Correct NH2-terminal processing of cardiac muscle alpha-isoactin (class II) in a nonmuscle mouse cell

Both mammalian nonmuscle and muscle actins possess an AcAsp(Glu)NH2 terminus. The nonmuscle actin genes code for a polypeptide with a Met-Asp NH2 terminus (class I) whereas the muscle actin genes code for a polypeptide with a Met-Cys-Asp NH2 terminus (class II). Two amino acids must be removed for mature muscle actin synthesis, whereas only the Met must be removed for nonmuscle actin synthesis. We wished to know whether a nonmuscle cell which normally does not synthesize a class I actin can correctly process a muscle actin with its extra NH2-terminal amino acid in vivo. To answer this question we have used L/LK165 cells, a mouse L-cell transfected with a human cardiac muscle actin gene. When these cells were labeled overnight with [35S]Cys, an actin with an NH2-terminal tryptic peptide corresponding to that of mature cardiac muscle actin was detected. When the cells were pulse-labeled for 20 min, a new actin intermediate containing an AcCys-Asp amino terminus was observed which then disappeared with time. Furthermore, the muscle actin was processed as fast if not faster than the nonmuscle actin in these cells. This actin intermediate was also seen in chick myotube cultures. Our results show that the ability to correctly process muscle specific actins is not tissue specific. Furthermore, these results confirm a processing pathway for class II actins proposed by us earlier on the basis of experiments with a cell-free translation system.     

Unusual metabolism of the yeast actin amino terminus

In this paper we have examined the post-translational modifications of the NH2 terminus of actin from the yeast Saccharomyces cerevisiae. Like actins examined previously, this actin contains an acetylated NH2 terminus. Actins in other organisms undergo a unique post-translational processing event in which the initial amino acid(s) are removed by an actin-specific processing enzyme in an acetylation-dependent reaction. This is defined as actin processing. In yeast, actin retains its initiator Met in vivo and is thus not processed even though a rat liver actin processing enzyme can process yeast actin in vitro. This lack of actin processing appears to be a general property of fungi, as the actin from three other species, Aspergillus nidulans, Schizosaccharomyces pombe, and Candida albicans are not NH2 terminally processed either. Yeast actin is a class I actin; its initiator Met directly precedes an acidic residue. We converted yeast actin to a class II species by inserting a Cys codon between the Met-1 and Asp-2 codons. In normal class II actins the Cys residue is removed as acetyl-Cys during processing. Neither the mutant actin nor chick beta-actin (a class I actin) are processed when expressed in yeast. S. cerevisiae thus appears to be also incapable of processing exogenous actins. Further study of the mutant actin containing a Cys at position 2 shows that 30-40% of this actin is stably unacetylated. This unacetylated actin does not have a shorter half-life than the acetylated form. From these studies we conclude that 1) NH2-terminal actin-specific processing is not required for actin function in yeast and three other fungi, 2) yeast are apparently incapable of processing any type of actin precursor, and 3) the stability of a yeast pseudo-class II actin is not affected by the acetylation state of the NH2 terminus.     

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.     

NH2-terminal processing of Drosophila melanogaster actin. Sequential removal of two amino acids

Class II actins, such as Drosophila and mammalian skeletal muscle actins, have genes that code for a Met-X-Asp NH2 terminus where X is usually cysteine. These actins have an Ac-Asp NH2 terminus so two amino acids must be removed. To determine the nature of this processing, we labeled Drosophila Schneider L-2 cells with [35S]methionine or cysteine, isolated the actin, and analyzed the NH2-terminal actin tryptic peptides and their thermolysin digestion products. After a 4-h labeling period, we detected completed actin polypeptide chains with either an unblocked Asp or an Ac-Asp NH2 terminus. No intermediate with an NH2-terminal Cys or Met could be demonstrated. If, however, Drosophila mRNA was translated in a mRNA-dependent rabbit reticulocyte lysate system, an additional 43-kDa actin intermediate was observed. On the basis of thermolysin digestion studies and experiments using mild acid hydrolysis of a labeled actin NH2-terminal tryptic peptide fragment, we identified this intermediate as having an Ac-Cys-Asp NH2 terminus. In a time-dependent fashion, Ac-Cys was removed generating actin with an exposed NH2-terminal Asp which was subsequently acetylated to produce the mature form of actin. The removal of Met and the acetylation of Cys may occur early in translation while the nascent polypeptide chain is still attached to the ribosome. Subsequent processing occurs following completion of the synthesis of the actin polypeptide. The removal of Ac-Cys from Drosophila actin is thus similar to removal of Ac-Met from the NH2 terminus of class I actins although in the case of the class II actins, it is the second amino acid that is removed as an acetylated species.     

Alternate pathways for removal of the class II actin initiator methionine

Class II actin genes usually specify a polypeptide with a Met-Cys-Asp NH2 terminus, whereas the actin itself begins with an acetyl (Ac)-Asp(Glu). Previous studies with Drosophila actin showed that the first detectable intermediate is one with an Ac-Cys NH2 terminus which is subsequently cleaved in a novel reaction to expose the Asp. The initiator Met was probably removed early in translation as a free amino acid. To determine whether the class II actin initiating Met could also be removed in an acetylation-dependent manner, we translated Drosophila mRNA in a rabbit reticulocyte lysate in which protein acetylation was inhibited. After 60 min, three actin intermediates were detected, NH2-Met-Cys-Asp-actin, Ac-Met-Cys-Asp-actin, and NH2-Cys-Asp-actin. During processing in the presence of acetyl-CoA, three additional species were observed with NH2-terminal Ac-Cys-Asp, NH2-Asp, and Ac-Asp segments. In a time- and acetyl-CoA-dependent fashion, Met-Cys-Asp-actin was processed to the mature actin, presumably through an Ac-Met-Cys-Asp intermediate. Thus, two different pathways for removal of the initiator Met of class II actins, acetylation-dependent and independent, are possible. Since no class II actin intermediate containing the initiator Met is seen in vivo, although in class I actins this intermediate is observed, the most probable pathway for class II actins in vivo is the cotranslational removal of the initiator Met as a free amino acid.     

Post-translational processing of the amino terminus affects actin function

We have studied the importance of N-terminal processing for normal actin function using the Drosophila Act88F actin gene transcribed and translated in vitro. Despite having different charges as determined by two-dimensional (2D) gel electrophoresis, Act88F expressed in vivo and in vitro in rabbit reticulocyte lysate bind to DNase I with equal affinity and are able to copolymerise with bulk rabbit actin equally well. Using peptide mapping and thin-layer electrophoresis we have shown that bestatin [( 3-amino-2-hydroxy-4-phenyl-butanoyl]-L-leucine), an inhibitor of aminopeptidases, can inhibit actin N-terminal processing in rabbit reticulocyte lysate. Although processed and unprocessed actins translated in vitro are able to bind to DNase I equally well, unprocessed actins are less able to copolymerise with bulk actins. This effect is more pronounced when bulk rabbit actin is used but is still seen with bulk Lethocerus actin. Also, the unprocessed actins reduce the polymerisation of the processed actin translated in vitro with the bulk rabbit actin. This suggests that individual actins do interact, even in non-polymerising conditions. The reduced ability of unprocessed actin to polymerise shows that correct post-translational modification of the N terminus is required for normal actin function.     

Drosophila ACT88F indirect flight muscle-specific actin is not N-terminally acetylated: a mutation in N-terminal processing affects actin function

Many eukaryotic proteins are co and post-translationally modified at their N termini by removal of one or two amino acid residues and N(alpha)-acetylation. Actins show two different forms of N-terminal processing dependent on their N-terminal sequence. In class II actins, which include muscle actins, the common primary sequence of Met-Cys-Asp-actin is processed to acetyl-Asp-actin. The functional significance of this in vivo is unknown. We have studied the indirect flight muscle-specific actin, ACT88F, of Drosophila melanogaster. Our results show that ACT88F is N-terminally processed in vivo as a class II actin by removal of the first two amino acid residues (Met and Cys), but that uniquely the N terminus is not acetylated. In addition we show that ACT88F is methylated, probably at His73.Flies carrying the mod(-) mutation fail to complete post-translational processing of ACT88F. We propose that the mod gene product is normally responsible for removing N-acetyl-cysteine from actin. The biological significance of this process is demonstrated by observations that retention of the N-acetyl-cysteine in ACT88F affects the flight muscle function of mod(-) flies. This suggests that the extreme N terminus affects actomyosin interactions in vivo, a proposal we have examined by in vitro motility assays of ACT88F F-actin from mod(-) flies. The mod(-) actin only moves in the presence of methylcellulose, a viscosity-enhancing agent, where it moves at velocities slightly, but significantly, reduced compared to wild-type. These data confirm that N-acetyl-cysteine at the N terminus affects actomyosin interactions, probably by reducing formation of the initial actomyosin collision complex, a process known to involve the actin N terminus.     

Studies on the role of actin's N tau-methylhistidine using oligodeoxynucleotide-directed site-specific mutagenesis

The primary structure of all actins except that isolated from Naegleria gruberi contains a unique N tau-methylhistidine (MeHis) at position 73. This modified residue has been implicated as possibly being important for the post-translational processing of actin's amino terminus, the binding of actin to DNase I, and in the polymerization of G-actin. We have investigated the potential role of MeHis in each of these processes by utilizing site-directed mutagenesis to change His-73 of skeletal muscle actin to Arg and Tyr. Wild type and mutant actins were synthesized in vivo, using non-muscle cells transfected with mutant cDNAs, and in vitro by translating mutant RNAs synthesized using SP6 RNA polymerase in a rabbit reticulocyte lysate. We have found that actins containing Arg or Tyr at position 73 undergo amino-terminal processing, bind to DNase I-agarose, and become incorporated into the cytoskeleton of a nonmuscle cell as efficiently as wild type actin. Furthermore, using an in vitro copolymerization assay we have found that although there is no difference between the Arg mutant and the wild type actins, the Tyr mutant has a slightly greater critical concentration for polymerization. These results show that MeHis is not absolutely required for any of these processes.     

Structural Differences Explain Diverse Functions of Plasmodium Actins

Actins are highly conserved proteins and key players in central processes in all eukaryotic cells. The two actins of the malaria parasite are among the most divergent eukaryotic actins and also differ from each other more than isoforms in any other species. Microfilaments have not been directly observed in Plasmodium and are presumed to be short and highly dynamic. We show that actin I cannot complement actin II in male gametogenesis, suggesting critical structural differences. Cryo-EM reveals that Plasmodium actin I has a unique filament structure, whereas actin II filaments resemble canonical F-actin. Both Plasmodium actins hydrolyze ATP more efficiently than α-actin, and unlike any other actin, both parasite actins rapidly form short oligomers induced by ADP. Crystal structures of both isoforms pinpoint several structural changes in the monomers causing the unique polymerization properties. Inserting the canonical D-loop to Plasmodium actin I leads to the formation of long filaments in vitro. In vivo, this chimera restores gametogenesis in parasites lacking actin II, suggesting that stable filaments are required for exflagellation. Together, these data underline the divergence of eukaryotic actins and demonstrate how structural differences in the monomers translate into filaments with different properties, implying that even eukaryotic actins have faced different evolutionary pressures and followed different paths for developing their polymerization properties.     

Mutational screen identifies critical amino acid residues of beta-actin mediating interaction between its folding intermediates and eukaryotic cytosolic chaperonin CCT

The three-dimensional reconstruction of apo-CCT-alpha-actin by cryoelectron microscopy shows that actin binds either the CCTbeta-CCTdelta or the CCTepsilon-CCTdelta subunit pairs of the chaperonin in an open and apparently quasi-native conformation. The CCT-binding sites are seen located at the tips of the two arms of actin and these same regions of actin have been implicated in CCT binding through beta-actin peptide-array screening. Three main CCT binding regions exist: actin Sites I, II, and III, which are composed of loops that are surface-exposed in native actin. Sixty-eight amino acid residues on beta-actin have been screened by mutagenesis for effects on CCT interaction in quantitative in vitro translation assays in rabbit reticulocyte lysate. Actin seems to be folding cooperatively on chaperonin, since certain mutants discriminate CCT binding from processing. Actin Site II, located at the tip of actin subdomain 4, is the major determinant for CCT binding. Site II is composed of two anti-parallel extended beta-strands, with F200-T203 and D244 contributing substantially to the binding site. The substrate recognition chemistry of CCT thus seems different from that of Group I chaperonins and probably reflects the fact that it needs to be highly specific to enable capture and folding of the actins and tubulins.     

The binding of mutant actins to profilin, ATP and DNase I.

Twenty-five mutations were created in the Drosophila melanogaster Act88F actin gene by in vitro mutagenesis and the mutant actins expressed in vitro. The affinity of the mutant actins for ATP, profilin and DNase I was determined. They were also tested for conformational changes by non-denaturing gel electrophoresis. Mutations at positions 364 (highly conserved) and 366 (invariant) caused changes in conformation, reduced ATP binding and increased profilin binding. At position 362 (invariant) only the conservative change from tyrosine to phenylalanine had no effect; other changes at this position affected conformation, ATP and profilin binding. Although only glycine or serine occur naturally at position 368, changes to threonine or glutamine had no effect on the actin. The mutant in which Asp363 was replaced by His and that in which Glu364 was replaced by Lys decreased DNase I binding, yet neither amino acid occurs in the DNase I binding site. Likewise several mutations affect ATP and profilin binding but are distant from the binding sites. We conclude that, although actin has a highly conserved amino acid sequence, individual amino acids can have variable tolerance for substitutions. Also amino acid changes can exert significant effects on the binding of ligands to distant parts of the actin structure.     

The Molecular Evolution of Actin

We have investigated the molecular evolution of plant and nonplant actin genes comparing nucleotide and amino acid sequences of 20 actin genes. Nucleotide changes resulting in amino acid substitutions (replacement substitutions) ranged from 3-7% for all pairwise comparisons of animal actin genes with the following exceptions. Comparisons between higher animal muscle actin gene sequences and comparisons between higher animal cytoplasmic actin gene sequences indicated less than 3% divergence. Comparisons between plant and nonplant actin genes revealed, with two exceptions, 11-15% replacement substitution. In the analysis of plant actins, replacement substitution between soybean actin genes SAc1, SAc3, SAc4 and maize actin gene MAc1 ranged from 8-10%, whereas these members within the soybean actin gene family ranged from 6-9% replacement substitution. The rate of sequence divergence of plant actin sequences appears to be similar to that observed for animal actins. Furthermore, these and other data suggest that the plant actin gene family is ancient and that the families of soybean and maize actin genes have diverged from a single common ancestral plant actin gene that originated long before the divergence of monocots and dicots. The soybean actin multigene family encodes at least three classes of actin. These classes each contain a pair of actin genes that have been designated kappa (SAc1, SAc6), lambda (SAc2, SAc4) and mu (SAc3, SAc7). The three classes of soybean actin are more divergent in nucleotide sequence from one another than higher animal cytoplasmic actin is divergent from muscle actin. The location and distribution of amino acid changes were compared between actin proteins from all sources. A comparison of the hydropathy of all actin sequences, except from Oxytricha, indicated a strong similarity in hydropathic character between all plant and nonplant actins despite the greater number of replacement substitutions in plant actins. These protein sequence comparisons are discussed with respect to the demonstrated and implicated roles of actin in plants and animals, as well as the tissue-specific expression of actin.     

Molecular cloning and expression of four actin isoforms during Artemia development.

Four cDNA clones coding for different Artemia actin isoforms have been isolated. Three of the clones contain the complete coding sequences while the fourth one lacks 145 bases, coding for the 49 amino terminal amino acids of the protein. The amino acid sequences predicted for the four actin isoforms identified are highly homologous to insect actins as well as to vertebrate cytoplasmic actins. The four identified cDNA clones code for mRNAs of 5.2, 1.9, 1.6 and 1.8 kb, respectively, whose expression is regulated during development. Three of the actin mRNAs are present in cryptobiotic embryos while the other is not. The steady-state levels of all four mRNAs increase during development to reach maximal levels by 10-15 hours of development and decrease thereafter. The total number of actin genes encoded in the Artemia genome has been estimated as 8 to 10 by Southern analysis of total DNA.     

Structure and Evolution of the Actin Gene Family in Arabidopsis Thaliana

Higher plants contain families of actin-encoding genes that are divergent and differentially expressed. Progress in understanding the functions and evolution of plant actins has been hindered by the large size of the actin gene families. In this study, we characterized the structure and evolution of the actin gene family in Arabidopsis thaliana. DNA blot analyses with gene-specific probes suggested that all 10 of the Arabidopsis actin gene family members have been isolated and established that Arabidopsis has a much simpler actin gene family than other plants that have been examined. Phylogenetic analyses suggested that the Arabidopsis gene family contains at least two ancient classes of genes that diverged early in land plant evolution and may have separated vegetative from reproductive actins. Subsequent divergence produced a total of six distinct subclasses of actin, and five showed a distinct pattern of tissue specific expression. The concordance of expression patterns with the phylogenetic structure is discussed. These subclasses appear to be evolving independently, as no evidence of gene conversion was found. The Arabidopsis actin proteins have an unusually large number of nonconservative amino acid substitutions, which mapped to the surface of the actin molecule, and should effect protein-protein interactions.     

Glutamate receptor subtypes evidenced by differences in desensitization and dependence on the GLR3.3 and GLR3.4 genes

Ionotropic glutamate (Glu) receptors in the central nervous system of animals are tetrameric ion channels that conduct cations across neuronal membranes upon binding Glu or another agonist. Plants possess homologous molecules encoded by GLR genes. Previous studies of Arabidopsis thaliana root cells showed that the amino acids alanine (Ala), asparagine (Asn), cysteine (Cys), Glu, glycine (Gly), and serine trigger transient Ca(2+) influx and membrane depolarization by a mechanism that depends on the GLR3.3 gene. This study of hypocotyl cells demonstrates that these six effective amino acids are not equivalent agonists. Instead, they grouped into hierarchical classes based on their ability to desensitize the response mechanism. Sequential treatment with two different amino acids separated by a washout phase demonstrated that Glu desensitized the depolarization mechanism to Gly, but Gly did not desensitize the mechanism to Glu. All 36 possible pairs of agonists were tested to characterize the desensitization hierarchy. The results could be explained by a model in which one class of channels contained a subunit that was activated and therefore desensitized only by Glu, while a second class could be activated and desensitized by Ala, Cys, Glu, or Gly. A third class could be activated and desensitized by any of the six effective amino acids. Analysis of knockout mutants indicated that GLR3.3 was a required component of all three classes of channels, while the related GLR3.4 molecule specifically affected only two of the classes. The resulting model is an important step toward understanding the biological roles of these enigmatic ion channels.     

Removal of the amino-terminal acidic residues of yeast actin. Studies in vitro and in vivo.

We have examined the role of the acidic residues Asp2 and Glu4 at the NH2 terminus of Saccharomyces cerevisiae actin through site-directed mutagenesis. In DNEQ actin, these residues have been changed to Asn2 and Gln4, whereas in delta DSE actin, the Asp2-Ser-Glu tripeptide has been deleted. Both mutant actins can replace wild type yeast actin. Peptide mapping studies reveal that DNEQ, like wild type actin, retains the initiator Met and is NH2 terminally acetylated, whereas delta DSE has a free NH2 terminus and has lost the initiator Met. Interestingly, microscopic examination of filaments of these two actins reveal the appearance of bundled filaments. The DNEQ bundles are smaller and more ordered, whereas the delta DSE bundles are larger and more loosely organized. Additionally, both mutant actins activate the ATPase activity of rabbit muscle myosin S1 fragment to a lesser extent than wild type. We have also developed a sensitive assay for actin function in vivo that enabled us to detect a slight defect in the ability of these mutant actins to support secretion, an important function in yeast. Thus, although the mutant actins resulted in no gross phenotypic changes, we were able to detect a defect in actin function through this assay. From these studies we can conclude that 1) although NH2-terminal negative charges are not essential to yeast life, the loss of such charges does result in a slight defect in the actins' ability to support secretion, 2) removal of the NH2-terminal negative charges promotes the bundling of actin filaments, and 3) actins lacking NH2-terminal negative charges are unable to activate the myosin S1 ATPase activity as well as wild type actin.     

Actin of Histriculus cavicola: characteristics of the highly divergent hypotrich ciliate actins.

A macronuclear gene-sized molecule carrying an actin gene from the hypotrich ciliate, Histriculus cavicola, was characterized. Southern blot analysis using a coding region probe suggested that actin in H. cavicola is encoded by a single gene. A comparison of the promoter regions indicated that the H. cavicola actin gene has a TATA box in the 5' flanking region in a position identical to those in other oxytrich ciliates. The coding sequence of this gene is not interrupted by any introns, and codes for a protein of 375 amino acid residues. This protein shares a high degree of similarity with other oxytrichid actins, and a relatively low similarity with actins from other eukaryotes. Comparative analyses of sequences indicated that most of the amino acid substitutions in hypotrich actins are found in surface loops, while the core structures are well-conserved. The sites that interact with DNase I and several regions involved in actin-actin contact have diverged considerably in hypotrich actins, while nucleotide-binding sites are the best-conserved interaction motif.     

The actin genes of Drosophila: protein coding regions are highly conserved but intron positions are not

The entire set of six closely related Drosophila actin genes was isolated using recombinant DNA methodology, and the structures of the respective coding regions were characterized by gene mapping techniques and by nucleotide sequencing of selected portions. Structural comparisons of these genes have resulted in several unexpected findings. Most striking is the nonconservation of the positions of intervening sequences within the protein-encoding regions of these genes. One of the Drosophila actin genes, DmA4, is split within a glycine codon at position 13; none of the remaining five genes is interrupted in the analogous position. Another gene, DmA6, is split within a glycine codon at position 307; at least two of the Drosophila actin genes are not split in the analogous position. Additionally, none of the Drosophila actin genes is split within codon four, where the yeast actin gene is interrupted. The six Drosophila actin genes encode several different proteins, but the amino acid sequence of each is similar to that of vertebrate cytoplasmic actins. None of the genes encodes a protein comparable in primary sequence to vertebrate skeletal muscle actin. Surprisingly, in each of these derived actin amino acid sequences in the initiator methionine is directly followed by a cysteine residue, which in turn precedes the string of three acidic amino acids characteristic of the amino termini of mature vertebrate cytoplasmic actins. We discuss these findings in the context of actin gene evolution and function.     

Amino acid sequence of Acanthamoeba actin

By amino acid sequence studies, only one form of cytoplasmic actin was detected in Acanthamoeba castellanii. Its amino acid sequence is very similar to the sequences of Dictyostelium and Physarum actins, from which Acanthamoeba actin differs in only nine and seven residues, respectively, including the deletion of the first residue. Acanthamoeba actin is unique in containing a blocked NH2-terminal neutral amino acid (glycine), while all other actins sequenced thus far have a blocked acidic amino acid (aspartic or glutamic) at the NH2 terminus. Acanthamoeba actin is also unique in that it contains an N epsilon-trimethyllysine residue at position 326. Like other actins, Acanthamoeba actin contains an NT-methylhistidine residue at position 73. The protein sequence is in complete agreement with the sequence derived from the nucleotide sequence of an expressed actin gene.     

Correlation between polymerizability and conformation in scallop beta-like actin and rabbit skeletal muscle alpha-actin.

In order to investigate the structural basis for functional differences among actin isoforms, we have compared the polymerization properties and conformations of scallop adductor muscle beta-like actin and rabbit skeletal muscle alpha-actin. Polymerization of scallop Ca(2+)-actin was slower than that of skeletal muscle Ca(2+)-actin. Cleavage of the actin polypeptide chain between Gly-42 and Val-43 with Escherichia coli protease ECP 32 impaired the polymerization of scallop Mg(2+)-actin to a greater extent than skeletal muscle Mg(2+)-actin. When monomeric scallop and skeletal muscle Ca(2+)-actins were subjected to limited proteolysis with trypsin, subtilisin, or ECP 32, no differences in the conformation of actin subdomain 2 were detected. At the same time, local differences in the conformations of scallop and skeletal muscle actin subdomains 1 were revealed as intrinsic fluorescence differences. Replacement of tightly bound Ca(2+) with Mg(2+) resulted in more extensive proteolysis of segment 61-69 of scallop actin than in the case of skeletal muscle actin. Furthermore, segment 61-69 was more accessible to proteolysis with subtilisin in polymerized scallop Ca(2+)-actin than in polymerized skeletal muscle Ca(2+)-actin, indicating that, in the polymeric form, the nucleotide-containing cleft is in a more open conformation in beta-like scallop actin than in skeletal muscle alpha-actin. We suggest that this difference between scallop and skeletal muscle actins is due to a less efficient shift of scallop actin subdomain 2 to the position it has in the polymer. The possible consequences of amino acid substitutions in actin subdomain 1 in the allosteric regulation of the actin cleft, and hence in the different stabilities of polymers formed by different actins, are discussed.