Acan125 binding to the SH3 domain of acanthamoeba myosin-IC.

The domain organization of Acanthamoeba myosin-I, an oligomodular motor protein, includes a potentially important protein interaction module that is mostly uncharacterized. The Src homology 3, SH3, domain of myosin-I binds Acan125, a protein containing at least two consensus ligand binding domains: C-terminal SH3 binding motifs (PXXP) and N-terminal leucine-rich repeats. We report the first affinities determined for an SH3 domain of any myosin, namely, K(d) = 7 microM for a 21-residue synthetic peptide based on the PXXP domain sequence and K(d) = 0.15 microM for the PXXP domain included in the C-terminus of Acan125. These values are consistent with affinities reported for peptides and proteins that associate with SH3. By deletional analysis we show that only the PXXP domain is required for Acan125 to interact with the SH3 domain of Acanthamoeba myosin-IC (AmyoC(SH3)). The synthetic peptide described above at a concentration near the K(d) for SH3 binding blocked the interaction between native AmyoC and Acan125, mapping the interaction to the PXXP domain of Acan125 and the SH3 domain of myosin-I. These results are consistent with prototypical SH3 binding and suggest that a PXXP module is both necessary and sufficient to interact with an SH3 module of myosin-I.

The carboxy terminus of AFAP-110 modulates direct interactions with actin filaments and regulates its ability to alter actin filament integrity and induce lamellipodia formation.

The actin filament-associated protein AFAP-110 is an SH2/SH3 binding partner for Src. AFAP-110 contains several protein-binding motifs in its amino terminus and has been hypothesized to function as an adaptor molecule that could link signaling proteins to actin filaments. Recent studies using deletional mutagenesis demonstrated that AFAP-110 can alter actin filament integrity in SV40 transformed Cos-1 cells. Thus, AFAP-110 may be positioned to modulate the effects of Src upon actin filaments. In this report, we sought to determine whether (a) AFAP-110 could interact with actin filaments directly and (b) deletion mutants could affect actin filament integrity and cell shape in untransformed fibroblast cells. The data demonstrate that the carboxy terminus of AFAP-110 is both necessary and sufficient for actin filament association, in vivo and in vitro. Analysis of the carboxy terminus revealed a mean 40% similarity with other known actin-binding motifs, indicating a mechanism for binding to actin filaments. AFAP-110 can also induce lamellipodia formation. Contiguous with the alpha-helical, actin-binding motif is an alpha-helical, leucine zipper motif. Deletion of the leucine zipper motif (AFAP(Deltalzip)) followed by cellular expression enabled AFAP(Deltalzip) to alter actin filament integrity and cell shape in untransformed cells as evidenced by the induction of lamellipodia formation. We hypothesize that AFAP-110 may be an important signaling protein that can directly modulate changes in actin filament integrity and induce lamellipodia formation.

Organization and ligand binding properties of the tail of Acanthamoeba myosin-IA. Identification of an actin-binding site in the basic (tail homology-1) domain.

The Acanthamoeba myosin-IA heavy chain gene encodes a 134-kDa protein with a catalytic domain, three potential light chain binding sites, and a tail with separately folded tail homology (TH) -1, -2, and -3 domains. TH-1 is highly resistant to trypsin digestion despite consisting of 15% lysine and arginine. TH-2/3 is resistant to alpha-chymotrypsin digestion. The peptide link between TH-1 and TH-2/3 is cleaved by trypsin, alpha-chymotrypsin, and endo-AspN but not V8 protease. The CD spectra of TH-2/3 indicate predominantly random structure, turns, and beta-strands but no alpha-helix. The hydrodynamic properties of TH-2/3 (Stokes' radius of 3.0 nm, sedimentation coefficient of 1.8 S, and molecular mass of 21.6 kDa) indicate that these domains are as long as the whole myosin-I tail in reconstructions of electron micrographs. Furthermore, separately expressed and purified TH-1 binds with high affinity to TH-2/3. Thus we propose that TH-1 and TH-2/3 are arranged side by side in the myosin-IA tail. Separate TH-1, TH-2, and TH-2/3 each binds muscle actin filaments with high affinity. Salt inhibits TH-2/3 binding to muscle actin but not amoeba actin filaments. TH-1 enhances binding of TH-2/3 to muscle actin filaments at physiological salt concentration, indicating that TH-1 and TH-2/3 cooperate in actin binding. An intrinsic fluorescence assay shows that TH-2/3 also binds with high affinity to the protein Acan125 similar to the SH3 domain of myosin-IC. Phylogenetic analysis of SH3 sequences suggests that myosin-I acquired SH3 domain after the divergence of the genes for myosin-I isoforms.

The myosin-I-binding protein Acan125 binds the SH3 domain and belongs to the superfamily of leucine-rich repeat proteins.

The SH3 domains of src and other nonreceptor tyrosine kinases have been shown to associate with the motif PXXP, where P and X stand for proline and an unspecified amino acid, but a motif that binds to the SH3 domain of myosin has thus far not been characterized. We previously showed that the SH3 domain of Acanthamoeba myosin-IC interacts with the protein Acan125. We now report that the Acan125 protein sequence contains two tandem consensus PXXP motifs near the C terminus. To test for binding, we expressed a polypeptide, AD3p, which includes 344 residues of native C-terminal sequence and a mutant polypeptide, AD3delta977-994p, which lacks the sequence RPKPVPPPRGAKPAPPPR containing both PXXP motifs. The SH3 domain of Acanthamoeba myosin-IC bound AD3p and not AD3delta977-994p, showing that the PXXP motifs are required for SH3 binding. The sequence of Acan125 is related overall to a protein of unknown function coded by Caenorhabditis elegans gene K07G5.1. The K07G5.1 gene product contains a proline-rich segment similar to the SH3 binding motif found in Acan125. The aligned sequences show considerable conservation of leucines and other hydrophobic residues, including the spacing of these residues, which matches a motif for leucine-rich repeats (LRRs). LRR domains have been demonstrated to be sites for ligand binding. Having an LRR domain and an SH3-binding domain, Acan125 and the C. elegans homologue define a novel family of bifunctional binding proteins.

Identification of Acan125 as a myosin-I-binding protein present with myosin-I on cellular organelles of Acanthamoeba.

We have discovered the first protein to bind to a non-filamentous myosin, aside from actin. This protein, Acan125, is a 125-kDa protein from Acanthamoeba that associates with the SH3 domain of Acanthamoeba myosin-IC and not the SH3 domain of human fodrin. Antibodies raised against Acan125 recognize a single protein of 125 kDa from a whole cell lysate of Acanthamoeba; antibodies to myosin-I (M1.7 and M1.8) do not recognize Acan125 on the same blot. Double labeling of Acanthamoeba show Acan125 and myosin-I to be present on the same intracellular organelle, most likely amoebastomes. Immunoprecipitation with either anti-myosin-I or anti-Acan125 antibodies coprecipitates both Acan125 and myosin-I from a lysate of Acanthamoeba, demonstrating that Acan125 interacts with native myosin-I.

Vanadium (IV) inhibits calmodulin-stimulated skeletal muscle myosin light chain kinase activity.

Vanadium, believed to be an essential trace metal, exhibits numerous biological effects. Using electron spin resonance spectroscopy, we have demonstrated that vanadyl, vanadium (IV), the predominant intracellular form of vanadate (vanadium V), binds to calmodulin in the presence of physiological concentrations of magnesium, extending earlier work which showed competitive binding of vanadyl and calcium to calmodulin. In the presence of a magnesium-containing buffer, vanadyl does not lead to calmodulin activation of the calmodulin-dependent enzyme, rabbit skeletal muscle myosin light chain kinase; in the presence of calcium, vanadyl is a potent inhibitor of the calmodulin-activated form of the kinase. Thus, vanadyl can potentially interfere with some of the intracellular actions of calcium, presumably via binding to calmodulin. This observation deserves consideration in view of the potential clinical application of vanadium treatment to mimick insulin action and lower blood glucose.

Phospholipid membrane-associated brush border myosin-I activity.

Brush border myosin-I (BBMI) is associated with the membrane of intestinal epithelial cells where it probably plays a structural role. BBMI also has been identified on Golgi-derived vesicles in intestinal epithelial cells where it may translocate vesicles into the brush border. However, the mechanochemical activity of BBMI bound to a phospholipid membrane has not been described. This study reports that phospholipid membrane-associated BBMI displays ATPase activity when bound to phospholipids, but does not move actin filaments when associated with a phospholipid bilayer. BBMI does not bind significantly to brush border membrane lipids, which contain about 16% phosphatidylserine (PS), in either a pelleting or planar membrane assay. Similarly, planar membranes containing 20% PS do not bind a significant amount of BBMI. Increasing the concentration of PS to 40% does result in the binding of BBMI to both vesicles and planar membranes. This binding is enhanced with increased Ca2+ concentrations. BBMI retains its ATPase activity when bound to phospholipid vesicles containing 40% PS. However, BBMI attached to a phospholipid bilayer surface does not move actin filaments, even though the amount of BBMI bound to the lipid surface, as reflected by the number of actin filaments associated with bilayer-bound BBMI, is sufficient to observe motility in control experiments. When membrane fluidity is reduced by adding cholesterol to the membrane lipids containing 40% PS, BBMI still binds to the membrane, but again no actin filament motility is observed. The lack of binding by BBMI to brush border membrane lipids and the absence of membrane-associated BBMI mechanical activity suggest that factors in addition to membrane lipids are necessary for membrane-associated myosin-I motility.

Direct visualization by electron microscopy of the weakly bound intermediates in the actomyosin adenosine triphosphatase cycle.

We used a novel stopped-flow/rapid-freezing machine to prepare the transient intermediates in the actin-myosin adenosine triphosphatase (ATPase) cycle for direct observation by electron microscopy. We focused on the low affinity complexes of myosin-adenosine triphosphate (ATP) and myosin-adenosine diphosphate (ADP)-Pi with actin filaments since the transition from these states to the high affinity actin-myosin-ADP and actin-myosin states is postulated to generate the molecular motion that drives muscle contraction and other types of cellular movements. After rapid freezing and metal replication of mixtures of myosin subfragment-1, actin filaments, and ATP, the structure of the weakly bound intermediates is indistinguishable from nucleotide-free rigor complexes. In particular, the average angle of attachment of the myosin head to the actin filament is approximately 40 degrees in both cases. At all stages in the ATPase cycle, the configuration of most of the myosin heads bound to actin filaments is similar, and the part of the myosin head preserved in freeze-fracture replicas does not tilt by more than a few degrees during the transition from the low affinity to high affinity states. In contrast, myosin heads chemically cross-linked to actin filaments differ in their attachment angles from ordered at 40 degrees without ATP to nearly random in the presence of ATP when viewed by negative staining (Craig, R., L.E. Greene, and E. Eisenberg. 1985. Proc. Natl. Acad. Sci. USA. 82:3247-3251, and confirmed here), freezing in vitreous ice (Applegate, D., and P. Flicker. 1987. J. Biol. Chem. 262:6856-6863), and in replicas of rapidly frozen samples. This suggests that many of the cross-linked heads in these preparations are dissociated from but tethered to the actin filaments in the presence of ATP. These observations suggest that the molecular motion produced by myosin and actin takes place with the myosin head at a point some distance from the actin binding site or does not involve a large change in the shape of the myosin head.

Myosin-I moves actin filaments on a phospholipid substrate: implications for membrane targeting.

Acanthamoeba myosin-I bound to substrates of nitrocellulose or planar lipid membranes on glass moved actin filaments at an average velocity of 0.2 micron/s. This movement required ATP and phosphorylation of the myosin-I heavy chain. We prepared planar lipid membranes on a glass support by passive fusion of lipid vesicles (Brian, A. A., and H. M. McConnell. 1984. Proc. Natl. Acad. Sci. USA. 81:6159-6163) composed of phosphatidylcholine and containing 0-40% phosphatidylserine. The mass of lipid that bound to the glass was the same for membranes of 2 and 20% phosphatidylserine in phosphatidylcholine and was sufficient to form a single bilayer. Myosin-I moved actin filaments on planar membranes of 5-40% but not 0-2% phosphatidylserine. At the low concentrations of phosphatidylserine, actin filaments tended to detach suggesting that less myosin-I was bound. We used the cooperative activation of Acanthamoeba myosin-I ATPase by low concentrations of actin to assess the association of phospholipids with myosin-I. Under conditions where activity depends on the binding of actin to the tail of myosin-I (Albanesi, J. P., H. Fujisaki, and E. D. Korn. 1985. J. Biol. Chem. 260:11174-11179), phospholipid vesicles with 5-40% phosphatidylserine inhibited ATPase activity. The motility and ATPase results demonstrate a specific interaction of the tail of myosin-I with physiological concentrations of phosphatidylserine. This interaction is sufficient to support motility and may provide a mechanism to target myosin-I to biological membranes.

Functional implications of the unusual amino acid sequence of the regulatory light chain of Acanthamoeba castellanii myosin-II.

We have determined by protein chemistry methods the amino acid sequence of light chain 2 from Acanthamoeba castellanii myosin-II (ALC2). This is the first reported sequence for any protozoan myosin light chain. ALC2 consists of 154 amino acid residues, including a single residue of His and two residues each of Pro and Tyr, and lacks Cys and Trp. The N-terminus is blocked, and if an N-terminal acetyl group is assumed. ALC2 has a calculated molecular weight of 17,657. ALC2 is an acidic protein, with a calculated net charge of -7 at pH 7. The sequence of ALC2 is most similar to those of the calmodulins (identity approximately 35%), followed by myosin regulatory light chains. ALC2 appears to lack the potential N-terminal phosphorylation site and single Ca(2+)-binding site in region I which are characteristic of most myosin regulatory light chains. Instead, ALC2, unlike any other myosin light chain characterized to date, may have a functional Ca(2+)-binding site only in region II, suggesting a novel role of ALC2 in the Ca2+ regulation of the activity of Acanthamoeba myosin-II.

Characterization of actin filament severing by actophorin from Acanthamoeba castellanii.

Actophorin is an abundant 15-kD actinbinding protein from Acanthamoeba that is thought to form a nonpolymerizable complex with actin monomers and also to reduce the viscosity of polymerized actin by severing filaments (Cooper et al., 1986. J. Biol. Chem. 261:477-485). Homologous proteins have been identified in sea urchin, chicken, and mammalian tissues. Chemical crosslinking produces a 1:1 covalent complex of actin and actophorin. Actophorin and profilin compete for crosslinking to actin monomers. The influence of actophorin on the steady-state actin polymer concentration gave a Kd of 0.2 microM for the complex of actophorin with actin monomers. Several new lines of evidence, including assays for actin filament ends by elongation rate and depolymerization rate, show that actophorin severs actin filaments both at steady state and during spontaneous polymerization. This is confirmed by direct observation in the light microscope and by showing that the effects of actophorin on the low shear viscosity of polymerized actin cannot be explained by monomer sequestration. The severing activity of actophorin is strongly inhibited by stoichiometric concentrations of phalloidin or millimolar concentrations of inorganic phosphate.

Fluorescent adducts of wheat calmodulin implicate the amino-terminal region in the activation of skeletal muscle myosin light chain kinase.

Considerable attention is being directed toward defining a binding site in the central region of calmodulin that forms a high affinity interaction with certain enzymes and amphiphilic peptides. However, other regions of calmodulin are also known to be involved in the activation of enzymes such as myosin light chain kinase, regions which may not be directly involved in the binding of small peptides, e.g. mastoparan X. We investigated the properties of wheat calmodulin fluorescent derivatives, which were modified chemically in the first calcium binding site at Cys-27, in the activation of rabbit fast skeletal muscle myosin light chain kinase. Unmodified wheat calmodulin stimulated myosin light chain kinase to a greater maximal velocity than wheat calmodulin that was modified at Cys-27 by any of four fluorescent compounds, IAANS (2-[4'-iodoacetamidoanilino]naphthalene-6-sulfonic acid), 5-[2'-[[iodoacetyl]amino]ethyl]aminonaphthalene]-1-sulfonic acid, 5-iodoacetamidofluorescein, and 7-diethylamino-3-[4'-maleimidylphenyl]-4-methylcoumarin; the midpoints for activation of myosin light chain kinase were not significantly different for unmodified wheat calmodulin and three of the four wheat calmodulin derivatives. Myosin light chain kinase, but not mastoparan X, enhanced the fluorescence emission intensity of wheat calmodulin-IAANS. Mastoparan X reversed, in a dose-dependent manner, the changes in fluorescence intensity of a preformed complex of myosin light chain kinase and wheat calmodulin-IANNS. Thus, we propose that the region vicinal to Cys-27 participates in the activation but not the high affinity association of myosin light chain kinase. Lastly, a comparison of mammalian and plant calmodulin showed that the Vmax for the stimulation of myosin light chain kinase was 1.6-fold greater for bovine than wheat calmodulin. The difference between the two calmodulins was more pronounced at lower Ca2+ because less Ca2+ was needed to saturate the kinase rate when stimulated by bovine calmodulin.

An enzymatically active cross-linked complex of calmodulin and rabbit skeletal muscle myosin light chain kinase.

The interaction between bovine testes calmodulin and rabbit fast skeletal muscle myosin light chain kinase was investigated with the zero-length cross-linking reagent N,N'-dicyclohexylcarbodiimide. A cross-linked product of 110 kDa was produced only in the presence of Ca2+. The reaction mixture was separated on diethylaminoethyl cellulose, and a fraction containing the cross-linked complex of calmodulin and myosin light chain kinase was found to have an elevated kinase activity in the absence of Ca2+, which constituted approximately 50% of the maximally stimulated kinase activity of control, and additional kinase activity in the presence of Ca2+, which constituted the remaining 50% of control activity. Calmodulin added exogenously to the cross-linked complex had no effect on the measured Ca2+ dependence or the maximal extent of kinase activity, which is consistent with the cross-linking of calmodulin in close proximity to a regulatory region of myosin light chain kinase. Moreover, the results are consistent with a mechanism whereby the association of calmodulin is sufficient to stimulate kinase activity and the binding of Ca2+ to bound calmodulin increases catalytic efficiency.

Calcium binding and fluorescence measurements of dansylaziridine-labelled troponin C in reconstituted thin filaments.

The direct binding of Ca2+ to reconstituted thin filaments containing troponin C and the 5-dimethylaminonaphthalene-1-sulphonylaziridine (DANZ) fluorescent analogue of troponin C (TnCDANZ) was measured (25 degrees C) at three Mg2+ concentrations. Biphasic Scatchard plots were found for all binding curves reflecting the binding of Ca2+ to high- and low-affinity sites of troponin. The binding of Ca2+ to the high-affinity sites had a greater sensitivity to Mg2+ (KMg = 1 x 10(4)M-1) than the low-affinity sites (KMg = 1.2 x 10(3)M-1). The fluorescence change of thin filaments reconstituted with TnCDANZ was titrated with Ca2+ in the same solutions used for binding assays. The Ca2+-dependent fluorescence change had nearly the same sensitivity to Mg2+ (KMg = 9.4 x 10(2)M-1) as did Ca2+ binding to the low-affinity sites. The Ca2+ concentration at the midpoint of the fluorescence change was about 0.3 log units less than at the midpoint for Ca2+ binding to the low-affinity sites. A similar relationship between the fluorescence change and Ca2+ binding to the low-affinity sites of isolated TnCDANZ was measured (4 degrees C). From these results the binding of Ca2+ to either low-affinity site is concluded to produce the fluorescence change. In comparison with the low-affinity sites of isolated troponin and troponin-tropomyosin complex, the low-affinity sites of reconstituted thin filaments were consistently lower in Ca2+ affinity.

Fast skeletal muscle skinned fibers and myofibrils reconstituted with N-terminal fluorescent analogues of troponin C.

Glycerinated rabbit fast skeletal muscle fibers were chemically skinned with 1% Brij 35 and partially depleted of endogenous troponin C subunit (TnC) by exposure of the fibers to EDTA (Zot, H. G., and Potter, J. D. (1982) J. Biol. Chem. 257, 7678-7683). The TnC-depleted fibers exhibited a decrease in maximal tension that was mostly restored by readdition of TnC or by the addition of the fluorescent 5-dimethylaminonaphthalene-1-sulfonyl aziridine analogue, TnCDanz. TnCDanz is known to undergo an increase in fluorescence intensity when Ca2+ binds to the two low affinity Ca2+-specific regulatory sites of TnC. Steady-state fractional fluorescence and tension changes were measured simultaneously as a function of Ca2+. The Ca2+ sensitivity of the fluorescence curve was about 0.6 log unit greater than the tension curve. This difference in sensitivity could be explained if separate conformational states of TnC, brought about by Ca2+ binding to the Ca2+-specific sites, produce the fluorescence and tension changes. TnC-depleted fibers were also reconstituted with the fluorescent 2-[(4'-iodoacetamido)analino]naphthalene-6-sulfonic acid analogue, cardiac TnCIaans, which undergoes an increase in fluorescence intensity when Ca2+ binds to the single Ca2+- specific regulatory site. The steady-state fractional fluorescence and tension curves for fibers reconstituted with cardiac TnCIaans had nearly the same Ca2+ sensitivity. The steady-state fractional fluorescence of myofibrils reconstituted with TnCDanz was found to have a greater sensitivity to Ca2+ than the simultaneously measured ATPase. In all cases paired fractional fluorescence and activity curves tended to have parallel dependence on Ca2+. These procedures make it possible to study the Ca2+ binding properties of the Ca2+- specific sites in intact myofibrils and skinned fibers; the results presented suggest that the Ca2+ affinity of the Ca2+-specific sites of troponin are reduced in the thin filament compared to that of troponin in solution.

Evidence that the Sr2+ activation properties of cardiac troponin C are altered when substituted into skinned skeletal muscle fibers.

Troponin C (TnC) was extracted from skinned skeletal muscle fibers by a method similar to that used previously on myofibrils (Zot, H.G., and Potter, J.D. (1982) J. Biol. Chem. 257, 7678-7683) and replaced with either skeletal (fast-twitch) or cardiac TnC. The relationship between isometric tension and Sr2+ concentration remained essentially the same before removal and after replacement with skeletal or cardiac TnC. Therefore, the origin of the TnC made no difference in the Sr2+ activation properties of the skinned fiber. In contrast, the activation of skinned cardiac fibers is approximately an order of magnitude more sensitive to Sr2+ than skinned skeletal fibers. These results show that the affinity of cardiac TnC for Sr2+ is altered when substituted into skinned skeletal muscle fibers through protein-protein interactions.

Purification of actin from cardiac muscle.

Actin from cardiac acetone and ether powders is compared to actin from skeletal acetone powder using a modification of an established extraction procedure. The yield of actin from cardiac ether powder is nearly the same as the yield from skeletal acetone powder whereas significantly less actin is obtained from cardiac acetone powder. Sodium dodecyl sulfate polyacrylamide gel electrophoresis shows the actins from each of the sources to be virtually identical in terms of purity and mobility. Molecular sieve chromatography of G-actin demonstrates cardiac actin from ether powder to have identical polymerization and mobility properties as skeletal actin from acetone powder. A simplified procedure, developed for highly purified actin from muscle powder and prepared in a single day is presented. The storage of F-actin at -80 degrees C is also discussed.