Purification from Dictyostelium discoideum of a low-molecular-weight myosin that resembles myosin I from Acanthamoeba castellanii

Discovery of the first unconventional myosin: Acanthamoeba myosin-I

Having characterized actin from Acanthamoeba castellanii (Weihing and Korn, Biochemistry, 1971, 10, 590-600) and knowing that myosin had been isolated from the slime mold Physarum (Hatano and Tazawa, Biochim. Biophys. Acta, 1968, 154, 507-519; Adelman and Taylor, Biochemistry, 1969, 8, 4976-4988), we set out in 1969 to find myosin in Acanthamoeba. We used K-EDTA-ATPase activity to assay myosin, because it is a unique feature of muscle myosins. After slightly less than 3 years, we purified a K-EDTA ATPase that interacted with actin. Actin filaments stimulated the Mg-ATPase activity of the crude enzyme, but this was lost with further purification. Recombining fractions from the column where this activity was lost revealed a "cofactor" that allowed actin filaments to stimulate the Mg-ATPase of the purified enzyme. The small size of the heavy chain and physical properties of the purified myosin were unprecedented, so many were skeptical, assuming that our myosin was a proteolytic fragment of a larger myosin similar to muscle or Physarum myosin. Subsequently our laboratories confirmed that Acanthamoeba myosin-I is a novel unconventional myosin that interacts with membrane lipids (Adams and Pollard, Nature, 1989, 340 (6234), 565-568) and that the cofactor is a myosin heavy chain kinase (Maruta and Korn, J. Biol. Chem., 1977, 252, 8329-8332). Phylogenetic analysis (Odronitz and Kollmar, Genome Biology, 2007, 8, R196) later established that class I myosin was the first myosin to appear during the evolution of eukaryotes.

The model organism Dictyostelium discoideum

Much of our knowledge of molecular cellular functions is based on studies with a few number of model organisms that were established during the last 50 years. The social amoeba Dictyostelium discoideum is one such model, and has been particularly useful for the study of cell motility, chemotaxis, phagocytosis, endocytic vesicle traffic, cell adhesion, pattern formation, caspase-independent cell death, and, more recently, autophagy and social evolution. As nonmammalian model of human diseases D. discoideum is a newcomer, yet it has proven to be a powerful genetic and cellular model for investigating host-pathogen interactions and microbial infections, for mitochondrial diseases, and for pharmacogenetic studies. The D. discoideum genome harbors several homologs of human genes responsible for a variety of diseases, -including Chediak-Higashi syndrome, lissencephaly, mucolipidosis, Huntington disease, IBMPFD, and Shwachman-Diamond syndrome. A few genes have already been studied, providing new insights on the mechanism of action of the encoded proteins and in some cases on the defect underlying the disease. The opportunities offered by the organism and its place among the nonmammalian models for human diseases will be discussed.

Leveraging the membrane - cytoskeleton interface with myosin-1

Class 1 myosins are small motor proteins with the ability to simultaneously bind to actin filaments and cellular membranes. Given their ability to generate mechanical force, and their high prevalence in many cell types, these molecules are well positioned to carry out several important biological functions at the interface of membrane and the actin cytoskeleton. Indeed, recent studies implicate these motors in endocytosis, exocytosis, release of extracellular vesicles, and the regulation of tension between membrane and the cytoskeleton. Many class 1 myosins also exhibit a load-dependent mechano-chemical cycle that enables them to maintain tension for long periods of time without hydrolyzing ATP. These properties put myosins-1 in a unique position to regulate dynamic membrane-cytoskeleton interactions and respond to physical forces during these events.

Isolation, characterization, and bioinformatic analysis of calmodulin-binding protein cmbB reveals a novel tandem IP22 repeat common to many Dictyostelium and Mimivirus proteins

A novel calmodulin-binding protein cmbB from Dictyostelium discoideum is encoded in a single gene. Northern analysis reveals two cmbB transcripts first detectable at 4 h during multicellular development. Western blotting detects an approximately 46.6 kDa protein. Sequence analysis and calmodulin-agarose binding studies identified a "classic" calcium-dependent calmodulin-binding domain (179IPKSLRSLFLGKGYNQPLEF198) but structural analyses suggest binding may not involve classic alpha-helical calmodulin-binding. The cmbB protein is comprised of tandem repeats of a newly identified IP22 motif ([I,L]Pxxhxxhxhxxxhxxxhxxxx; where h = any hydrophobic amino acid) that is highly conserved and a more precise representation of the FNIP repeat. At least eight Acanthamoeba polyphaga Mimivirus proteins and over 100 Dictyostelium proteins contain tandem arrays of the IP22 motif and its variants. cmbB also shares structural homology to YopM, from the plague bacterium Yersenia pestis.

Myosins and cell dynamics in cellular slime molds

Myosin is a mechanochemical transducer and serves as a motor for various motile activities such as cell migration, cytokinesis, maintenance of cell shape, phagocytosis, and morphogenesis. Nonmuscle myosin in vivo does not either stay static at specific subcellular regions or construct highly organized structures, such as sarcomere in skeletal muscle cells. The cellular slime mold Dictyostelium discoideum is an ideal "model organism" for the investigation of cell movement and cytokinesis. The advantages of this organism prompted researchers to carry out pioneering cell biological, biochemical, and molecular genetic studies on myosin II, which resulted in elucidation of many fundamental features of function and regulation of this most abundant molecular motor. Furthermore, recent molecular biological research has revealed that many unconventional myosins play various functions in vivo. In this article, how myosins are organized and regulated in a dynamic manner in Dictyostelium cells is reviewed and discussed.

Detection of calmodulin-binding proteins and calmodulin-dependent phosphorylation linked to calmodulin-dependent chemotaxis to folic and cAMP in Dictyostelium

Calmodulin (CaM) antagonists, trifluoperazine (TFP) or calmidazolium (R24571), dose-dependently inhibited cAMP and folic acid (FA) chemotaxis in Dictyostelium. Developing, starved, and refed cells were compared to determine if certain CaM-binding proteins (CaMBPs) and CaM-dependent phosphorylation events could be identified as potential downstream effectors. Recombinant CaM ([35S]VU-1-CaM) gel overlays coupled with cell fractionation revealed at least three dozen Ca(2+)-dependent and around 12 Ca(2+)-independent CaMBPs in Dictyostelium. The CaMBPs associated with early development were also found in experimentally starved cells (cAMP chemotaxis), but were different for the CaMBP population linked to growth-phase cells (FA chemotaxis). Probing Western blots with phosphoserine antibodies revealed several phosphoprotein bands that displayed increases when cAMP-responsive cells were treated with TFP. In FA-responsive cells, several but distinct phosphoproteins decreased when treated with TFP. These data show that unique CaMBPs are present in growing, FA-chemosensitive cells vs. starved cAMP-chemoresponsive cells that may be important for mediating CaM-dependent events during chemotaxis.

Regulation of Dictyostelium myosin I and II

Dictyostelium expresses 12 different myosins, including seven single-headed myosins I and one conventional two-headed myosin II. In this review we focus on the signaling pathways that regulate Dictyostelium myosin I and myosin II. Activation of myosin I is catalyzed by a Cdc42/Rac-stimulated myosin I heavy chain kinase that is a member of the p21-activated kinase (PAK) family. Evidence that myosin I is linked to the Arp2/3 complex suggests that pathways that regulate myosin I may also influence actin filament assembly. Myosin II activity is stimulated by a cGMP-activated myosin light chain kinase and inhibited by myosin heavy chain kinases (MHCKs) that block bipolar filament assembly. Known MHCKs include MHCK A and MHCK B, which have a novel type of kinase catalytic domain joined to a WD repeat domain, and MHC-protein kinase C (PKC), which contains both diacylglycerol kinase and PKC-related protein kinase catalytic domains. A Dictyostelium PAK (PAKa) acts indirectly to promote myosin II filament formation, suggesting that the MHCKs may be indirectly regulated by Rac GTPases.

Molecular motors and membrane traffic in Dictyostelium

Phagocytosis and membrane traffic in general are largely dependent on the cytoskeleton and their associated molecular motors. The myosin family of motors, especially the unconventional myosins, interact with the actin cortex to facilitate the internalization of external materials during the early steps of phagocytosis. Members of the kinesin and dynein motor families, which mediate transport along microtubules (MTs), facilitate the intracellular processing of the internalized materials and the movement of membrane. Recent studies indicate that some unconventional myosins are also involved in membrane transport, and that the MT- and actin-dependent transport systems might interact with each other. Studies in Dictyostelium have led to the discovery of many motors involved in critical steps of phagocytosis and membrane transport. With the ease of genetic and biochemical approaches, the established functional analysis to test phagocytosis and vesicle transport, and the effort of the Dictyostelium cDNA and Genome Projects, Dictyostelium will continue to be a superb model system to study phagocytosis in particular and cytoskeleton and motors in general.

Regulation and expression of metazoan unconventional myosins

Unconventional myosins are molecular motors that convert adenosine triphosphate (ATP) hydrolysis into movement along actin filaments. On the basis of primary structure analysis, these myosins are represented by at least 15 distinct classes (classes 1 and 3-16), each of which is presumed to play a specific cellular role. However, in contrast to the conventional myosins-2, which drive muscle contraction and cytokinesis and have been studied intensively for many years in both uni- and multicellular organisms, unconventional myosins have only been subject to analysis in metazoan systems for a short time. Here we critically review what is known about unconventional myosin regulation, function, and expression. Several points emerge from this analysis. First, in spite of the high relative conservation of motor domains among the myosin classes, significant differences are found in biochemical and enzymatic properties of these motor domains. Second, the idea that characteristic distributions of unconventional myosins are solely dependent on the myosin tail domain is almost certainly an oversimplification. Third, the notion that most unconventional myosins function as transport motors for membranous organelles is challenged by recent data. Finally, we present a scheme that clarifies relationships between various modes of myosin regulation.

Functional analysis of tail domains of Acanthamoeba myosin IC by characterization of truncation and deletion mutants

Acanthamoeba myosin IC has a single 129-kDa heavy chain and a single 17-kDa light chain. The heavy chain comprises a 75-kDa catalytic head domain with an ATP-sensitive F-actin-binding site, a 3-kDa neck domain, which binds a single 17-kDa light chain, and a 50-kDa tail domain, which binds F-actin in the presence or absence of ATP. The actin-activated MgATPase activity of myosin IC exhibits triphasic actin dependence, apparently as a consequence of the two actin-binding sites, and is regulated by phosphorylation of Ser-329 in the head. The 50-kDa tail consists of a basic domain, a glycine/proline/alanine-rich (GPA) domain, and a Src homology 3 (SH3) domain, often referred to as tail homology (TH)-1, -2, and -3 domains, respectively. The SH3 domain divides the TH-3 domain into GPA-1 and GPA-2. To define the functions of the tail domains more precisely, we determined the properties of expressed wild type and six mutant myosins, an SH3 deletion mutant and five mutants truncated at the C terminus of the SH3, GPA-2, TH-1, neck and head domains, respectively. We found that both the TH-1 and GPA-2 domains bind F-actin in the presence of ATP. Only the mutants that retained an actin-binding site in the tail exhibited triphasic actin-dependent MgATPase activity, in agreement with the F-actin-cross-linking model, but truncation reduced the MgATPase activity at both low and high actin concentrations. Deletion of the SH3 domain had no effect. Also, none of the tail domains, including the SH3 domain, affected either the K(m) or V(max) for the phosphorylation of Ser-329 by myosin I heavy chain kinase.

Regulation of the enzymatic and motor activities of myosin I

Myosins I were the first unconventional myosins to be purified and they remain the best characterized. They have been implicated in various motile processes, including organelle translocation, ion channel gating and cytoskeletal reorganization but their exact cellular functions are still unclear. All members of the myosin I family, from yeast to man, have three structural domains: a catalytic head domain that binds ATP and actin; a tail domain believed to be involved in targeting the myosins to specific subcellular locations and a junction or neck domain that connects them and interacts with light chains. In this review we discuss how each of these three domains contributes to the regulation of myosin I enzymatic activity, motor activity and subcellular localization.

A potentially exhaustive screening strategy reveals two novel divergent myosins in Dictyostelium

In recent years, the myosin superfamily has kept expanding at an explosive rate, but the understanding of their complex functions has been lagging. Therefore, Dictyostelium discoideum, a genetically and biochemically tractable eukaryotic amoeba, appears as a powerful model organism to investigate the involvement of the actomyosin cytoskeleton in a variety of cellular tasks. Because of the relatively high degree of functional redundancy, such studies would be greatly facilitated by the prior knowledge of the whole myosin repertoire in this organism. Here, we present a strategy based on PCR amplification using degenerate primers and followed by negative hybridization screening which led to the potentially exhaustive identification of members of the myosin family in D. discoideum. Two novel myosins were identified and their genetic loci mapped by hybridization to an ordered YAC library. Preliminary inspection of myoK and myoM sequences revealed that, despite carrying most of the hallmarks of myosin motors, both molecules harbor features surprisingly divergent from most known myosins.

Architectural dynamics of F-actin in eupodia suggests their role in invasive locomotion in Dictyostelium

Eupodia are F-actin-containing cortical structures similar to vertebrate podosomes or invadopodia found in metastatic cells. Eupodia are rich in alpha-actinin and myosin IB/D, but not a Dictyostelium homologue of talin. In the present study, we localized other actin-binding proteins, ABP120, cofilin, coronin, and fimbrin, in the eupodia and examined the three-dimensional organization of their F-actin system by confocal microscopy and transmission electron microscopy. To examine their function, we analyzed the assembly and disassembly dynamics of the F-actin system in eupodia and its relation to lamellipodial protrusion. Actin dynamics was examined by monitoring S65T-GFP-coronin and rhodamine-actin using a real-time confocal unit and a digital microscope system. Fluorescence morphometric analysis demonstrates the presence of a precise spatiotemporal coupling between F-actin assembly in eupodia and lamellipodial protrusion. When a lamellipodium advances to invade a tight space, additional rows of eupodia are sequentially formed at the base of that lamellipodium. These results indicate that mechanical stress at the leading edge modulates the structural integrity of actin and its binding proteins, such that eupodia are formed when anchorage is needed to boost for invasive protrusion of the leading edge.

Analysis of the regulatory phosphorylation site in Acanthamoeba myosin IC by using site-directed mutagenesis

The actin-activated ATPase activity of Acanthamoeba myosin IC is stimulated 15- to 20-fold by phosphorylation of Ser-329 in the heavy chain. In most myosins, either glutamate or aspartate occupies this position, which lies within a surface loop that forms part of the actomyosin interface. To investigate the apparent need for a negative charge at this site, we mutated Ser-329 to alanine, asparagine, aspartate, or glutamate and coexpressed the Flag-tagged wild-type or mutant heavy chain and light chain in baculovirus-infected insect cells. Recombinant wild-type myosin IC was indistinguishable from myosin IC purified from Acanthamoeba as determined by (i) the dependence of its actin-activated ATPase activity on heavy-chain phosphorylation, (ii) the unusual triphasic dependence of its ATPase activity on the concentration of F-actin, (iii) its Km for ATP, and (iv) its ability to translocate actin filaments. The Ala and Asn mutants had the same low actin-activated ATPase activity as unphosphorylated wild-type myosin IC. The Glu mutant, like the phosphorylated wild-type protein, was 16-fold more active than unphosphorylated wild type, and the Asp mutant was 8-fold more active. The wild-type and mutant proteins had the same Km for ATP. Unphosphorylated wild-type protein and the Ala and Asn mutants were unable to translocate actin filaments, whereas the Glu mutant translocated filaments at the same velocity, and the Asp mutant at 50% the velocity, as phosphorylated wild-type proteins. These results demonstrate that an acidic amino acid can supply the negative charge in the surface loop required for the actin-dependent activities of Acanthamoeba myosin IC in vitro and indicate that the length of the side chain that delivers this charge is important.

The ATPase activity of Myr3, a rat myosin I, is allosterically inhibited by its own tail domain and by Ca2+ binding to its light chain calmodulin

We purified Myr3 (third unconventional myosin from rat), a mammalian "amoeboid" subclass myosin I, from rat liver. The heavy chain of purified Myr3 is associated with a single calmodulin light chain. Myr3 exhibits K/EDTA-ATPase and Mg-ATPase activity. The Mg-ATPase activity is stimulated by increasing F-actin concentrations in a complex triphasic manner similar to the Mg-ATPase activity of myosin I molecules from protozoa. Although purified Myr3 was observed to cross-link actin filaments, it bound in an ATP regulated manner to F-actin, and no evidence for a nucleotide-independent high affinity actin binding site that could explain the triphasic activation pattern was obtained. Micromolar concentrations of free Ca2+ reversibly inhibit the Mg-ATPase activity of Myr3 by binding to its light chain calmodulin, which remains bound to the Myr3 heavy chain irrespective of the free Ca2+ concentration. Polyclonal antibodies and Fab fragments directed against the tail domain were found to stimulate the Mg-ATPase activity. A similar stimulation of the Myr3 Mg-ATPase activity is observed upon proteolytic removal of the very C-terminal SH3 domain. These results demonstrate that Myr3 is subject to negative regulation by free calcium and its own tail domain and possibly positive regulation by a tail-domain binding partner.

The myosin I SH3 domain and TEDS rule phosphorylation site are required for in vivo function

The class I myosins play important roles in controlling many different types of actin-based cell movements. Dictyostelium cells either lacking or overexpressing amoeboid myosin Is have significant defects in cortical activities such as pseudopod extension, cell migration, and macropinocytosis. The existence of Dictyostelium null mutants with strong phenotypic defects permits complementation analysis as a means of exploring important functional features of the myosin I heavy chain. Mutant Dictyostelium cells lacking two myosin Is exhibit profound defects in growth, endocytosis, and rearrangement of F-actin. Expression of the full-length myoB heavy chain in these cells fully rescues the double mutant defects. However, mutant forms of the myoB heavy chain in which a serine at the consensus phosphorylation site has been altered to an alanine or in which the C-terminal SH3 domain has been removed fail to complement the null phenotype. The wild-type and mutant forms of the myoB heavy chain appeared to be properly localized when they were expressed in the myosin I null mutants. These results suggest that the amoeboid myosin I consensus phosphorylation site and SH3 domains do not play a role in the localization of myosin I, but are absolutely required for in vivo function.

Myosin I overexpression impairs cell migration

Dictyostelium myoB, a member of the myosin I family of motor proteins, is important for controlling the formation and retraction of membrane projections by the cell's actin cortex (Novak, K.D., M.D. Peterson, M.C. Reedy, and M.A. Titus. 1995. J. Cell Biol. 131:1205-1221). Mutants that express a three- to sevenfold excess of myoB (myoB+ cells) were generated to further analyze the role of myosin I in these processes. The myoB+ cells move with an instantaneous velocity that is 35% of the wild-type rate and exhibit a 6-8-h delay in initiation of aggregation when placed under starvation conditions. The myoB+ cells complete the developmental cycle after an extended period of time, but they form fewer fruiting bodies that appear to be small and abnormal. The myoB+ cells are also deficient in their ability both to form distinct F-actin filled projections such as crowns and to become elongate and polarized. This defect can be attributed to the presence of at least threefold more myoB at the cortex of the myoB+ cells. In contrast, threefold overexpression of a truncated myoB that lacks the src homology 3 (SH3) domain (myoB/SH3- cells) or myoB in which the consensus heavy chain phosphorylation site was mutated to an alanine (S332A-myoB) does not disturb normal cellular function. However, there is an increased concentration of myoB in the cortex of the myoB/SH3- and S332A-myoB cells comparable to that found in the myoB+ cells. These results suggest that excess full-length cortical myoB prevents the formation of the actin-filled extensions required for locomotion by increasing the tension of the F-actin cytoskeleton and/or retracting projections before they can fully extend. They also demonstrate a role for the phosphorylation site and SH3 domain in mediating the in vivo activity of myosin I.

Cloning and characterization of a Dictyostelium myosin I heavy chain kinase activated by Cdc42 and Rac

The motile activities of the small, single-headed class I myosins (myosin I) from the lower eukaryotes Acanthamoeba and Dictyostelium are activated by phosphorylation of a single serine or threonine residue in the head domain of the heavy chain. Recently, we purified a myosin I heavy chain kinase (MIHCK) from Dictyostelium based on its ability to activate the Dictyostelium myosin ID isozyme (Lee, S. -F., and Côté, G. P. (1995) J. Biol. Chem. 270, 11776-11782). The complete sequence of the Dictyostelium MIHCK has now been determined, revealing a protein of 98 kDa that is composed of an amino-terminal domain rich in proline, glutamine, and serine, a putative Cdc42/Rac binding motif, and a carboxyl-terminal kinase catalytic domain. MIHCK shares significant sequence identity with the Saccharomyces cerevisiae Ste20p kinase and the mammalian p21-activated kinase. Gel overlay assays and affinity chromatography experiments showed that MIHCK interacted with GTPgammaS (guanosine 5'-3-O-(thiotriphosphate))-labeled Cdc42 and Rac1 but not RhoA. In the presence of GTPgammaS-Rac1 MIHCK autophosphorylation increased from 1 to 9 mol of phosphate/mol, and the rate of Dictyostelium myosin ID phosphorylation was stimulated 10-fold. MIHCK may therefore provide a direct link between Cdc42/Rac signaling pathways and motile processes driven by myosin I molecules.

The catalytic domain of Acanthamoeba myosin I heavy chain kinase. I. Identification and characterization following tryptic cleavage of the native enzyme

The actin-activated Mg2+-ATPase activities of the myosin I isoenzymes from Acanthamoeba castellanii are greatly increased by phosphorylation catalyzed by myosin I heavy chain kinase (MIHC kinase), a monomeric 97-kDa protein whose activity is greatly enhanced by acidic phospholipids and by autophosphorylation of multiple sites. In this paper, we show that the 35-kDa COOH-terminal fragment obtained by trypsin cleavage of maximally activated, autophosphorylated kinase retains the full activity and two to three of the autophosphorylation sites of the native enzyme. Other autophosphorylation sites occur in the middle third of the native enzyme. A trypsin cleavage site within the 35-kDa region is protected in phosphorylated kinase but is readily cleaved in unphosphorylated kinase producing catalytically inactive 25- and 11-kDa fragments from the NH2- and COOH-terminal ends, respectively, of the 35-kDa peptide. This implies that the conformation around the "25/11" cleavage site changes upon phosphorylation of the native enzyme. The position of this site corresponds to the activation loop of protein kinase A (see the accompanying paper: Brzeska, H., Szczepanowska, J., Hoey, J., and Korn, E. D. (1996) J. Biol. Chem. 271, 27056-27062). Exogenously added MIHC kinase phosphorylates the 11-kDa fragment, but not the 25-kDa fragment, indicating that the phosphorylation sites of the 35-kDa catalytic fragment are located within the COOH-terminal 11 kDa. The accompanying paper describes the cloning, sequencing, and expression of a fully active 35-kDa catalytic domain.

Purification and characterization of a Dictyostelium protein kinase required for actin activation of the Mg2+ ATPase activity of Dictyostelium myosin ID

We have isolated a protein from Dictyostelium with a molecular mass of 110 kDa as judged by SDS-gel electrophoresis that can stimulate the actin-activated MgATPase activity of Dictyostelium myosin ID (MyoD). In the presence of MgATP the 110-kDa protein incorporated phosphate into itself and into the heavy chain, but not the light chain, of MyoD. Phosphorylation to 0.5 mol of Pi/mol increased the MyoD actin-activated MgATPase rate from 0.2 to 3 mumol/min/mg. Renaturation following SDS-gel electrophoresis demonstrated that the 110-kDa protein contained intrinsic protein kinase and autophosphorylation activity. Autophosphorylation to 1 mol of Pi/mol enhanced the rate at which the 110-kDa protein kinase phosphorylated MyoD by 40-fold. The rate of autophosphorylation was strongly dependent on the 110-kDa protein kinase concentration, indicating an intermolecular reaction. Synthetic peptides of 9-11 residues corresponding to the heavy chain phosphorylation site of Acanthamoeba myosin IC and the homologous sites in Dictyostelium myosin IB (MyoB) and MyoD were poor substrates for the 110-kDa protein kinase. The 110-kDa protein kinase was unable to phosphorylate the MyoB isozyme suggesting that it may be specific for MyoD.

Association of the Dictyostelium 30 kDa actin bundling protein with contact regions

‘Contact regions’ are plasma membrane domains derived from areas of intercellular contact between aggregating Dictyostelium amebae (H.M. Ingalls et al. (1986). Proc. Nat. Acad. Sci. USA 83, 4779). Purified contact regions contain a prominent actin-binding protein with an M(r) of 34,000. Immunoblotting with monoclonal antibodies identifies this polypeptide as a 34,000 M(r) actin-bundling protein (known as 30 kDa protein), previously shown to be enriched in filopodia (M. Fechheimer (1987). J. Cell Biol. 104, 1539). About four times more 30 kDa protein by mass is associated with contact regions than is found in total plasma membranes isolated from aggregating cells. In agreement with these observations, immunostaining of the 30 kDa protein in aggregating cells reveals a prominent localization along the plasma membrane at sites of intercellular contact. By contrast, alpha-actinin does not appear to be significantly enriched at sites of cell to cell contact. Binding experiments using purified plasma membranes, actin and 30 kDa protein indicate that the 30 kDa protein is associated with the plasma membrane primarily through interactions with actin filaments. Calcium ions are known to decrease the interaction of actin with 30 kDa protein in solution. Surprisingly, membrane-associated complexes of actin and the 30 kDa protein are much less sensitive to dissociation by micromolar levels of free calcium ions than are complexes in solutions lacking membranes.(ABSTRACT TRUNCATED AT 250 WORDS)

Actin-based cytoskeleton in growth cone activity

A growing tip of neurite, the neuronal growth cone, is a highly motile and adhesive form of cytoarchitecture. The growth cone plays vital roles for navigation, elongation and maintenance of neurites. One major constituent of growth cones, regulated by the intracellular Ca2+ signal, is the actin-based cytoskeleton. In this article, I have summarized four types of Ca(2+)-dependent regulation of the actin-based cytoskeleton in growth cones: gelsolin-actin, myosin II-actin microfilament, myosin II-actin, and Ca(2+)-sensitive alpha-actinin-actin systems. The four examples of Ca(2+)-dependent regulation described here may be involved in growth cone motility. The actin-based membrane skeleton forming a meshwork beneath the cytoplasmic surface of the growth cone membrane is also important for adhesion of growth cones to recognize cue molecules. The actin-based membrane skeleton participates in this recognition process and the adhesion-dependent signal transduction in association with receptors for cell adhesion molecules.

The Dictyostelium myosin IE heavy chain gene encodes a truncated isoform that lacks sequences corresponding to the actin binding site in the tail

We have isolated cDNA and genomic clones which together span the entire coding sequence for the 114.8 kDa heavy chain of Dictyostelium myosin IE (DMIE). The deduced primary sequence reveals a pattern characteristic of all myosins I, i.e., a myosin-like globular head domain fused to a tail domain that shows no similarity to the coiled-coil rod-like tail of type II myosins. The approx. 35 kDa tail domain of DMIE shows some sequence similarity to the membrane interaction region of other myosins I (tail-homology-region 1; TH-1), but lacks completely the sequences that correspond to the second actin binding site (the glycine-, proline- and alanine-rich TH-2 region and the src-like TH-3 region). Therefore, DMIE more closely resembles DMIA (Titus et al. (1989) Cell Regul 1, 55-63), which is also truncated, than DMIB and DMID, both of which possess all three tail homology regions. The similarity between the DMIE and DMIA isoforms extends to their pattern of expression, in which the steady state level of transcript for both genes is highest in vegetative cells and falls gradually after five to ten hours of starvation-induced development. Together, these results have important implications for interpreting and prioritizing gene targeting experiments designed to identify the functions of myosins I in vivo.

Myosin-like protein (M(r) 175,000) in Gregarina blaberae

A myosin-like protein (M(r) 175,000) was detected in the parasitic protozoan Gregarina blaberae, by both immunofluorescence and immunoblotting of one- and two-dimensional electrophoresis gels using anti-myosin antibodies. This protein was present in the trophozoite ghost but not in the cytoplasmic extract, nor in extract from the sexual stage, suggesting a protein-stage-dependent expression. The protein tightly bound to the cortical membranes was insoluble at low ionic strength, or in detergent solutions, but could be extracted from Gregarina ghosts by 6 M urea in high ionic strength solution (0.5 M NaCl) and in the presence of reducing agents (20 mM DTT). The protein was localized by indirect immunofluorescence in the cortex of the epimerite, in the fibrillar disc (the so-called septum) separating the proto- and the deutomerite segments, in the contractile ring or sphincter at the top of the protomerite, and as longitudinal lines underlying the G. blaberae epicyte folds. The presence of both actin-like and myosin-like proteins would be consistent with a role in gliding and other cell motility processes of this parasite.

Evidence for a new member of the myosin I family from mammalian brain

Myosin I is an actin-based motor responsible for powering a wide variety of motile activities in amebae and slime molds and has been found previously in vertebrates as the lateral bridges within intestinal epithelial cell microvilli. Although neurons exhibit extensive cellular and intracellular motility, including the production of ameboid-like growth cones during development, the proteins responsible for the motor in these processes are unknown. Here, we report the isolation of a partially purified protein fraction from bovine brain that is enriched for a 150-kDa protein; immunochemical and biochemical analyses suggest that this protein possesses a number of functional properties that have been ascribed to myosin I from various sources. These properties include an elevated K(+)-EDTA ATPase, a modest actin-activated Mg(2+)-ATPase, the ability to bind calmodulin, and a ready association with phospholipid vesicles made from phosphatidylserine, but not from phosphatidylcholine. The combination of these properties, together with a molecular mass of 150 kDa (most myosin I molecules found to date have molecular masses in the range 110-130 kDa) yet recognition by an anti-myosin I antibody, suggests the presence of a new member of the myosin I family within mammalian brain.

The role of myosin I and II in cell motility

It has been recognized since the turn of the century that cell motility by non-muscle cells requires virtually continuous restructuring of the cytoskeleton (see refs [1-4]). It is also clear that cell motility requires a mechanism for converting chemical energy into mechanical work. The proteins actin and myosin, two important constituents of the cytoskeleton, have been postulated to act as the chemicomechanical transducer in motile cells. Central to their role as a force generating mechanism in motile cells is the ability of myosin (a) to hydrolyze ATP when it interacts with actin and (b) to form filaments. Recent studies on mammalian cells and on the cellular slime mold Dictyostelium discoideum have shed light and at the same time raised questions regarding the involvement of myosin in cell motility. Moreover, they have demonstrated the presence of two types of myosins, called myosin II and myosin I, that have unique biochemical and regulatory properties and that may play different roles in mediating cell motility. In this chapter we will discuss the properties of these two myosins and then describe what is known about their involvement in Dictyostelium and mammalian cell motility.

The yeast type II myosin heavy chain: analysis of its predicted polypeptide sequence

We have completed the nucleotide sequence of the yeast MYO1 gene and deduced its amino acid sequence. The gene is 5553 bp long and contains no introns. Analysis of the sequence, as well as its comparison with other myosins, demonstrate that the yeast protein is a type II myosin heavy chain with characteristic head and tail regions. The latter domain contains six proline residues in two clusters of three, at approximately two thirds from the start of the gene.

Purification of Dictyostelium myosin II heavy chain kinase A based on the increase in negative charge accompanying hyperphosphorylation

The initial step in the purification of Dictyostelium myosin II heavy chain kinase A (MHCK A) is chromatography over phosphocellulose. Fractions containing MHCK A are pooled and chromatographed over a Mono Q column (Pharmacia LKB Biotechnology) equilibrated in 0.15 M KCl. Under these conditions MHCK A and most of the contaminating proteins elute in the flowthrough. The addition of Mg2+ and ATP to the Mono Q flowthrough results in the phosphorylation, within 15 min, of MHCK A to a level of 10 mol of phosphate per mole of 130-kDa kinase subunit. The hyperphosphorylated MHCK A binds to Mono Q columns in the presence of 0.15 M KCl and can be eluted, as a single homogeneous band, by a salt gradient to 0.35 M KCl. A similar purification procedure may prove useful for other proteins which can be highly phosphorylated. Hyperphosphorylation is shown to have no effect on the position at which MHCK A elutes from gel filtration columns (apparent M(r) greater than 700,000).

Dictyostelium myosin II heavy-chain kinase A is activated by autophosphorylation: studies with Dictyostelium myosin II and synthetic peptides

One of the major sites phosphorylated on the Dictyostelium myosin II heavy chain by the Dictyostelium myosin II heavy-chain kinase A (MHCK A) is Thr-2029. Two synthetic peptides based on the sequence of the Dictyostelium myosin II heavy chain around Thr-2029 have been synthesized: MH-1 (residues 2020-2035; RKKFGESEKTKTKEFL-amide) and MH-2 (residues 2024-2035). Both peptides are substrates for MHCK A and are phosphorylated to a level of 1 mol of phosphate/mol. Tryptic digests indicate that the peptides are phosphorylated on the threonine corresponding to Thr-2029. When assays are initiated by the addition of MHCK A, the rate of phosphate incorporation into the peptides increases progressively for 4-6 min. The increasing activity of MHCK A over this time period is a result of autophosphorylation. Although each 130-kDa subunit of MHCK A can incorporate up to 10 phosphate molecules, 3 molecules of phosphate per subunit are sufficient to completely activate the kinase. Autophosphorylated MHCK A displays Vmax values of 2.2 and 0.6 mumol.min-1.mg-1 and Km values of 100 and 1200 microM with peptides MH-1 and MH-2, respectively. Unphosphorylated MHCK A displays a 50-fold lower Vmax with MH-1 but only a 2-fold greater Km. In the presence of Dictyostelium myosin II, the rate of autophosphorylation of MHCK A is increased 4-fold. If assays are performed at 4 degrees C (to slow the rate of MHCK A autophosphorylation), autophosphorylation can be shown to increase the activity of MHCK A with myosin II.

Actomyosin organization in mitotic Dictyostelium amoebae

Immunofluorescence localization of actin and myosin during mitosis indicates the significant roles of these cytoskeletons for cytokinesis. High frequency mitosis was induced by synchronous culture using temperature shift (T. Kitanishi-Yumura and Y. Fukui, 1987), and high resolution fluorescence microscopy was performed by the agar-overlay method (S. Yumura and Y. Fukui, 1984). It was shown that actin and myosin are dissociated from the cortex in prophase and reassembled in anaphase to form unique cortical structures: the contractile ring and/or polar lamellipodial network. Conventional myosin (myosin-II) is only localized in the contractile ring, whereas a low-molecular weight isozyme (myosin-I) is localized in the polar leading edge (Y. Fukui, T. Lynch, H. Brzeska, and E. Korn, 1989). Actin is localized in both structures and also forms a unique array in the furrow oriented perpendicular to the plane of constriction (Y. Fukui and S. Inoué, manuscript in preparation). The study suggests that conventional myosin provides the major force of constriction, whereas myosin-I participates in projecting lamellipodia, and actin is involved in several different functions in different regions of the cytoplasm.

Partial characterization of a carotenoid droplet ATPase and its possible significance in carotenoid droplet dispersion in goldfish xanthophores

The dispersion of carotenoid droplets in permeabilized goldfish xanthophores is dependent on ATP, F-actin, and cytosol. We report here that the motor (ATPase, translocator) resides with the permeabilized cell remnants and not in the cytosol. We also report that the carotenoid droplets have an ATPase that is not conventional myosin, dynein, or an ion pump. Its activity appears to correlate with the actin content of the carotenoid droplet preparation. A carotenoid droplet protein of Mr 72,000 (p72) is shown to be labeled by irradiation with 8-azido-ATP with concomitant loss of ATPase activity of the carotenoid droplets. We propose that this protein may be the ATPase responsible for carotenoid droplet dispersion.