Mapping of a replication origin within the promoter region of two unlinked, abundantly transcribed actin genes of Physarum polycephalum.

We analyzed the replication of two unlinked actin genes, ardB and ardC , which are abundantly transcribed in the naturally synchronous plasmodium of the slime mold Physarum polycephalum. Detection and size measurements of single-stranded nascent replication intermediates (RIs) demonstrate that these two genes are concomitantly replicated at the onset of the 3-h S phase and tightly linked to replication origins. Appearance of RIs on neutral-neutral two-dimensional gels at specific time points in early S phase and analysis of their structure confirmed these results and further established that, in both cases, an efficient, site-specific, bidirectional origin of replication is localized within the promoter region of the gene. We also determined similar elongation rates for the divergent replication forks of the ardC gene replicon. Finally, taking advantage of a restriction fragment length polymorphism, we studied allelic replicons and demonstrate similar localizations and a simultaneous firing of allelic replication origins. Computer search revealed a low level of homology between the promoters of ardB and ardC and, most notably, the absence of DNA sequences similar to the yeast autonomously replicating sequence consensus sequence in these Physarum origin regions. Our results with the ardB and ardC actin genes support the model of early replicating origins located within the promoter regions of abundantly transcribed genes in P. polycephalum.     

The origin and evolution of green algal and plant actins

The Viridiplantae are subdivided into two groups: the Chlorophyta, which includes the Chlorophyceae, Trebouxiophyceae, Ulvophyceae, and Prasinophyceae; and the Streptophyta, which includes the Charophyceae and all land plants. Within the Streptophyta, the actin genes of the angiosperms diverge nearly simultaneously from each other before the separation of monocots and dicots. Previous evolutionary analyses have provided limited insights into the gene duplications that have produced these complex gene families. We address the origin and diversification of land plant actin genes by studying the phylogeny of actins within the green algae, ferns, and fern allies. Partial genomic sequences or cDNAs encoding actin were characterized from Cosmarium botrytis (Zygnematales), Selaginella apoda (Selaginellales), Anemia phyllitidis (Polypodiales), and Psilotum triquetrum (Psilotales). Selaginella contains at least two actin genes. One sequence (Ac2) diverges within a group of fern sequences that also includes the Psilotum Ac1 actin gene and one gymnosperm sequence (Cycas revoluta Cyc3). This clade is positioned outside of the angiosperm actin gene radiation. The second Selaginella sequence (Ac1) is the sister to all remaining land plant actin sequences, although the internal branches in this portion of the tree are very short. Use of complete actin-coding regions in phylogenetic analyses provides support for the separation of angiosperm actins into two classes. N-terminal "signature" sequence analyses support these groupings. One class (VEG) includes actin genes that are often expressed in vegetative structures. The second class (REP) includes actin genes that trace their ancestry within the vegetative actins and contains members that are largely expressed in reproductive structures. Analysis of intron positions within actin genes shows that sequences from both Selaginella and Cosmarium contain the conserved 20-3, 152-1, and 356-3 introns found in many members of the Streptophyta. In addition, the Cosmarium actin gene contains a novel intron at position 76-1.     

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.     

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.     

谷子肌动蛋白基因的克隆及序列分析

以谷子 (Setariaitalica)为材料 ,提取总RNA。根据植物肌动蛋白基因编码区的两端的保守序列设计了简并引物 ,用 5’RACE方法扩增出了谷子肌动蛋白基因编码区序列。以豌豆肌动蛋白cDNA作探针进行的Southern杂交分析表明扩增出了目的基因。将所获得的片段克隆到T载体后进行测序 ,序列分析结果表明 :谷子肌动蛋白基因的编码区长 1 1 3 1个核苷酸 ,编码了 3 77个氨基酸 ;所得序列 (命名为MIAc)与GenBank中注册的肌动蛋白基因序列的相似性均在 6 0 %以上 ,与其它肌动蛋白氨基酸序列的相似性达 89%以上。根据高等植物肌动蛋白序列相似性重建了进化树 ,表明谷子肌动蛋白与水稻肌动蛋白异型体RAc2和RAc3之间的亲缘关系最为密切 ,在进化过程中分化时间最为接近     

谷子肌动蛋白基因的克隆及序列分析

以谷子（Setaria italica）为材料,提取总RNA。根据植物肌动蛋白基因编码区的两端的保守序列设计了简并引物,用5'RACE方法扩增出了谷子肌动蛋白基因编码区序列。以豌豆肌动蛋白cDNA作探针进行的Southern杂交分析表明扩增出了目的基因。将所获得的片段克隆到T载体后进行测序,序列分析结果表明：谷子肌动蛋白基因的编码区长1131个核苷酸,编码了377个氨基酸;所得序列(命名为MIAc)与GenBank中注册的肌动蛋白基因序列的相似性均在60%以上,与其它肌动蛋白氨基酸序列的相似性达89%以上。根据高等植物肌动蛋白序列相似性重建了进化树,表明谷子肌动蛋白与水稻肌动蛋白异型体RAc2和RAc3之间的亲缘关系 最为密切,在进化过程中分化时间最为接近。     

Nucleotide sequence of an actin-encoding gene from Hydra attenuata: structural characteristics and evolutionary implications

We have determined the complete nucleotide sequence of an actin-encoding gene from Hydra attenuata as well as partial sequences of cDNA clones from two additional actin-encoding genes. The gene from the genomic clone contains a single intron, and has promoter and polyadenylation signals similar to those found in other species. The hydra genome has a very A + T-rich base composition (71%). This is reflected in the codon usage of the actin-encoding genes, which is strongly biased towards codons having A or T in the third position. The hydra actin-encoding gene family consists of three or more transcribed genes, two of which are very closely related to each other and probably arose by a recent gene duplication. Hydra actin, like other invertebrate actins, is more similar to the non-muscle isotypes of vertebrates than to the vertebrate muscle actins. Hydra actin is more similar to animal actins than to those of plants or fungi, which is consistent with the view that all metazoans arose from a single protist ancestor.     

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.     

Sea urchin actin gene subtypes. Gene number, linkage and evolution

The actin gene family of the sea urchin Strongylocentrotus purpuratus was analyzed by the genome blot method, using subcloned probes specific to the 3' terminal non-translated actin gene sequence, intervening sequence and coding region probes. We define an actin gene subtype as that gene or set of genes displaying homology with a given 3' terminal sequence probe, when hybridized at 55 degrees C, 0.75 M-Na+. By determining the often polymorphic restriction fragment band pattern displayed in genome blots by each probe, all, or almost all of the actin genes in this species could be classified. Our evidence shows that the S. purpuratus genome probably contains seven to eight actin genes, and these can be assigned to four subtypes. Studies of the expression of the genes (Shott et al., 1983) show that the actin genes of three of these subtypes code for cytoskeletal actins (Cy), while the fourth gives rise to a muscle-specific actin (M). We denote the array of S. purpuratus actin genes indicated by our data as follows. There is a single CyI actin gene, two or possibly three CyII genes (CyIIa, CyIIb, and possibly CyIIc), three CyIII actin genes (CyIIIa, CyIIIb, CyIIIc), and a single M actin gene. Comparative studies were carried out on the actin gene families of five other sea urchin species. At least the CyIIa and CyIIb genes are also linked in the Strongylocentrotus franciscanus genome, and this species also has a CyI gene, an M actin gene and at least two CyIII actin genes. It is not clear whether it also possesses a CyIIc actin gene, or a CyIIIc actin gene. The genome of a more closely related congener, Strongylocentrotus dr?bachiensis, includes 3' terminal sequences suggesting the presence of a CyIIc gene. In S. franciscanus and S. dr?bachiensis the first intron of the CyI gene has remained homologous with intron sequences of both the CyIIa and CyIIb genes, indicating a common origin of these three linked cytoskeletal actin genes. Of the four S. purpuratus 3' terminal subtype probe sequences only the CyI 3' terminal sequence has been conserved sufficiently during evolution to permit detection outside of the genus Strongylocentrotus. An unexpected observation was that a sequence found only in the 3' untranslated region of the CyII actin gene in the DNA of S. dr?bachiensis and S. purpuratus is represented as a large family of interspersed repeat sequences in the genome of S. franciscanus.     

A complex gene superfamily encodes actin in petunia.

We have shown by several independent criteria that actin is encoded by a very large and complex superfamily of genes in Petunia. Several cDNA and genomic probes encoding actins from diverse organisms (Dictyostelium, Drosophila, chicken and soybean) hybridize to hundreds of restriction fragments in the petunia genome. Actin-hybridizing sequences were isolated from a petunia genomic library at a rate of at least 200 per genome equivalent. Twenty randomly selected actin-hybridizing clones were characterized in more detail. DNA sequence data from four representative and highly divergent clones, PAc2, PAc3, PAc4 and PAc7, demonstrate that these actin-like sequences are related to functional actin genes. Intron positions typical of other known plant actin genes are conserved in these clones. Four of six clones analyzed (PAc1, PAc2, PAc3, PAc4) hybridize to leaf mRNA of the same size (1.7 kb) as that reported for other plant actin mRNAs and to a slightly smaller mRNA species (1.5 kb). Five distinct subfamilies of actin-related genes were characterized which varied in size from a few members to several dozen members. It is clear from our data that other actin gene subfamilies must also exist within the genome. Possible mechanisms of actin gene amplification and genome turnover are discussed.     

Organization of the actin multigene family of Dictyostelium discoideum and analysis of variability in the protein coding regions

There are 17 to 20 actin genes in the genome of the cellular slime mold Dictyostelium discoideum. Genomic clones of 15 of the genes have been isolated. Extensive nucleotide sequence within the protein-coding regions has been determined, including the complete nucleotide sequence of four genes representing the three distinct evolutionary groups of Dictyostelium actin genes. All are similar to mammalian cytoplasmic actins at diagnostic amino acid positions, and there is generally less variability among Dictyostelium actin genes than among Drosophila actin genes. Two genes, Actins 3-sub 1 and 3-sub 2 differ substantially from all the rest in terms of replacement amino acid substitutions and probably encode actin-related proteins rather than bona fide actins. Each contains several amino acid substitutions that should alter the secondary structure of the resulting proteins, and Actin 3-sub 2 encodes four additional amino acids at the C terminus. This gene is as divergent from other Dictyostelium actin genes as is the yeast or a soybean actin gene. At present, evidence suggests that all 15 genes examined are expressed, except the previously identified Actin 2-sub 2. We suggest that Dictyostelium might maintain a high number of functional actin genes for the purpose of regulating the level of actin synthesis within narrow limits, rather than because most genes perform different functions.     

Insect muscle actins differ distinctly from invertebrate and vertebrate cytoplasmic actins

Summary Invertebrate actins resemble vertebrate cytoplasmic actins, and the distinction between muscle and cytoplasmic actins in invertebrates is not well established as for vertebrate actins. However, Bombyx and Drosophila have actin genes specifically expressed in muscles. To investigate if the distinction between muscle and cytoplasmic actins evidenced by gene expression analysis is related to the sequence of corresponding genes, we compare the sequences of actin genes of these two insect species and of other Metazoa. We find that insect muscle actins form a family of related proteins characterized by about 10 muscle-specific amino acids. Insect muscle actins have clearly diverged from cytoplasmic actins and form a monophyletic group emerging from a cluster of closely related proteins including insect and vertebrate cytoplasmic actins and actins of mollusc, cestode, and nematode. We propose that muscle-specific actin genes have appeared independently at least twice during the evolution of animals: insect muscle actin genes have emerged from an ancestral cytoplasmic actin gene within the arthropod phylum, whereas vertebrate muscle actin genes evolved within the chordate lineage as previously described.Offprint requests to.: N. Mounier     

Molecular characterization of mutant actin genes which induce heat-shock proteins in Drosophila flight muscles

Heat-shock proteins (hsps) are constitutively induced by the mutant actins in the Drosophila indirect flight muscles (IFM). We compared primary structures of the mutant actin genes (KM75 and HH5) which induce hsps and of the non-inducing alleles (KM129 and KM88). The KM75 actin has lost 20 amino acids at the C-terminus. The HH5 actin has only one amino acid substitution, from Gly-336 to Ser. In KM129, the C-terminal part of actin is replaced by novel amino acids. KM88 is a null allele, with an amber mutation early in the coding region of the mutated actin gene. Although all of the KM75, HH5 and KM129 actins have defects near the C-terminus, only hsp-inducing mutant actins cause enlargement of the IFM nuclei as well as a disruption of myofibrils even in the presence of two copies of the normal genes. We further consider the underlying mechanisms linking these features of the hsp-inducing alleles.     

The Complete Amino Acid Sequence of Actins from Bovine Aorta, Bovine Heart, Bovine Fast Skeletal Muscle, and Rabbit, Slow Skeletal Muscle

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 closer relation to nonmuscle actins. By these criteria cardiac muscle actin lies between skeletal muscle actin and smooth muscle actins.