Daniel Safer

A structural change in the kinesin motor protein that drives motility

Kinesin motors power many motile processes by converting ATP energy into unidirectional motion along microtubules. The force-generating and enzymatic properties of conventional kinesin have been extensively studied; however, the structural basis of movement is unknown. Here we have detected and visualized a large conformational change of a ∼15-amino-acid region (the neck linker) in kinesin using electron paramagnetic resonance, fluorescence resonance energy transfer, pre-steady state kinetics and cryo-electron microscopy. This region becomes immobilized and extended towards the microtubule ‘plus’ end when kinesin binds microtubules and ATP, and reverts to a more mobile conformation when γ-phosphate is released after nucleotide hydrolysis. This conformational change explains both the direction of kinesin motion and processive movement by the kinesin dimer.

Myosin VI is an actin-based motor that moves backwards.

Myosins and kinesins are molecular motors that hydrolyse ATP to track along actin filaments and microtubules, respectively. Although the kinesin family includes motors that move towards either the plus or minus ends of microtubules, all characterized myosin motors move towards the barbed (+) end of actin filaments. Crystal structures of myosin II (refs 3,4,5,6) have shown that small movements within the myosin motor core are transmitted through the ‘converter domain’ to a ‘lever arm’ consisting of a light-chain-binding helix and associated light chains. The lever arm further amplifies the motions of the converter domain into large directed movements. Here we report that myosin VI, an unconventional myosin, moves towards the pointed (-) end of actin. We visualized the myosin VI construct bound to actin using cryo-electron microscopy and image analysis, and found that an ADP-mediated conformational change in the domain distal to the motor, a structure likely to be the effective lever arm, is in the opposite direction to that observed for other myosins. Thus, it appears that myosin VI achieves reverse-direction movement by rotating its lever arm in the opposite direction to conventional myosin lever arm movement.

MAP2 and tau bind longitudinally along the outer ridges of microtubule protofilaments

MAP2 and tau exhibit microtubule-stabilizing activities that are implicated in the development and maintenance of neuronal axons and dendrites. The proteins share a homologous COOH-terminal domain, composed of three or four microtubule binding repeats separated by inter-repeats (IRs). To investigate how MAP2 and tau stabilize microtubules, we calculated 3D maps of microtubules fully decorated with MAP2c or tau using cryo-EM and helical image analysis. Comparing these maps with an undecorated microtubule map revealed additional densities along protofilament ridges on the microtubule exterior, indicating that MAP2c and tau form an ordered structure when they bind microtubules. Localization of undecagold attached to the second IR of MAP2c showed that IRs also lie along the ridges, not between protofilaments. The densities attributable to the microtubule-associated proteins lie in close proximity to helices 11 and 12 and the COOH terminus of tubulin. Our data further suggest that the evolutionarily maintained differences observed in the repeat domain may be important for the specific targeting of different repeats to either α or β tubulin. These results provide strong evidence suggesting that MAP2c and tau stabilize microtubules by binding along individual protofilaments, possibly by bridging the tubulin interfaces.

Cargo binding induces dimerization of myosin VI

Although myosin VI has properties that would allow it to function optimally as a dimer, full-length myosin VI exists as a monomer in isolation. Based on the ability of myosin VI monomers to dimerize when held in close proximity, we postulated that cargo binding normally regulates dimerization of myosin VI. We tested this hypothesis by expressing a known dimeric cargo adaptor protein of myosin VI, optineurin, and the myosin VI-binding segment from a monomeric cargo adaptor protein, Dab2. In the presence of these adaptor proteins, full-length myosin VI has ATPase properties of a dimer, appears as a dimer in electron micrographs, and moves processively on actin filaments. The results support a model in which cargo binding exposes internal dimerization sequences within full-length myosin VI. Because, unexpectedly, a monomeric fragment of Dab2 triggers dimerization, it would appear that myosin VI is designed to function as a dimer in cells.

An electrophoretic procedure for detecting proteins that bind actin monomers

The electrophoretic mobility of fluorescently labeled G-actin in polyacrylamide gels under nondenaturing conditions is altered by the formation of complexes with actin-binding proteins. This effect offers a convenient method for detecting and quantitating such proteins in tissue fractions and for monitoring their purification. When followed by second-dimension electrophoresis in the presence of sodium dodecyl sulfate, the method also gives the apparent molecular weights of the actin-binding components and the stoichiometry of the complexes. The method has also been used to identify actin-binding fragments in digests of actin-binding proteins, to investigate the formation of multicomponent complexes, and to determine the calcium-sensitivity of complexes.

Myosin VI Dimerization Triggers an Unfolding of a Three-Helix Bundle in Order to Extend Its Reach

Myosin VI challenges the prevailing theory of how myosin motors move on actin: the lever arm hypothesis. While the reverse directionality and large powerstroke of myosin VI can be attributed to unusual properties of a subdomain of the motor (converter with a unique insert), these adaptations cannot account for the large step size on actin. Either the lever arm hypothesis needs modification, or myosin VI has some unique form of extension of its lever arm. We determined the structure of the region immediately distal to the lever arm of the motor and show that it is a three-helix bundle. Based on C-terminal truncations that display the normal range of step sizes on actin, CD, fluorescence studies, and a partial deletion of the bundle, we demonstrate that this bundle unfolds upon dimerization of two myosin VI monomers. This unconventional mechanism generates an extension of the lever arm of myosin VI.

Undecagold clusters for site-specific labeling of biological macromolecules: simplified preparation and model applications

We report simple and rapid procedures for the synthesis of a variety of stable, water-soluble undecagold cluster, and model applications of a thiol-reactive gold cluster for the specific labeling of cysteine residues in proteins.

Co-ordinate regulation of the cytoskeleton in 3T3 cells overexpressing thymosin-β4

In several cell types, short-term increases in the concentration of the G-actin-sequestering peptide thymosin-beta4 (Tbeta4) cause the disassembly of F-actin bundles. To determine the extent of cell adaptability to these reductions in F-actin, we overexpressed Tbeta4 in NIH 3T3 cells. In cell lines with Tbeta4 levels twice those of vector controls, G-actin increased approximately twofold as expected. However, F-actin did not decrease as in short-term experiments but rather also increased approximately twofold so that the G-F ratio remained constant. Surprisingly, the cytoskeletal proteins myosin IIA, alpha-actinin, and tropomyosin also increased nearly twofold. These increases were specific; DNA, total protein, lactic dehydrogenase, profilin, and actin depolymerizing factor levels were unchanged in the overexpressing cells. The Tbeta4 lines spread more fully and adhered to the dish more strongly than vector controls; this altered phenotype correlated with a twofold increase in talin and alpha5-integrin and a nearly threefold increase in vinculin. Focal adhesions, detected by indirect immunofluorescence with antivinculin, were increased in size over the controls. Northern blotting showed that mRNAs for both beta-actin and vinculin were increased twofold in the overexpressing lines. We conclude that 1) NIH 3T3 cells adapt to increased levels of G-actin sequestered by increased Tbeta4 by increasing their total actin so that the F-actin/G-actin ratio remains constant; 2) these cells coordinately increase several cytoskeletal and adhesion plaque proteins; and 3) at least for actin and vinculin, this regulation is at the transcriptional level. We therefore propose that the proteins of this multimember interacting complex making up the actin-based cytoskeleton, are coordinately regulated by factors that control the expression of several proteins. The mechanism may bear similarities to the control of synthesis of another multimember interacting complex, the myofibril of developing muscle cells.

β‐thymosins from marine invertebrates: Primary structure and interaction with actin

The beta-thymosins are distributed throughout the vertebrate phyla, and all known vertebrate beta-thymosins bind actin monomers. To determine whether beta-thymosin-like peptides function as actin-binding proteins in invertebrates, we fractionated perchloric acid extracts of the gonads of both the sea urchin, Arbacia punctulata, and the scallop, Argopecten irradians, and screened the fractions for proteins which could be crosslinked to actin. In each case a peptide was isolated which crosslinks to actin from both rabbit skeletal muscle and scallop cross-striated adductor muscle; both peptides were sequenced and each was found to consist of 40 amino acid residues, compared with 41-43 residues for the vertebrate beta-thymosins. The sequences of the scallop and sea urchin beta-thymosins are 80% identical to each other, 75% identical to residues 1-40 of thymosin beta4, and 72-80% identical to residues 1-40 of other vertebrate beta-thymosins. The sea urchin peptide was found to inhibit actin polymerization and nucleotide exchange. The affinity of the sea urchin peptide for rabbit muscle actin is apparently lower than that of thymosin beta4, since about twice the concentration of sea urchin peptide is required to give inhibition of actin polymerization or nucleotide exchange equivalent to thymosin beta4.

Axial packing in light meromyosin paracrystals

Abstract The positions of ends of molecules have been correlated with the striation pattern in negatively stained paracrystals of light meromyosin, and the pattern of deposition of C-protein on paracrystals has been examined both in negative stain and in section. The data show that in paracrystals of papain LMM ‡ , molecules may be related by overlaps of 16 or 44 nm; in paracrystals of chymotryptic LMM, molecules may overlap by multiples of 14 nm. The polarity by which overlapping molecules are related may be deduced for those molecules which bind C-protein. In paracrystals of papain LMM, molecules may overlap by 16 nm head-to-head or by 44 nm head-to-tail; in paracrystals of chymotryptic LMM, the head-to-head and head-to-tail overlaps are 14 and 42 nm. The binding of C-protein at 42 nm intervals to paracrystals whose staining pattern shows an undifferentiated 14 nm periodicity indicates that some feature of molecular packing must repeat at 42 nm intervals. The observation of C-protein bound at the edges of paracrystals suggests that the C-protein binding site is near one end of the LMM molecule.