A study on actin-like protein biosynthesis in rat liver mitochondria

The in vitro experiments revealed no incorporation of amino acids into actin-like protein of isolated rat liver mitochondria. The method of pulse label showed the presence of [14C]actin-like protein in mitochondria of intact animals which were not administered cycloheximide. A new synthesized actin-like protein is identified in mitochondria as a labelled polypeptide with apparent molecular weight 42 kDa. The data obtained may evidence for cytoplasmic localization of mitochondrial actin-like protein biosynthesis.     

Synthesis of actin-like protein in rat liver mitochondria

Isolated rat liver mitochondria failed to exhibit in vitro incorporation of [14C]-amino acids into actin-like protein. The use of a pulse-labelling technique demonstrated the appearance of [14C]-actin-like protein in the mitochondria of control, cycloheximide-free rats. The actin-like protein was identified by the method of affinity binding on DNAse1-sepharose and by electrophoresis on polyacrylamide gel with sodium dodecyl sulphate. It was shown that mitochondrial actin-like protein is not included among the nine polypeptides synthesized in mitochondria during cycloheximide-induced blockade of cytoplasmic protein synthesis. It was shown that actin-like protein was not desorbed from mitochondria by repeated washing with isotonic sucrose-mannitol medium. The results obtained indicate that the actin-like protein is biosynthesised in the cytoplasmic compartment.     

Identification of an actin-like protein and of its messenger ribonucleic acid in Saccharomyces cerevisiae.

We have identified a yeast protein that resembles actins from other eucaryotes in its tight binding to pancreatic deoxyribonuclease I, its copolymerizaton with purified muscle actin, its one-dimensional peptide map, and its apparent polymerization into 7-nm filaments. The yeast actin-like protein yielded a single spot on two-dimensional polyacrylamide gel electrophoresis, suggesting that a single protein species was present. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the actin-like protein had an apparent molecular weight of 45,000 compared with 42,000 for muscle actin. In an attempt to identify the messenger ribonucleic acid coding for the actin-like protein, yeast polyadenylic acid-rich ribonucleic acid was translated in wheat germ and reticulocyte cell-free protein-synthesizing systems. The actin-like protein was identified among the translation products of the reticulocyte system by its tight binding to deoxyribonuclease I, its comigration with the in vivo-synthesized actin-like protein during sodium dodecyl sulfate-polyacrylamide gel electrophoresis, an the similarity of its peptide map to that of the in vivo-synthesized protein. A yeast protein synthesized in the wheat-germ system was also found to bind to deoxyribonuclease I and to copolymerize with muscle actin. However, its apparent molecular weight was about 35,000, suggesting that it was a product either of incomplete translation or of proteolytic cleavage of the actin-like protein.     

AN ACTIN-LIKE PROTEIN OF THE SEA URCHIN EGGS II. DIRECT ISOLATION PROCEDURE

A direct extraction procedure for isolation of an actin-like protein from fresh sea urchin eggs was tried. The actin-like protein was found in the 10,000g supernatant of the egg homogenate. The crude extract obtained from the egg homogenate was purified by ammonium sulfate fractionation and dialysis against an ATP-cysteine solution. The purified actin-like protein occurred as 2.8S globular protein units, which transformed into heavy components of 7–8S and 12–13S on addition of salts. This change was accompanied by a rise in viscosity.     

Evolution of human cytoplasmic actin gene sequences: chromosome mapping and structural characterizations of three cytoplasmic actin-like pseudogenes including one on the Y chromosome

Eight recombinant phage clones containing cytoplasmic actin-like gene sequences have been isolated from a human genomic library for structural characterization. Kpn I family repeat sequences flank six of these actin genes isolated, and Alu family repeats are scattered throughout the DNA inserts of all eight phage clones. Three of these genes are γ actin-like, and the other five are β actin-like. The complete nucleotide sequence analysis of one β and one γ actin-like genes and their flanking regions demonstrates that they both are processed pseudogenes. Using unique DNA sequences flanking these two pseudogenes as hybridization probes for human-mouse somatic cell hybrid DNAs, we have mapped the two actin pseudogenes on human chromosomes 8 and 3, respectively. We have also determined the DNA sequence of a human Y chromosome-linked, processed actin pseudogene. The different values of sequence divergence of these processed pseudogenes and their functional counterparts allow us to estimate the time of generation of the pseudogenes. The results suggest that the cDNA insertion events generating the human cytoplasmic actin-like pseudogenes have occurred at significantly different times during the evolution of primates, after their separation from other mammalian species.     

Isolation and characteristics of actin-like proteins in liver mitochondria

Using affinity chromatography on DNAase I-Sepharose, an actin-like protein was isolated from rat liver mitochondria and purified 60-fold. SDS electrophoresis in polyacrylamide gel revealed that the protein migrated with muscle actin and thus had the molecular weight of 42 000 Da. Evidence for the actin-like nature of the mitochondrial protein could be obtained from the fact that the protein inhibited the activity of pancreatic DNAase I which, similar to the smooth muscle protein, was less conspicuous than that of its muscle counterpart. Unlike striated muscle actin but similar to the smooth muscle protein, the mitochondrial actin weakly stimulated the Mg-ATPase activity of rabbit skeletal muscle myosin. After manyfold washing of the mitochondria with isotonic isolation media, the content of the actin-like protein remained unchanged, which indirectly points to the presence of insignificant cytoplasmic actin contaminations. During isoelectrofocusing, the mitochondrial actin-like protein yielded two forms, i. e., beta- and gamma-isoactins, whose ratio was 8:1. The pI values for the beta- and gamma-isoforms were 5.52 and 5.59, respectively. The identical position of the absorption spectra (260 nm) and fluorescence excitation spectra (around 280 nm) maxima of the actin-like protein and smooth and skeletal muscle actins testify to their homology.     

Myosin and actin from Escherichia coli K12 C600.

Myosin-like protein and actin-like protein from E. coli formed filaments very similar in structure to those of myosin and actin from skeletal muscle. At 0.2 M KCl, a large number of "thick filaments" of uniform size (about 0.6-0.7 micron long and about 20 nm wide) was present. These thick filaments aggregated as the KCl concentration decreased to less than 0.2 M. Filaments of actin-like protein were decorated with muscle heavy meromyosin, showing "arrowheads". The arrowhead structure disappeared in the presence of ATP. A mixture of E. coli myosin-like protein and rabbit skeletal actin exhibited a gelation phenomenon on the additon of ATP. The phenomenon was reversible and showed ATP specificity. However, the gelation phenomenon was not observed with the mixture of E. coli actin-like protein and E. coli myosin-like protein. These results provide compelling evidence that the E. coli myosin-like protein and actin-like protein we isolated are essentially identical to myosin and actin, respectively.     

Myosin-like protein and actin-like protein from Escherichia coli K12 C600.

Myosin-like protein was obtained from E. coli by extraction with a sucrose solution and by precipitation with rabbit skeletal actin. The preparation of E. coli myosin-like protein looked very similar, in the sodium dodecyl sulfate-gel electrophoretic pattern, to that of rabbit skeletal myosin. The myosin-like protein was able to reversibly bind to rabbit actin. It had the activities of EDTA-, Ca-, and Mg-ATPases. The product in the EDTA-ATPase reaction catalyzed by the myosin-like protein was identified as ADP by ion exchange chromatography. The Mg-ATPase activity of E. coli myosin-like protein was activated by either rabbit actin or E. coli actin-like protein though the activation was much stronger by the latter. However, the myosin-like protein did not exhibit superprecipitation either with rabbit actin or with E. coli actin-like protein. Actin-like protein was also obtained from E. coli by essentially the same procedures as those described for preparation of rabbit skeletal actin. E. coli actin-like protein was capable of activating Mg-ATPase of rabbit myosin, and also of superprecipitation with rabbit myosin. Extraction from both the whole cells and the membrane fraction of E. coli strongly suggested that the myosin-like protein and the actin-like protein are both localized in the membrane fraction rather than in the cytoplasmic fraction.     

Luminescence characteristics of mitochondrial actin-like protein

Investigations comparing tryptophan fluorescence of mitochondrial actin-like protein with that of skeletal and smooth muscle actins have shown that the mitochondrial protein is characterized by a fluorescence spectrum peak at a longer wavelength (337 nm), by a certain broadening of this peak (56 nm) and by a reduction in the lifespan of the excited state of tryptophanyls (2.7 ns). The data obtained suggest the existence of peculiarities in the structure of mitochondrial actin-like protein.     

Anti-actin-peroxidase staining of the helical wall-free prokaryoteSpiroplasma citri

An antiserum made against sodium dodecyl sulfate-denatured actin from invertebrates and coupled to horseradish peroxidase specifically stains the wall-free prokaryoteSpiroplasma citri. The results of experiments with spiroplasmas reported here, coupled with the report of the extraction from them of an actin-like protein, suggest that these highly motile organisms possess an actin-like mediated mechanism of motility.     

Bacterial cell polarity: a "swarmer-stalked" tale of actin

The actin cytoskeleton is important for cell polarity and morphogenesis in eukaryotic organisms. A recent article describes an unexpected requirement for the actin-like protein MreB in the polarization of the bacterium Caulobacter crescentus. More surprisingly, the formation of a filamentous MreB structure that traverses the length of the cell is sufficient for randomized polar localization of cell-fate proteins. In this article, we discuss the significance of these findings and the possible mechanisms by which an actin-like cytoskeleton could mediate cell polarity in bacteria.     

Actin-like filaments in the acrosomal apparatus of spermatozoa of a sea urchin

The acrosomal apparatus of a sea urchin, Echinocardium cordatum, consists of an acrosomal vesicle and a post-acrosomal rod. The rod is 2.5 μm long and extends from the acrosomal vesicle to the bottom of a nuclear invagination. The rod consists of a bundle of longitudinally disposed, 60 Å thick, actin-like filaments which bind heavy meromyosin to form arrowhead complexes. The actin-like filaments may have a dual function in the fertilization process: (1) extension of the acrosomal process through the egg investments; (2) incorporation of the sperm nucleus.     

Biochemical characteristics of functionally active actin-like protein from liver mitochondria

The actin-like protein with a molecular weight of 42 kDa was obtained from the preparation of freshly isolated mitochondria of the rat liver using the method of immobilized DNAse affinity chromatography. The inhibitory ability of the isolated protein with respect to pancreatic DNAse I was the same as that of muscular actin. The native structure of the mitochondria protein is confirmed by the data of spectral analysis and its ability to globular-fibrillar transformation with an increased ionic strength of the solution. The polymerization ability as well as a stimulating effect of the actin-like protein of mitochondria on the ATPase activity of myosin is much less pronounced as compared to actin of skeletal muscles.     

An actin-like component in spermatocytes of a crane fly (Nephrotoma suturalis Loew)

Decorated actin-like filaments were seen in spindles after crane fly spermatocytes were glycerinated and then treated with rabbit skeletal muscle heavy meromyosin (HMM). Both ATP and pyrophosphate inhibited the HMM reaction. In prometaphase, metaphase, and mid-anaphase cells, actin-like filaments were seen near regions where chromosomal spindle fibres are seen in living cells, and were oriented in the pole-to-pole direction. In the interzone of anaphase cells, actin-like filaments were not oriented in a preferential direction when they were not associated with the microtubules attached to the sex chromosomes. No filaments were seen in glycerinated spindles not treated with HMM. We discuss reasons why filaments might not be seen without prior HMM treatment, and we discuss the possible role of the actin-like filaments in the spindles. — Spindle microtubules often were not seen in cells treated with HMM. This depended on the stage of division: in prometaphase no microtubules were seen; in metaphase microtubules were seen, in apparently normal numbers; in mid-anaphase, microtubules between the autosomes and the poles were seen in reduced numbers, those associated with the equatorial sex-chromosomes were seen in apparently normal numbers, while those between the separating autosomal half-bivalents were not seen. Microtubules were not seen in glycerinated spindles not treated with HMM, suggesting that HMM in some way affects microtubule stability. The question of microtubule stability is briefly discussed.     

Kinetics of the biosynthesis and distribution of labelled actin-like proteins in rat liver submitochondrial fractions

Affinity adsorption on immobilized DNAase I and the measurements of the protein mobility upon SDS-PAGE electrophoresis were used for the identification of the actin-like protein as well as for the study of its biosynthesis is liver mitochondria of hepatectomized rats. The kinetics of biosynthesis showed a maximum on the 10th min after intraperitoneal injection of the label. Fractionation of mitochondria demonstrated that more than 50% of the whole amount of the "de novo" synthesized protein is localized in the intermembrane space, approximately 30%--in the mitochondrial matrix. The purity of the fractions was controlled by analyzing the polypeptide content of the samples and by measuring the marker enzyme activity. Besides, additional identification of the actin-like protein was carried out directly in the mitochondrial matrix and intermembrane space by two-dimensional electrophoresis in polyacrylamide gel performed by the O'Farrell method. The subsequent staining of the gels with silver revealed the presence of two basic isoforms of non-muscle action (beta- and gamma-actins). The presence of the actin-like protein in the inner mitochondrial compartments characterized by a high rate of metabolism may be regarded as compelling evidence of its mitochondrial localization.     

Coevolution of actin and associated proteins: an α-actinin-like protein in a cyanobacterium (Spirulina platensis)

Actin, together with associated proteins, such as myosin, cross-linking or capping proteins, has been observed in all eukaryotic cells. Presence of actin or actin-like proteins has also been reported in prokaryotic organisms belonging to the cyanobacteria. Our aim was first to extend the characterization of an actin-like protein to another prokaryotic cell, i.e. Spirulina, then to compare the antigenic reactivity of this new protein with that of Synechocystis and skeletal actins. We observed that some of the conserved antigenic epitopes corresponded to actin regions known to interact with cross-linking proteins. We also report for the first time that α-actinin and filamin purified from chicken gizzard both interact with a prokaryotic actin-like protein. Finally, we searched for the occurrence of a cross-linking protein in these cyanobacteria and identified a 105-kDa protein as an α-actinin-like protein using specific antibodies.     

An ultrastructural study of the microfilaments in rat brain by means of E-PTA staining and heavy meromyosin labeling

To identify structures involved in the translocation of the synaptic vesicles towards the presynaptic membrane, an ultrastructural study has been undertaken by means of (1) the E-PTA stain and (2) the HMM-labeling procedure. Using serial sections of E-PTA stained nervous tissue, especially those made in transversal and tangential planes, the geometric order of the presynaptic grid and of its constituents has been described in detail. It consisted of dense projections having the shape of small truncated pyramids cut parallel to their hexagonal bases which rested on the electron-lucent presynaptic membrane. The dense projections were arranged at the points of equilateral triangles. Around each dense projection, six asymmetric hexagonal holes were seen to be arrayed in an hexagonal pattern, forming thus the presynaptic sieve. From the spiny tops of the dense projections, which appeared as specialized structures of the dense material coating the inner surface of the plasma membrane at the level of the synaptic cleft, fine filaments, 40--60 A in diameter, radiated and formed a three-dimensional meshwork pervading the presynaptic bag. The dense cytoplasmic coating delineating the plasma membrane served as anchor points for these microfilaments. Upon incubation with rabbit skeletal muscle HMM the microfilaments underwent specific structural changes, consisting of: (1) a striking increase in diameter; (2) the association of periodic and polarized substructures with their surfaces. The synaptic vesicles and mitochondria were seen to be attached to the numerous HMM-decorated filaments or enmeshed in the network formed by these filaments. The actin-like filaments were anchored to the plasma membrane at many points and to the presynaptic dense projections. Following incubation in the buffer alone or in buffer HMM solutions containing Na+ pyrophosphate or ATP, no arrowheaded structures were observed. Thus, a network consisting of actin-like filaments was demonstrated in the presynaptic bag. Of particular interest was the structural relation of the actin-like filaments with the occasional, tapered myosin-like filaments. The role of the presynaptic actin-like network in the transport of synaptic vesicles towards the presynaptic membrane by a mechanism of chemomechanical transduction is discussed. In the postsynaptic dendrite or dendritic spine, a filamentous network was observed to be attached to the subsynaptic web by means of the E-PTA stain and of the HMM-labeling procedure. The occurrence of an actin-like meshwork in the postsynaptic region is suggested to produce changes in the macromolecular configuration of the postsynaptic membrane by a "mechanoenzyme" system similar to that described in the mitochondrial membrane.     

A Second Actin-Like MamK Protein in Magnetospirillum magneticum AMB-1 Encoded Outside the Genomic Magnetosome Island

Magnetotactic bacteria are able to swim navigating along geomagnetic field lines. They synthesize ferromagnetic nanocrystals that are embedded in cytoplasmic membrane invaginations forming magnetosomes. Regularly aligned in the cytoplasm along cytoskeleton filaments, the magnetosome chain effectively forms a compass needle bestowing on bacteria their magnetotactic behaviour. A large genomic island, conserved among magnetotactic bacteria, contains the genes potentially involved in magnetosome formation. One of the genes, mamK has been described as encoding a prokaryotic actin-like protein which when it polymerizes forms in the cytoplasm filamentous structures that provide the scaffold for magnetosome alignment. Here, we have identified a series of genes highly similar to the mam genes in the genome of Magnetospirillum magneticum AMB-1. The newly annotated genes are clustered in a genomic islet distinct and distant from the known magnetosome genomic island and most probably acquired by lateral gene transfer rather than duplication. We focused on a mamK-like gene whose product shares 54.5% identity with the actin-like MamK. Filament bundles of polymerized MamK-like protein were observed in vitro with electron microscopy and in vivo in E. coli cells expressing MamK-like-Venus fusions by fluorescence microscopy. In addition, we demonstrate that mamK-like is transcribed in AMB-1 wild-type and ΔmamK mutant cells and that the actin-like filamentous structures observed in the ΔmamK strain are probably MamK-like polymers. Thus MamK-like is a new member of the prokaryotic actin-like family. This is the first evidence of a functional mam gene encoded outside the magnetosome genomic island.     

Evolution of cytomotive filaments: the cytoskeleton from prokaryotes to eukaryotes

The basic features of the active filaments that use nucleotide hydrolysis to organise the cytoplasm are remarkably similar in the majority of all cells and are either actin-like or tubulin-like. Nearly all prokaryotic cells contain at least one form of FtsZ, the prokaryotic homologue of tubulin and some bacterial plasmids use tubulin-like TubZ for segregation. The other main family of active filaments, assembled from actin-like proteins, occurs in a wide range of bacterial species as well as in all eukaryotes. Some bacterial plasmids also use ParM, another actin-like protein. Higher-order filament structures vary from simple to complex depending on the cellular application. Equally, filament-associated proteins vary greatly between species and it is not possible currently to trace their evolution from prokaryotes to eukaryotes. This lack of similarity except in the three-dimensional structures and longitudinal interactions between the filament subunits hints that the most basic cellular function of the filaments is to act as linear motors driven by assembly dynamics and/or bending and hence we term these filament systems 'cytomotive'. The principle of cytomotive filaments seems to have been invented independently for actin- and tubulin-like proteins. Prokaryotes appear to have a third class of cytomotive filaments, typically associated with surfaces such as membranes or DNA: Walker A cytoskeletal ATPases (WACA). A possible evolutionary relationship of WACAs with eukaryotic septins is discussed.     

The mammalian anti-α-smooth muscle actin monoclonal antibody recognizes an α-actin-like protein in planaria (Dugesia lugubris s.l.)

The presence of an alpha-smooth muscle (alpha-sm) actin-like protein in planaria (Dugesia lugubris s.l.) is reported. The protein shows a 42 kDa molecular weight determined by sodium dodecyl sulphate polyacrylamide gel electrophoresis and is specifically recognized by the mammalian anti alpha-sm actin monoclonal antibody. When a planarian is induced to regenerate by head amputation, the immunostaining of the alpha-sm actin-like molecule becomes important in the area of growing blastema, reaching a maximum between 70-120 hours after injury. Conventional electron microscopy at the 4-day-regeneration stage shows that blastema-forming cells are a homogeneous population whose morphological features resemble those of migrating mesenchyme-like cells; only the myoblasts show a recognizable phenotype. The immunocytochemical localization of alpha-sm actin-like molecule by immunoperoxidase (light microscopy) and immunogold stains (electron microscopy) was carried out on both intact and injured worms. The antigen was localized mainly at the basal portion of the epidermal cells and in the undifferentiated mesenchyme-like cells. Myoblasts, but not differentiated myofibers, were also labelled by this antibody. The results indicate that in the lower Eumetazoan planarians, as well as in vertebrates, the alpha-sm actin can be considered to be a marker for myoid differentiation. The suggestion that alpha-sm actin can be used as a marker for mesenchyme-like cells in vertebrates and in invertebrates is also discussed.