of non-voltage-gated sodium channels of 12 picosiemens conductance. Similar effects could be evoked by addition of the actin-severing protein gelsolin to the bath cytosol-like solution containing 1 μm[Ca2+] i . The sodium channel activity induced by disassembly of submembranous microfilaments with cytochalasin D or gelsolin could be abolished by intact actin added to the bath cytosol-like solution in the presence of 1 mmMgCl2 to induce actin polymerization. In the absence of MgCl2, addition of intact actin did not abolish the channel activity. Moreover, the sodium currents were unaffected by heat-inactivated actin or by actin whose polymerizability was strongly reduced by cleavage with specific Escherichia coli A2 protease ECP32. Thus, the inhibitory effect of actin on channel activity was observed only under conditions promoting rapid polymerization. Taken together, our data show that sodium channels are directly controlled by dynamic assembly and disassembly of submembranous F-actin.