Fragmin60 encodes an actin-binding protein with a C2 domain and controls actin Thr-203 phosphorylation in Physarum plasmodia and sclerotia

We report the isolation of a cDNA clone encoding a 60-kDa protein termed fragmin60 that cross-reacts with fragmin antibodies. Unlike other gelsolin-related proteins, fragmin60 contains a unique N-terminal domain that shows similarity with C2 domains of aczonin, protein kinase C, and synaptotagmins. The fragmin60 C2 domain binds three calcium ions, one with nanomolar affinity and two with micromolar affinity. Actin binding by fragmin60 requires higher calcium concentrations than does binding of actin by a fragmin60 mutant lacking the C2 domain, suggesting that the C2 domain secures the actin binding moiety in a conformation preventing actin binding at low calcium concentrations. The fragmin60 C2 domain does not bind phospholipids but interacts with the endogenous homologue of Saccharomyces cerevisiae S-phase kinase-associated protein (Skp1), as shown by pull-down assays and co-expression in mammalian cells. Recombinant fragmin60 promotes in vitro phosphorylation of actin Thr-203 by the actin-fragmin kinase. We further show that in vivo phosphorylation of actin in the fragmin60-actin complex occurs in sclerotia, a dormant stage of Physarum development, as well as in plasmodia. Our findings indicate that we have cloned a novel type of gelsolin-related actin-binding protein that is involved in controlling regulation of actin phosphorylation in vivo.     

Tyrosine phosphorylation of actin during microcyst formation and germination in Polysphondylium pallidum

High osmolarity causes amoebae of the cellular slime mould Polysphondylium pallidum to individually encyst, forming microcysts. During microcyst differentiation, actin is tyrosine phosphorylated. Tyrosine phosphorylation of actin is independent of encystment conditions and occurs during the final stages of microcyst formation. During microcyst germination, actin undergoes dephosphorylation prior to amoebal emergence. Renewed phosphorylation of actin in germinating microcysts can be triggered by increasing the osmolarity of the medium which inhibits emergence. Immunofluorescence reveals that actin is dispersed throughout the cytoplasm in dormant microcysts. Following the onset of germination, actin is observed around vesicles where it co-localizes with phosphotyrosine. Prior to emergence, actin localizes to patches near the cell surface. Increasing osmolarity disrupts this localization and causes actin to redistribute throughout the cytoplasm, a situation similar to that observed in dormant microcysts. The tyrosine phosphorylation state of actin does not appear to influence the long-term viability of dormant microcysts. Together, these results indicate an association between actin tyrosine phosphorylation, organization of the actin cytoskeleton, and microcyst dormancy.     

Translational control and the cytoskeleton in Physarum polycephalum

Translationally active plasmodia of the syncytial slime mold Physarum polycephalum develop into translationally dormant sclerotia during starvation. Although functional mRNA and ribosomes exist in sclerotia, protein synthesis is suppressed at the level of initiation. To test the possibility that alterations in the cytoskeleton may limit protein synthesis, we have examined the distribution of polysomes and actin mRNA in the cytoskeletal (CSK) and soluble (SOL) fractions of Triton X-100-extracted plasmodia and sclerotia. Most of the polysomes and actin mRNA were located in the CSK of plasmodia, while most of the ribosomes and actin mRNA were located in the SOL of sclerotia. The results suggest that ribosomes and mRNA shift from the CSK to the SOL as protein synthesis is suppressed during starvation. Plasmodia and sclerotia can be induced to accumulate excess polysomes by treatment with low levels of the elongation inhibitor cycloheximide. Treatment of plasmodia with cycloheximide caused excess polysomes to accumulate in the SOL, suggesting that the CSK contains a limited capacity for binding translational components and that the association of polysomes with the cytoskeleton is not required for protein synthesis. Treatment of sclerotia with cycloheximide, however, caused polysomes and actin mRNA to accumulate in the CSK, suggesting that the sclerotial cytoskeleton, although depleted in ribosomes and mRNA, is capable of binding translational components. It is concluded that alterations in the sclerotial cytoskeleton are not involved in translational control.     

Physarum amoebae express a distinct fragmin-like actin-binding protein that controls in vitro phosphorylation of actin by the actin-fragmin kinase.

Amoebae and plasmodia constitute the two vegetative growth phases of the Myxomycete Physarum. In vitro and in vivo phosphorylation of actin in plasmodia is tightly controlled by fragmin P, a plasmodium-specific actin-binding protein that enables actin phosphorylation by the actin-fragmin kinase. We investigated whether amoebal actin is phosphorylated by this kinase, in spite of the lack of fragmin P. Strong actin phosphorylation was detected only following addition of recombinant actin-fragmin kinase to cell-free extracts of amoebae, suggesting that amoebae contain a protein with properties similar to plasmodial fragmin. We purified the complex between actin and this protein to homogeneity. Using an antibody that specifically recognizes phosphorylated actin, we demonstrate that Thr203 in actin can be phosphorylated in this complex. A full-length amoebal fragmin cDNA was cloned and the deduced amino acid sequence shows 65% identity with plasmodial fragmin. However, the fragmins are encoded by different genes. Northern blots using RNA from a developing Physarum strain demonstrate that this fragmin isoform (fragmin A) is not expressed in plasmodia. In situ localization showed that fragmin A is present mainly underneath the plasma membrane. Our results indicate that Physarum amoebae express a fragmin P-like isoform which shares the property of binding actin and converting the latter into a substrate for the actin-fragmin kinase.     

Glucose-induced pathways for actin tyrosine dephosphorylation during Dictyostelium spore germination

In the presence of germination signals, dormant spores of Dictyostelium discoideum rapidly germinate to start a new life cycle. Previously we have shown that half of the actin molecules in spores are maintained in a tyrosine-phosphorylated state, and a decline of the actin phosphorylation levels is a prerequisite for spore swelling. In this study, we have established d-glucose as a trigger molecule for the actin dephosphorylation. Present in a nutrient germination medium, d-glucose both may act as a trigger molecule and/or may serve as a substrate within a pathway for actin dephosphorylation depending upon spore age. However, the glucose-induced actin dephosphorylation was insufficient for spores to swell. Other factors in the nutrient medium were required for complete germination of young spores aged 1 to 5 days. In contrast, dispersion in nonnutrient buffer was necessary and sufficient for a decline of actin phosphorylation levels and even the emergence of amoebae in older spores (6 days and beyond). Moreover, the dephosphorylation pathway in the older spores was independent of energy production. We propose that the diversification of the actin dephosphorylation pathway may enable spores to increase their probability of germination upon spore aging.     

A novel type of protein kinase phosphorylates actin in the actin-fragmin complex.

Actin-fragmin kinase (AFK) from Physarum polycephalum specifically phosphorylates actin in the EGTA-resistant 1:1 actin-fragmin complex. The cDNA deduced amino acid sequence reveals two major domains of approximately 35 kDa each that are separated by a hinge-like proline/serine-rich segment of 50 residues. Whereas the N-terminal domain does not show any significant similarity to protein sequences from databases, there are six complete kelch repeats in the protein that comprise almost the entire C-terminal half of the molecule. To prove the intrinsic phosphorylation activity of AFK, full-length or partial cDNA fragments were expressed both in a reticulocyte lysate and in Escherichia coli. In both expression systems, we obtained specific actin phosphorylation and located the catalytic domain in the N-terminal half. Interestingly, this region did not contain any of the known protein kinase consensus sequences. The only known sequence motif present that could have been involved in nucleotide binding was a nearly perfect phosphate binding loop (P-loop). However, introduction of two different point mutations into this putative P-loop sequence did not alter the catalytic activity of the kinase, which indicates an as yet unknown mechanism for phosphate transfer. Our data suggest that AFK belongs to a new class of protein kinases and that this actin phosphorylation might be the first example of a widely distributed novel type of regulation of the actin cytoskeleton in non-muscle cells.     

Involvement of actin dephosphorylation in germination of Physarum sclerotium

The plasmodium of Physarum polycephalum grows without cytokinesis and shows an active cytoplasmic streaming under wet and nutritious conditions. It can undergo reversible differentiation into several types of dormancy to survive in adverse environments. Temperature change or osmotic stress leads to cytoplasmic division of the plasmodium into cells containing one or more nuclei: these form a macrocyst, the spherule. Desiccation also induces cell division of the plasmodium followed by formation of a sclerotium, a dormant body resistant to dry stress. More than half of the actin in a sclerotium is phosphorylated at a single site, threonine 203, resulting in loss of its ability to polymerize into actin filaments. In the present study, actin phosphorylation was found in the sclerotium but not in either the plasmodium or in the spherule. This result suggests that phosphorylation of sclerotium actin may be related to the mechanism associated with desiccation resistance rather than morphological changes through cell compartmentalization in the macrocyst formation. Moreover. dephosphorylation of the phosphorylated form of sclerotium actin began within 5 min after addition of water. Dephosphorylation was not affected by sucrose and sorbitol sugars, but was inhibited by ammonium bicarbonate, ammonium phosphate, sodium phosphate, NaCl, and KCl in a dose-dependent manner. On the other hand, in germination of the sclerotium there was measurable sensitivity to both carbohydrates and salts. Actin dephosphorylation seems to be one of the important processes in the early phase of sclerotium germination.     

Proteomic analysis of rice leaf sheath during drought stress

Drought is one of the most severe limitations on the productivity of rainfed lowland and upland rice. To investigate the initial response of rice to drought stress, changes in protein expression were analyzed using a proteomic approach. Two-week-old rice seedlings were exposed to drought conditions from 2 to 6 days, and proteins were extracted from leaf sheaths, separated by two-dimensional polyacrylamide gel electrophoresis and stained with Coomassie brilliant blue. After drought stress for 2 to 6 days, 10 proteins increased in abundance and the level of 2 proteins decreased. The functional categories of these proteins were identified as defense, energy, metabolism, cell structure, and signal transduction. In addition to drought stress, accumulations of protein were analyzed under several different stress conditions. The levels of an actin depolymerizing factor, a light harvesting complex chain II, a superoxidase dismutase and a salt-induced protein were changed by drought and osmotic stresses, but not cold or salt stresses, or abscisic acid treatment. The effect of drought stress on protein in the leaf sheaths of drought-tolerant rice cultivar was also analyzed. The light harvesting complex chain II and the actin depolymerizing factor were present at high levels in a drought-tolerant rice cultivar before stress application. With drought stress, actin depolymerizing factor was expressed in leaf blades, leaf sheaths, and roots. These results suggest that actin depolymerizing factor is one of the target proteins induced by drought stress.     

Protein synthesis elongation factor Tu present in spores of<Emphasis Type="Italic">Streptomyces coelicolor</Emphasis> can be phosphorylated<Emphasis Type="Italic">in vitro</Emphasis> by the spore protein kinase

In vitro phosphorylation of EF-Tu was shown in cell-free extract from dormant spores of Streptomyces coelicolor by a protein kinase present in spores. EF-Tu phosphorylation was observed on both intrinsic S. coelicolor factor and externally added purified EF-Tu from S. aureofaciens, on two isoforms. Putative serine and threonine residues as potential phosphorylation targets were determined in primary sequence and demonstrated on 3D structure model of EF-Tu.     

Expression of proteins and protein kinase activity during germination of aerial spores of Streptomyces granaticolor

Dormant aerial spores of Streptomyces granaticolor contain pre-existing pool of mRNA and active ribosomes for rapid translation of proteins required for earlier steps of germination. Activated spores were labeled for 30 min with [35S]methionine/cysteine in the presence or absence of rifamycin (400 microg/ml) and resolved by two-dimensional electrophoresis. About 320 proteins were synthesized during the first 30 min of cultivation at the beginning of swelling, before the first DNA replication. Results from nine different experiments performed in the presence of rifamycin revealed 15 protein spots. Transition from dormant spores to swollen spores is not affected by the presence of rifamycin but further development of spores is stopped. To support existence of pre-existing pool of mRNA in spores, cell-free extract of spores (S30 fraction) was used for in vitro protein synthesis. These results indicate that RNA of spores possesses mRNA functionally competent and provides templates for protein synthesis. Cell-free extracts isolated from spores, activated spores, and during spore germination were further examined for in vitro protein phosphorylation. The analyses show that preparation from dormant spores catalyzes phosphorylation of only seven proteins. In the absence of phosphatase inhibitors, several proteins were partially dephosphorylated. The activation of spores leads to a reduction in phosphorylation activity. Results from in vitro phosphorylation reaction indicate that during germination phosphorylation/dephosphorylation of proteins is a complex function of developmental changes.     

ACTIN BINDING PROTEIN 29 from Lilium pollen plays an important role in dynamic actin remodeling

Villin/gelsolin/fragmin superfamily proteins have been shown to function in tip-growing plant cells. However, genes encoding gelsolin/fragmin do not exist in the Arabidopsis thaliana and rice (Oryza sativa) databases, and it is possible that these proteins are encoded by villin mRNA splicing variants. We cloned a 1006-bp full-length cDNA from Lilium longiflorum that encodes a 263-amino acid predicted protein sharing 100% identity with the N terminus of 135-ABP (Lilium villin) except for six C-terminal amino acids. The deduced 29-kD protein, Lilium ACTIN BINDING PROTEIN29 (ABP29), contains only the G1 and G2 domains and is the smallest identified member of the villin/gelsolin/fragmin superfamily. The purified recombinant ABP29 accelerates actin nucleation, blocks barbed ends, and severs actin filaments in a Ca(2+)- and/or phosphatidylinositol 4,5-bisphosphate-regulated manner in vitro. Microinjection of the protein into stamen hair cells disrupted transvacuolar strands whose backbone is mainly actin filament bundles. Transient expression of ABP29 by microprojectile bombardment of lily pollen resulted in actin filament fragmentation and inhibited pollen germination and tube growth. Our results suggest that ABP29 is a splicing variant of Lilium villin and a member of the villin/gelsolin/fragmin superfamily, which plays important roles in rearrangement of the actin cytoskeleton during pollen germination and tube growth.     

The formation of actin rods composed of actin tubules in Dictyostelium discoideum spores

A new type of actin rod formed in both the nucleus and the cytoplasm, as well as tyrosine phosphorylation of actin, is implicated in the maintenance of dormancy and viability of Dictyostelium discoideum spores. Here the ultrastructure of the rods and their relationship to the phosphorylation of actin were examined. The rods first appeared in premature spores at the midculmination stage as bundles composed of actin tubules hexagonally cross-linked. The 13-nm-diameter bundles were composed of three actin filaments. Formation of the actin rods begins during the late culmination stage and proceeds until 2 days after completion of fruiting bodies. The physical events occur in the following order; association of several modules of bundles, close packing and decrease in diameter of actin tubules, elongation of rods across the nucleus or the cytoplasm. Actin phosphorylation levels increased at the late culmination stage and reached a maximum level 12 h later. Immediately following activation of spore germination, actin was rapidly dephosphorylated, followed shortly thereafter by the disappearance of rods. Shortened actin tubules once again became arranged in a hexagonal pattern. This hexagonal arrangement of actin tubules is possibly involved in rod formation and disappearance and does not depend upon actin phosphorylation. In contrast, rod-maturation processes may correlate with actin phosphorylation.     

Cofilin phosphorylation by protein kinase testicular protein kinase 1 and its role in integrin-mediated actin reorganization and focal adhesion formation

Testicular protein kinase 1 (TESK1) is a serine/threonine kinase with a structure composed of a kinase domain related to those of LIM-kinases and a unique C-terminal proline-rich domain. Like LIM-kinases, TESK1 phosphorylated cofilin specifically at Ser-3, both in vitro and in vivo. When expressed in HeLa cells, TESK1 stimulated the formation of actin stress fibers and focal adhesions. In contrast to LIM-kinases, the kinase activity of TESK1 was not enhanced by Rho-associated kinase (ROCK) or p21-activated kinase, indicating that TESK1 is not their downstream effector. Both the kinase activity of TESK1 and the level of cofilin phosphorylation increased by plating cells on fibronectin. Y-27632, a specific inhibitor of ROCK, inhibited LIM-kinase-induced cofilin phosphorylation but did not affect fibronectin-induced or TESK1-induced cofilin phosphorylation in HeLa cells. Expression of a kinase-negative TESK1 suppressed cofilin phosphorylation and formation of stress fibers and focal adhesions induced in cells plated on fibronectin. These results suggest that TESK1 functions downstream of integrins and plays a key role in integrin-mediated actin reorganization, presumably through phosphorylating and inactivating cofilin. We propose that TESK1 and LIM-kinases commonly phosphorylate cofilin but are regulated in different ways and play distinct roles in actin reorganization in living cells.     

Actin-fragmin interactions as revealed by chemical cross-linking

A one to one complex of actin and fragmin (a capping protein from Physarum polycephalum plasmodia) was cross-linked with 1-ethyl-3-[3-(dimethylamino)propyl] carbodiimide. The cross-linking reaction generated two cross-linked products with slightly different molecular weights (88 000 and 90 000) as major species. They were cross-linked products of one actin and one fragmin. The cross-linking site of fragmin in the actin sequence was determined by peptide mappings [Sutoh, K. (1982) Biochemistry 21, 3654-3661] after partial chemical cleavages of cross-linked products with hydroxylamine. The results indicated that the N-terminal segment of actin spanning residues 1-12 participated in cross-linking with fragmin. The cross-linker used in this study covalently bridges lysine side chains and side chains of acidic residues when they are in direct contact. Therefore, it seems that acidic residues in the N-terminal segment of actin (Asp-1, Glu-2, Asp-3, Glu-4, and Asp-11), at least some of them, are in the binding site of fragmin. It has already been shown that the same acidic segment of actin is in the binding site of myosin or depactin (an actin-depolymerizing protein isolated from starfish oocytes). We suggest that the unusual amino acid sequence of the N-terminal segment of actin makes its N-terminal region a favorable anchoring site for various types of actin-binding proteins.     

Specific activation of LIM kinase 2 via phosphorylation of threonine 505 by ROCK, a Rho-dependent protein kinase

LIM-kinase 1 (LIMK1) and LIM-kinase 2 (LIMK2) regulate actin cytoskeletal reorganization via cofilin phosphorylation downstream of distinct Rho family GTPases. We report our findings that ROCK, a downstream protein kinase of Rho, specifically activates LIMK2 but not LIMK1 downstream of RhoA. LIMK1 and LIMK2 activities toward cofilin phosphorylation were stimulated by co-expression with the active form of ROCK (ROCK-Delta3), whereas full-length ROCK selectively activates LIMK2 but not LIMK1. Activation of LIMK2 by RhoA was inhibited by Y-27632, a specific inhibitor of ROCK, but Rac1-mediated activation of LIMK1 was not. ROCK directly phosphorylated the threonine 505 residue within the activation segment of LIMK2 and markedly stimulated LIMK2 activity. A LIMK2 mutant with replacement of threonine 505 by valine abolished LIMK2 activities for cofilin phosphorylation and actin cytoskeletal changes, whereas replacement by glutamate enhanced the protein kinase activity and stress fiber formation by LIMK2. These results indicate that ROCK directly phosphorylates threonine 505 and activates LIMK2 downstream of RhoA and that this phosphorylation is essential for LIMK2 to induce actin cytoskeletal reorganization. Together with the finding that LIMK1 is regulated by Pak1, LIMK1 and LIMK2 are regulated by different protein kinases downstream of distinct Rho family GTPases.     

Inducible phosphorylation of cortactin is not necessary for cortactin-mediated actin polymerisation

Cortactin is an SH3 domain-containing protein that contributes to the formation of dynamic cortical actin-associated structures, such as lamellipodia and membrane ruffles. It was originally identified as a substrate for the protein kinase Src; however, the role of tyrosine phosphorylation in the translocation of cortactin to the cell periphery and in the subsequent actin polymerisation is still unclear. Recently, two serine/threonine kinases, Pak1 and Erk, have been implicated in the regulation of cortactin. Therefore, we systematically investigated whether phosphorylation on either tyrosine or serine/threonine residues is necessary for cortactin function. In COS7 cells over-expressing Vav2 or treated with EGF, we could not detect tyrosine phosphorylation, although cortactin was translocated to cell periphery and induced membrane ruffle formation. In addition, the selective MEK inhibitor, PD98059, did not influence in vivo the ability of cortactin to bind to and induce membrane ruffles upon Vav2 over-expression or short-term EGF treatment. Finally, using a constitutively active Pak1 mutant, Pak1 T423E, we showed that Pak1 is not capable of phosphorylating cortactin either in vitro or in COS7 cells. These results suggest that cortactin-mediated actin polymerisation at cell periphery requires only Rac activation but neither tyrosine nor serine/threonine phosphorylation.     

Sortase C-mediated anchoring of BasI to the cell wall envelope of Bacillus anthracis

Vegetative forms of Bacillus anthracis replicate in tissues of an infected host and precipitate lethal anthrax disease. Upon host death, bacilli form dormant spores that contaminate the environment, thereby gaining entry into new hosts where spores germinate and once again replicate as vegetative forms. We show here that sortase C, an enzyme that is required for the formation of infectious spores, anchors BasI polypeptide to the envelope of predivisional sporulating bacilli. BasI anchoring to the cell wall requires the active site cysteine of sortase C and an LPNTA motif sorting signal at the C-terminal end of the BasI precursor. The LPNTA motif of BasI is cleaved between the threonine (T) and the alanine (A) residue; the C-terminal carboxyl group of threonine is subsequently amide linked to the side chain amino group of diaminopimelic acid within the wall peptides of B. anthracis peptidoglycan.