Structural variations in actins. Biochemical and immunological tools for probing the structure of rabbit skeletal-muscle and bovine aortic actins.

Structural differences between skeletal-muscle and aortic actins were studied by using biochemical and immunological approaches. By using proteinase digestion we found that three regions of actin show structural differences: (a) in the C-terminal part, (b) the region around residue 227 and (c) the region around residue 167. By using antibodies specific to particular actin conformations we can discriminate between monomeric and filamentous forms of the two actins. Our results show that the minor sequence variations of the N- and C-terminal regions induce structural change in these regions, but also some long-range structural variations in other regions.     

Changes in contractile proteins during differentiation of myeloid leukemia cells. II. Purification and characterization of actin

A myeloid leukemia cell line, M1, differentiates to macrophage and gains locomotive and phagocytic activity when incubated with conditioned medium (CM) from a fibroblast culture and bacterial endotoxin. To characterize the actin molecules before and after differentiation, the actin was purified through three sequential steps: DEAE-sephadex A- 50, polymerization/depolymerization, and sephadex G-150 chromatography. There were no essential differences between the inhibitory activity of actins from control M1 cells and CM-treated M1 cells on both DNase I and heavy meromyosin (HMMM) K(+)-EDTA-ATPase; the same dose response as with skeletal muscle actin took place. After the treatment with CM, however, the specific activity for the activation of HMMM Mg(2+)- ATPase by actin became two-fold that of untreated M1 actin, which was one third of the value for skeletal muscle actin. The V(max) for the control and the CM-treated M1 cell, as well as the skeletal muscle actins, proved to be the same. By contrast, the K(app) values for the control and CM-treated M1-cell actins were 3- and 1.5-fold the value for skeletal-muscle actin. This means that CM treatment of the M1 actin produced a twofold affinity for the Mg(2+)-ATPase of skeletal-muscle myosin. The critical concentrations for polymerization were compared under different salt concentrations and temperatures. Although no marked difference was found for the presence of 2 mM MgCl(2), 0.1 M KCl in place of MgCl(2) at 5 degrees C gave the following values: 0.1 mg/ml for skeletal-muscle actin, 0.7 mg/ml for control M1 actin, 0,5 mg/ml for CM- treated M1 actin, and 1.0 mg/ml for the D(-) subline that is insensitive to CM. Although the critical concentration of D(-) actin is extraordinarily high, this actin showed normal polymerization above the critical concentration. This together with the data presented in our previous paper, that the D(-) actin in the crude extract did not polymerize, suggests that an inhibitor for actin polymerization is present in the subline. The kinetics experiment at 0.1 M KCl and 25 degrees C revealed a slower polymerization of untreated M1- and D(-)-cell actins as compared with CM-treated M1 actin. This delayed polymerization was due to a delay during the nucleation stage, not during the elongation stage. By isoelectric focusing, the ratios of β- to γ-actin showed a marked difference depending on the states of cells: about 4.9 for control M1, 2.8 for CM-treated M1, and 7.6 for D(-)-subline actins. Tryptic peptide maps also revealed the presence of different peptides. Thus, the functional differences of actin before and after the differentiation was accompanied by some chemical changes in actin molecules.     

Antigenic probes locate a serum-gelsolin-interaction site on the C-terminal part of actin.

The implication of part of the C-terminal of actin (within the 285-375 sequence) in the interaction of serum gelsolin was investigated by the use of specific antibodies. These antibodies were directed against two or three discrete epitopes, one of which was specific for skeletal-muscle actin. Some of these epitopes were found to be near the serum gelsolin-actin interface. Thus it can be assumed that part of the C-terminal of actin is exposed at the barbed end of the actin filament. The interaction between tropomyosin and actin was also studied.     

Two monoclonal antibodies to actin: one muscle selective and one generally reactive

Two IgG1, kappa monoclonal antibodies (Mab) against actin have been obtained from a fusion in which chicken gizzard actin was used as the immunogen. One Mab, designated B4, shows a preferential reactivity toward enteric smooth muscle actin but also cross-reacts with skeletal, cardiac, and aorta actins on the basis of immunoblots, ELISA assays, and indirect immunofluorescence. However, this antibody does not react with either cytoplasmic actin in any of these assay systems. A second Mab, designated C4, reacts with all six known vertebrate isoactins as well as Dictyostelium discoideum and Physarum polycephalum actins. Thus B4 Mab appears to react with an epitope that is at least partially shared among the muscle actins but not found in cytoplasmic actins, while C4 Mab binds to an antigenic determinant that has been highly conserved among the actins. The binding sites of both Mabs on skeletal actin overlap that of pancreatic DNase I. Both antibodies bind a SV8 proteolytic product comprising the amino-terminal two-thirds of the actin molecule, and their epitopes appear to overlap since C4 can compete for the binding of B4 to skeletal actin. Neither antibody is able to prevent actin polymerization.     

Conserved tissue-restricted expression of HUC 1-1 actin phenotype among eumetazoan organisms.

Actin has evolved from a single protein into a family of more than six distinct isoforms in mammals. Based on amino acid sequence data, actins segregate into two major classes, the "cytoplasmic" or nonmuscle actins, present in all animals, and the "a-" or muscle actins, a group restricted to vertebrate muscle. We have recently identified two unique actin isoforms in rat intestinal brush border which combine features of these two classes. The amino terminal regions of these actins indicate that they are of a cytoplasmic type and yet the carboxy terminal regions contain an epitope (defined by Mab HUC 1-1) which, among mammalian actins, is restricted to the muscle isoforms. We report here that in addition to the rat, all species thus far examined which have an intestinal "brush border" express actins containing the HUC 1-1 epitope in this region. Furthermore, we show that the actins present in the muscle tissue of nonvertebrate eumetazoans, which are all of the cytoplasmic type, also contain this epitope. Thus these findings suggest that the HUC 1-1 epitope appeared early on a subset of cytoplasmic-type actins and was retained among actins expressed in muscle tissue throughout the evolutionary divergence of these cytoplasmic-type actins to the "a-" muscle actins.     

The late pollen-specific actins in angiosperms

The actin gene family of Arabidopsis has eight functional genes that are grouped into two ancient classes, vegetative and reproductive, and into five subclasses based on their phylogeny and mRNA expression patterns. Progress in deciphering the functional significance of this diversity is hindered by the lack of tools that can distinguish the highly conserved subclasses of actin proteins at the biochemical and cellular level. In order to address the functional diversity of actin isovariants, we have used Arabidopsis recombinant actins as immunogens and produced several new anti-actin monoclonal antibodies. One of them, MAb45a, specifically recognizes two closely related reproductive subclasses of actins. On immunoblots, MAb45a reacts strongly with actins expressed in mature pollen but not with actins in other Arabidopsis tissues. Moreover, immunocytochemical studies show that this antibody can distinguish actin filaments in pollen tubes from those in most vegetative tissues. Peptide competition analyses demonstrate that asparagine at position 79 (Asn79) within an otherwise conserved sequence is essential for MAb45a specificity. Actins with the Asn79 epitope are also expressed in the mature pollen from diverse angiosperms and Ephedra but not from lower gymnosperms, suggesting that this epitope arose in an ancestor common to angiosperms and advanced gymnosperms more than 220 million years ago. During late pollen development in angio- sperms there is a switch in expression of actins from vegetative to predominantly reproductive subclasses, perhaps to fulfil the unique functions of pollen in fertilization.     

Subcellular sorting of isoactins: selective association of gamma actin with skeletal muscle mitochondria

We describe two subpopulations of actin antibodies isolated by affinity chromatography from a polyclonal antibody to chicken gizzard actin. One subpopulation recognizes gamma actins from smooth muscle and nonmuscle cells, but does not recognize alpha actin from skeletal muscle. The other subpopulation recognizes determinants that are common to alpha actin from skeletal muscle and the two gamma actin isotypes. Neither antibody recognizes cytoplasmic beta actin. Both antibodies recognize only actins or molecules with determinants that are also present in actins. By immunofluorescence we found that the anti-gamma actin colocalizes with mitochondria in fibers of mouse diaphragm, and that it does not bind detectably to the 1 bands of sarcomeres. The antibody that recognizes both alpha and gamma actins stains 1 bands intensely, as expected. We interpret these observations as preliminary evidence for selective association of gamma actin with skeletal muscle mitochondria and, more broadly, as evidence for subcellular sorting of isoactins.     

Actin antibodies. Preparation and characterization of antibodies specific for smooth-muscle actin isoforms.

We have determined the specificity of sera elicited by glutaraldehyde-stabilized bovine aortic actin. This modification induces a high titre of antibodies directed against the N-terminal (residues 1-39) and the C-terminal region of smooth-muscle actins. The crude antisera were purified on peptide (corresponding to the 1-9 or 1-8 N-terminal sequences of smooth-muscle isoactins)-polyacrylic-resin columns. By fractionating the antisera we obtained oligoclonal antibody populations specific for each isoactin.     

SVS II--an androgen-dependent actin-binding glycoprotein in rat semen.

Rat seminal vesicles and the lateral prostate secrete a glycoprotein designated as SVS II in an androgen-dependent manner. SVS II, which has a M(r) of 49,000 and a pI of 10.5, is an actin-binding protein. G- and F-actins cosediment with SVS II at a ratio of 2:1 (actin:SVS II). SVS II affects the kinetics of actin polymerization in the same way as do barbed end capping proteins. Interaction with actin is specific for the skeletal and cardiac muscle isoforms and there is no corresponding interaction with cytoplasmic actins. The binding site is close to the C-terminus of actin. Monospecific polyclonal antibodies directed against the N-terminus of actin cross-react with SVS II, but there is no cross-reaction by a monoclonal antibody directed against a C-terminal epitope on actin. Recent sequence analysis of SVS II shows a sequence of about 14 residues that is repeated 13 times between residues 86 and 298. The consensus sequence based on these repeats is homologous to residues 10 to 25 of actin; this may account for the immunological cross-reactivity. Like actin, SVS II binds and inhibits the activity of DNase I, but SVS II has no effect on the ATPase activity of myosin subfragment 1. Thus, SVS II is an actin-binding protein which retains some properties of actin itself.     

Induction by chemically modified actin derivatives of antibody specificity: A relation between modified sites and antibody interactions with monomeric and filamentous actins

A comparison of specific antibodies induced by unfolded actins modified either by oxidation or by arylation of lysine residues was reported. We have focused our work on binding properties with filamentous actin and located its preferential antigenic sites for the anti-arylated-actin antibodies in the C-part of the molecule. An interference of anti-oxidized actin antibodies upon actin polymerisation has also been reported.     

Preparation and characterization of bovine aortic actin.

A functional vascular smooth-muscle actin from bovine aorta was purified to homogeneity by an original method and was able to polymerize. Aortic actin is composed of two major isoforms and at least two minor ones. This actin was not phosphorylated by either cyclic AMP-dependent protein kinase or C kinase. The physical properties of aortic actin were found to be very similar to those of skeletal-muscle actin, except for amino acid composition (three tryptophan residues instead of four). The aortic actin and skeletal-muscle actin differ in the extent of activation of the Mg-dependent ATPase of skeletal-muscle myosin.     

The complete amino acid sequence of actins from bovine aorta, bovine heart, bovine fast skeletal muscle, and rabbit slow skeletal muscle. A protein-chemical analysis of muscle actin differentiation.

Complete amino acid sequences for four mammalian muscle actins are reported: bovine skeletal muscle actin, bovine cardiac actin, the major component of bovine aorta actin, and rabbit slow skeletal muscle actin. The number of different actins in a higher mammal for which full amino acid sequences are now available is therefore increased from two to five. Screening of different smooth muscle tissues revealed in addition to the aorta type actin a second smooth muscle actin, which appears very similar if not identical to chicken gizzard actin. Since the sequence of chicken gizzard actin is known, six different actins are presently characterized in a higher mammal. The two smooth muscle actins--bovine aorta actin and chicken gizzard actin--differ by only three amino acid substitutions, all located in the amino-terminal end. In the rest of their sequences both smooth muscle actins share the same four amino acid substitutions, which distinguish them from skeletal muscle actin. Cardiac muscle actin differs from skeletal muscle actin by only four amino acid exchanges. No amino acid substitutions were found when actins from rabbit fast and slow skeletal muscle were compared. In addition we summarize the amino acid substitution patterns of the six different mammalian actins and discuss their tissue specificity. The results show a very close relationship between the four muscle actins in comparison to the nonmuscle actins. The amino substitution patterns indicate that skeletal muscle actin is the highest differentiated actin form, whereas smooth muscle actins show a noticeably cloer relation to nonmuscle actins. By these criteria cardiac muscle actin lies between skeletal muscle actin and smooth muscle actins.     

Amino-terminal processing of actins mutagenized at the Cys-1 residue.

Most actins examined to date undergo a unique posttranslational modification termed processing, catalyzed by the actin N-acetylaminopeptidase. Processing is the removal of acetylmethionine from the amino terminus in class I actins with Met-Asp(Glu) amino termini. For class II actins with Met-X-Asp(Glu) amino termini, processing is the removal of the second residue as an N-acetylamino acid. Other cytosolic proteins with these amino termini are not processed suggesting that the reaction may be specific for actins. In actin, X is usually cysteine. However, there are some class II actins in which this residue is other than cysteine, suggesting a broader substrate specificity for actin N-acetylaminopeptidase than acetylmethionine or acetylcysteine. We constructed mutant actins in which this cysteine was replaced with serine, asparagine, glycine, aspartic acid, histidine, phenylalanine, and tyrosine and used these to determine the substrate specificity of rat liver actin N-acetylaminopeptidase in vitro. Amino-terminal acetylmethinonine was cleaved from adjacent aspartic acid, asparagine, or histidine, but not serine, glycine, phenylalanine, or tyrosine. Of the acetylated actin amino termini tested, only acetylmethionine and acetylcysteine were cleaved. Histidine was never N-acetylated and was not cleaved. When phenylalanine and tyrosine were adjacent to the initiator methionine, no initiator methionine was cleaved even though it was acetylated. These results suggest a narrow substrate specificity for the rat liver actin N-acetylaminopeptidase. They also demonstrate that the adjacent residue can effect actin N-acetylaminopeptidase specificity.     

Studies on trypanosomatid actin. I. Immunochemical and biochemical identification

In this study, the presence of actin in cultured trypanosomatids was investigated using polyclonal antibodies to heterologous actin. Polyclonal antisera to rabbit muscle actin and a monospecific anti-actin antibody react with a 43-kDa polypeptide in extracts of Trypanosoma cruzi, Herpetomonas samuelpessoai and Leishmania mexicana amazonensis on protein immunoblots. The 43-kDa polypeptide co-migrates with skeletal muscle actin and is retained within trypanosomatid cytoskeletons. Attempts to isolate H. samuelpessoai actin through DNase I affinity chromatography showed that the 43-kDa polypeptide did not bind to the column. Instead, low yields of a 47-kDa polypeptide were obtained indicating that the trypanosomatid actin displays unusual DNase I binding behavior when compared to actins from higher eukaryotes. Immunofluorescence studies confirmed that cytoskeletons retain the actin-like protein. In H. samuelpessoai, actin is localized in the region close to the flagellum, whereas in T. cruzi it is more homogeneously distributed. The data presented here show that trypanosomatid actin displays biochemical characteristics similar to actins of other protozoa.     

Structural Comparisons of Muscle and Nonmuscle Actins Give Insights Into the Evolution of Their Functional Differences

Actin is a highly conserved protein although many isoforms exist. In vertebrates and insects the different actin isoforms can be grouped by their amino acid sequence and tissue-specific gene expression into muscle and nonmuscle actins, suggesting that the different actins may have a functional significance. We ask here whether atomic models for G- and F-actins may help to explain this functional diversity. Using a molecular graphics program we have mapped the few amino acids that differ between isoactins. A small number of residues specific for muscle actins are buried in internal positions and some present a remarkable organization. Within the molecule, the replacements observed between muscle and nonmuscle actins are often accompanied by compensatory changes. The others are dispersed on the protein surface, except for a cluster located at the N-terminus which protrudes outward. Only a few of these residues specific for muscle actins are present in known ligand binding sites except the N-terminus, which has a sequence specific for each isoactin and is directly implicated in the binding to myosin. When we simulated the replacements of side chains of residues specific for muscle actins to those specific for nonmuscle actins, the N-terminus appears to be less compact and more flexible in nonmuscle actins. This would represent the first conformational grounds for proposing that muscle and nonmuscle actins may be functionally distinguishable. The rest of the molecule is very similar or identical in all the actins, except for a possible higher internal flexibility in muscle actins. We propose that muscle actin genes have evolved from genes of nonmuscle actins by substitutions leading to some conformational changes in the protruding N-terminus and the internal dynamics of the main body of the protein. Received: 15 March 1996 / Accepted: 14 July 1996     

Isolation of a minor species of actin from the nuclei of Acanthamoeba castellanii

Actin was extracted from isolated nuclei of Acanthamoeba castellanii and purified to homogeneity under nondenaturing conditions by diethylaminoethylcellulose and Sephadex G-100 chromatography. The pure protein has the same molecular weight as cytoplasmic Acanthamoeba actin and a very similar amino acid composition. Isoelectrofocusing shows that nuclear actin is slightly more acidic than the major cytoplasmic species, and comparative analysis of peptides from tryptic and cyanogen bromide digests shows that both actins are very similar but not chemically identical. In an assay that is specific for most actins, the inhibition of DNase I through the formation of a 1:1 G-actin-DNase I complex, the nuclear and cytoplasmic actins are equally effective. By use of a similar procedure for the purification of both actins, it is estimated that the amount of nuclear actin is about 1.5% of the amount of cytoplasmic actin, a major protein of the amoeba. It is concluded that a minor isoelectric species of actin associates selectively with the nuclei of A. castellanii.     

Immunological characterization of an anti-actin antibody specific for cytoplasmic actins and its use for the immunocytological localization of actin in Aplysia nervous tissue

Previous immunochemical and immunocytochemical studies have shown that an antibody to actin prepared from body wall muscle of the marine mollusc Aplysia californica is specific for vertebrate cytoplasmic actins. The ability of this anti-actin to distinguish between different forms of actin most likely reflects the recognition of amino acid sequences unique to cytoplasmic actins. We have confirmed the specificity of this antibody for cytoplasmic actins using nervous tissue as a source of cytoplasmic actin in further immunochemical studies. In addition to binding cytoplasmic actin in purified preparations, the antibody removed actin selectively from crude extracts of nervous tissue of some but not all of the species tested. Our results also suggest that tissue-specific differences in the distribution of cytoplasmic actins may exist. Immunofluorescence studies of Aplysia nervous tissue stained with anti-actin revealed that actin is present in the cell body and axonal processes of Aplysia neurons. Although the function of actin in nerve cells is not understood, the observed pattern of immunofluorescence staining is consistent with the idea that actin may be involved in movement within the axoplasm.     

Immune response of rabbits to native G-actins

Actins are highly conserved proteins and are therefore claimed to be not very immunogenic without prior denaturation or chemical modification. We have obtained in rabbits high-titered antibodies to "native" G-actins from chicken and man, and assayed their cross-reaction using an enzyme immunoassay, Western blotting and immunohistochemistry. The antigens differ in their ability to induce antibody formation (chicken gizzard actin [(beta), gamma] greater than chicken skeletal actin [alpha] = human platelet actin [beta, (gamma)]). Antibodies to skeletal actin [alpha] are muscle-specific and mainly directed against the homologous region comprising the N-terminus (residues 1-226). Antibodies to gizzard actin [(beta), gamma] cross-react, to a lesser extent, with the alpha and beta, (gamma) isoforms. They show no regional specificity within the homologous antigen. Antibodies to the tryptic core fragment (residues 69-374) of skeletal actin react with fragments comprising the C-terminal part of muscular actins. Antibodies to platelet actin [beta, (gamma)] cross-react with muscular actins, recognizing not the native, but slightly degraded molecules. Platelet actin induces the formation of high-titered albumin antibodies for hitherto unknown reasons.     

Identification of L-cell growth stimulating antibody as anti-actin

Anti-L-cell antisera having potent cell growth stimulatory properties were shown by Western blotting to have predominant specificity toward a protein with a molecular weight of 42K which we identified as actin. Extractions of L cells, based upon the known insolubility of cytoskeletal proteins (including actin) in Triton X-100 and the solubility of actin in low ionic strength Ca2+ and ATP-containing buffer, led to actin-enriched preparations that retained immunoreactivity with the anti-L-cell antisera. The 42-kDa antigen binds to deoxyribonuclease I, has a pI = 5.2-5.4, and has an amino acid composition, including the presence of 3-methylhistidine, compatible with compositions determined for actins from other sources. Rabbit antiserum specific for this 42-kDa protein, isolated by SDS-PAGE, reproduced the cell growth stimulation by the anti-L-cell antisera and absorption of the antiserum with purified L-cell actin eliminated this stimulation. Moreover, these antibodies bind to the microfilaments of 3T3 fibroblasts. When purified actins were used as soluble antigen inhibitors of the immune reactivity of antiserum to 42-kDa protein with intact L cells, rabbit thymus actin competed with the surface molecules on L cells and reduced the stimulatory effect of the antiserum by 80% at an actin concentration of 150 micrograms/ml. Chicken muscle actin reduced the antibody stimulation effect by only 24% at the same protein concentration, and mouse muscle actin was ineffective as an inhibitor. The F(ab')2 fraction of anti-42K IgG was effective in stimulating L cells, thus documenting the immune nature of the actin-anti-42K interaction. We conclude that anti-actin antibodies, upon binding to actin-like cell surface determinants on L cells, stimulate cellular metabolism.     

Studies on Trypanosomatid Actin I. Immunochemical and Biochemical Identification

In this study, the presence of actin in cultured trypanosomatids was investigated using polyclonal antibodies to heterologous actin. Polyclonal antisera to rabbit muscle actin and a monospecific anti-actin antibody react with a 43-kDa polypeptide in extracts of Trypanosoma cruzi, Herpetomonas samuelpessoai and Leishmania mexicana amazonensis on protein immunoblots. The 43-kDa polypeptide co-migrates with skeletal muscle actin and is retained within trypanosomatid cytoskeletons. Attempts to isolate H. samuelpessoai actin through DNase I affinity chromatography showed that the 43-kDa polypeptide did not bind to the column. Instead, low yields of a 47-kDa polypeptide were obtained indicating that the trypanosomatid actin displays unusual DNase I binding behavior when compared to actins from higher eukaryotes. Immunofluorescence studies confirmed that cytoskeletons retain the actin-like protein. In H. samuelpessoai , actin is localized in the region close to the flagellum, whereas in T. cruzi it is more homogeneously distributed. The data presented here show that trypanosomatid actin displays biochemical characteristics similar to actins of other protozoa.