Isolation and characterization of six different chicken actin genes.

Genes representing six different actin isoforms were isolated from a chicken genomic library. Cloned actin cDNAs as well as tissue-specific mRNAs enriched in different actin species were used as hybridization probes to group individual actin genomic clones by their relative thermal stability. Restriction maps showed that these actin genes were derived from separate and nonoverlapping regions of genomic DNA. Of the six isolated genes, five included sequences from both the 5' and 3' ends of the actin-coding area. Amino acid sequence analysis from both the NH2- and COOH-terminal regions provided for the unequivocal identification of these genes. The striated isoforms were represented by the isolated alpha-skeletal, alpha-cardiac, and alpha-smooth muscle actin genes. The nonmuscle isoforms included the beta-cytoplasmic actin gene and an actin gene fragment which lacked the 5' coding and flanking sequence; presumably, this region of DNA was removed from this gene during construction of the genomic library. Unexpectedly, a third nonmuscle chicken actin gene was found which resembled the amphibian type 5 actin isoform (J. Vandekerckhove, W. W. Franke, and K. Weber, J. Mol. Biol., 152:413-426). This nonmuscle actin type has not been previously detected in warm-blooded vertebrates. We showed that interspersed, repeated DNA sequences closely flanked the alpha-skeletal, alpha-cardiac, beta-, and type 5-like actin genes. The repeated DNA sequences which surround the alpha-skeletal actin-coding regions were not related to repetitious DNA located on the other actin genes. Analysis of genomic DNA blots showed that the chicken actin multigene family was represented by 8 to 10 separate coding loci. The six isolated actin genes corresponded to 7 of 11 genomic EcoRI fragments. Only the alpha-smooth muscle actin gene was shown to be split by an EcoRI site. Thus, in the chicken genome each actin isoform appeared to be encoded by a single gene.     

Isolation of actin genes in Bombyx mori: the coding sequence of a cytoplasmic actin gene expressed in the silk gland is interrupted by a single intron in an unusual position

To study the regulation of the gene(s) coding for the actin present in the microfilaments involved in the secretion of silk, we have probed a Bombyx mori genomic library with a Drosophila actin cDNA clone and selected 16 recombinant phages. They correspond to 3 different genomic fragments each containing a distinct actin coding sequence. Southern blots of genomic DNA probed with the cloned genes show that in Bombyx mori, there are at least 5 different actin genomic sequences. Two cloned genes A1 and A2 hybridize to a 1.7 kb long mRNA abundant in the carcass of the larva and thus probably code for muscle type actin. The third cloned gene, A3, hybridizes to two mRNAs of about 1.8 kb present in the silk gland and thus probably encodes a cytoplasmic actin. The coding sequence of this gene has been sequenced: it is almost identical to the Drosophila cytoplasmic actin genes but it has a single intron of 92 nucleotides within the codon 116, a position not observed in any other organism.     

Characterization of five members of the actin gene family in the sea urchin

Hybridization of an actin cDNA clone (pSA38) to restriction enzyme digests of Strongylocentrotus purpuratus DNA indicates that the sea urchin genome contains at least five different actin genes. A sea urchin genomic clone library was screened for recombinants which hydridize to pSA38 and four genomic clones were isolated. Restriction maps were generated which indicate that three of these recombinants contain different actin genes, and that the fourth may be an allele to one of these. The restriction maps suggest that one clone contains two linked actin genes. This fact, which was confirmed by heteroduplex analysis, indicates that the actin gene family may be clustered. The linked genes are oriented in the same direction and spaced about 8.0 kilobases apart. In heteroduplexes between genomic clones two intervening sequences were seen. Significant homology is confined to the actin coding region and does not include any flanking sequence. Southern blot analysis reveals that repetitive DNA sequences are found in the region of the actin genes.     

Isolation and characterization of human actin genes cloned in phage lambda vectors

Using Drosophila and chicken actin probes, we have selected 14 human actin lambda recombinants from a genomic library. We present a restriction maps indicating the positions of the sequences homologous to actin and to an Alu probe. Restriction mapping has revealed that nine out of ten of these clones are distinct, indicating that actin is a multigene family. Hybrid elution of HeLa cell mRNA from filters containing the recombinant DNA, followed by in vitro translation and immunoprecipitation, as well as one- or two-dimensional protein analysis, shows that these recombinants code for actin. Hybridization back to human DNA digested with restriction enzymes shows that the EcoRI fragments of at least one of the lambda recombinants (lambda HA-5) result in similar-sized human DNA fragments in the intact genome. In nuclei, a 4.5-kb mRNA precursor to the cytoplasmic 1.9-kb mRNA can be detected by hybridization with genomic or cDNA probes, indicating the presence of additional sequences and RNA processing.     

Human actin genes are single copy for alpha-skeletal and alpha-cardiac actin but multicopy for beta- and gamma-cytoskeletal genes: 3'' untranslated regions are isotype specific but are conserved in evolution.

We have constructed isotype-specific subclones from the 3' untranslated regions of alpha-skeletal, alpha-cardiac, beta-cytoskeletal, and gamma-cytoskeletal actin cDNAs. These clones have been used as hybridization probes to assay the number and organization of these actin isotypes in the human genome. Hybridization of these probes to human genomic actin clones (Engel et al., Proc. Natl. Acad. Sci. U.S.A. 78:4674-4678, 1981; Engel et al., Mol. Cell. Biol. 2:674-684, 1982) has allowed the unambiguous assignment of the genomic clones to isotypically defined actin subfamilies. In addition, only one isotype-specific probe hybridizes to each actin-containing gene, with a single exception. This result suggests that the multiple actin genes in the human genome are not closely linked. Genomic DNA blots probed with these subclones under stringent conditions demonstrate that the alpha-skeletal and alpha-cardiac muscle actin genes are single copy, whereas the cytoskeletal actins, beta and gamma, are present in multiple copies in the human genome. Most of the actin genes of other mammals are cytoplasmic as well. These observations have important implications for the evolution of multigene families.     

Actin-like sequences are present on human X and Y chromosomes.

The human genome contains greater than 20 actin-related sequences, six of which at least are expressed as protein. We have shown by blot hybridization the presence of actin-like sequences on both the X and the Y chromosomes. These sequences can be detected in HindIII digests of genomic DNA, using as probe cDNA clones corresponding to human alpha skeletal actin or to a hamster (beta or gamma) cytoskeletal actin; they show more homology to the latter probe. The actin probes also detect a polymorphic DNA fragment showing autosomal inheritance with a frequency for the major allele of 0.55 in the population studied. The X-linked actin sequence has been assigned to a centromeric region between Xp11 and Xq11 by hybridization to DNAs from a panel of human-mouse hybrid cell lines, and thus lies outside the postulated region of homology between the X and Y chromosomes. The Y-linked actin sequence can serve as a marker to analyse anomalies of sex determination or of gametogenesis in man. It was found in all XY males studied but was absent from the genomic DNA of four unrelated 'XX male' subjects and two XX hermaphrodites. This shows that the region of chromosome Y which contains the actin sequence is not translocated onto the X chromosome (or onto autosomes) in these patients.     

Genomic organization of Tropomodulins 2 and 4 and unusual intergenic and intraexonic splicing of YL-1 and Tropomodulin 4

Background  

The tropomodulins (TMODs) are a family of proteins that cap the pointed ends of actin filaments. Four TMODs have been identified in humans, with orthologs in mice. Mutations in actin or actin-binding proteins have been found to cause several human diseases, ranging from hypertrophic cardiomyopathy to immunodefiencies such as Wiskott-Aldrich syndrome. We had previously mapped Tropomodulin 2 (TMOD2) to the genomic region containing the gene for amyotrophic lateral sclerosis 5 (ALS5). We determined the genomic structure of Tmod2 in order to better analyze patient DNA for mutations; we also determined the genomic structure of Tropomodulin 4 (TMOD4).     

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.     

Echinococcus granulosus: Cloning and Functional in Vitro Characterization of an Actin Filament Fragmenting Protein

We report the isolation and characterization of an Echinococcus granulosus gene that codes for a protein with actin filament fragmenting and nucleating activities (EgAFFP). The genomic region corresponding to the EgAFFP gene presents a coding sequence of 1110 bp that is interrupted by eight introns. The EgAFFP deduced amino acid sequence is about 40% homologous to those of several members of the gelsolin family, such as Physarum polycephalum fragmin, Dictyostelium discoideum severin, and Lumbricus terrestris actin modulator. As do other proteins of the same family, EgAFFP presents three repeated domains, each one characterized by internal conserved amino acid motifs. Assays with fluorescence-labeled actin showed that the full-length recombinant EgAFFP effectively binds actin monomers in both a calcium-dependent and calcium-independent manner and also presents actin nucleating and severing activities.     

A Novel Family of Unconventional Actins in Volvocalean Algae

The unicellular green alga Chlamydomonas reinhardtii has two actin genes, one encoding a conventional actin (90% amino acid identity with mammalian actin), the other a highly divergent actin (64% identity) named novel actin-like protein (NAP). To see whether the presence of conventional and unconventional actins in a single organism is unique to C. reinhardtii, we searched for genomic sequences related to the NAP sequence in several other species of volvocalean algae. Here we show that Chlamydomonas moewusii and Volvox carteri also have, in addition to a conventional actin, an unconventional actin similar to the C. reinhardtii NAP. Analyses of the deduced protein sequences indicated that the NAP homologues form a distinct group derived from conventional actin.     

Unique properties of eukaryote-type actin and profilin horizontally transferred to cyanobacteria

A eukaryote-type actin and its binding protein profilin encoded on a genomic island in the cyanobacterium Microcystis aeruginosa PCC 7806 co-localize to form a hollow, spherical enclosure occupying a considerable intracellular space as shown by in vivo fluorescence microscopy. Biochemical and biophysical characterization reveals key differences between these proteins and their eukaryotic homologs. Small-angle X-ray scattering shows that the actin assembles into elongated, filamentous polymers which can be visualized microscopically with fluorescent phalloidin. Whereas rabbit actin forms thin cylindrical filaments about 100 μm in length, cyanobacterial actin polymers resemble a ribbon, arrest polymerization at 5-10 μm and tend to form irregular multi-strand assemblies. While eukaryotic profilin is a specific actin monomer binding protein, cyanobacterial profilin shows the unprecedented property of decorating actin filaments. Electron micrographs show that cyanobacterial profilin stimulates actin filament bundling and stabilizes their lateral alignment into heteropolymeric sheets from which the observed hollow enclosure may be formed. We hypothesize that adaptation to the confined space of a bacterial cell devoid of binding proteins usually regulating actin polymerization in eukaryotes has driven the co-evolution of cyanobacterial actin and profilin, giving rise to an intracellular entity.     

Biochemical and cell biological analysis of actin in the nematode Caenorhabditis elegans

The nematode Caenorhabditis elegans has long been a useful model organism for muscle research. Its body wall muscle is obliquely striated muscle and exhibits structural similarities with vertebrate striated muscle. Actin is the core component of the muscle thin filaments, which are highly ordered in sarcomeric structures in striated muscle. Genetic studies have identified genes that regulate proper organization and function of actin filaments in C. elegans muscle, and sequence of the worm genome has revealed a number of conserved candidate genes that may regulate actin. To precisely understand the functions of actin-binding proteins, such genetic and genomic studies need to be complemented by biochemical characterization of these actin-binding proteins in vitro. This article describes methods for purification and biochemical characterization of actin from C. elegans. Although rabbit muscle actin is commonly used to characterize actin-binding proteins from many eukaryotic organisms, we detect several quantitative differences between C. elegans actin and rabbit muscle actin, highlighting that use of actin from an appropriate source is important in some cases. Additionally, we describe probes for cell biological analysis of actin in C. elegans.