Amino acid sequence data of alpha-tubulin from myxamoebae of Physarum polycephalum

About 96% of the amino acid sequence of an alpha-tubulin from the slime mould Physarum polycephalum has been determined. Of 430 sequenced amino acids, 30 differ from the deduced amino acid sequence of a recently published alpha-tubulin complementary DNA from the plasmodial form of P. polycephalum. The myxamoebal alpha-tubulin differs from all other known alpha-tubulins in one of the last three C-terminal amino acids that are Gly-Glu-Tyr instead of the usual Glu-Glu-Tyr. These last three amino acids are preceded by 11 residues that appear to be particularly susceptible to mutation. No heterogeneity was found whilst sequencing the myxamoebal alpha-tubulin, indicating that only one type of alpha-tubulin is present in myxamoebae. This alpha-tubulin appears to be less conserved than the previously described plasmodial alpha-tubulin, supporting the hypothesis that the structural constraints on tubulin in axonemes have a significant effect on its rate of mutation.     

Analysis of structural characteristics of alpha-tubulins in plants with enhanced cold tolerance

The uniqueness of the point substitutions in the sequences of two alpha-tubulin isotypes from psychrophilic alga Chloromonas that can determine the increased cold tolerance of this alga was analyzed. The comparison of all known amino acid sequences of plant alpha-tubulins enabled to ascertain that only M268-->V replacement is unique and may have a significant influence on spatial structure of plant alpha-tubulins. Modeling of molecular surfaces of alpha-tubulins from Chloromonas, Chalmydomonas reinhardtii and goose grass Eleusine indica showed that insertion of the amino acid replacement M268-->V into the sequence of goose grace tubulin led to the likening of this protein surface to the surface of native alpha-tubulin from Chloromonas. Alteration of local hydrophobic properties of alpha-tubulin molecular surface in interdimeric contact zone as a result of the mentioned replacement was shown that may play important role in increasing the level of cold resistance of microtubules. The crucial role of amino acid residue in 268 position for forming the interdimeric contact surface of alpha-tubulin molecule was revealed. The assumption is made about the importance of replacements at this position for plant tolerance to abiotic factors of different nature (cold, herbicides).     

A divergent testis-specific alpha-tubulin isotype that does not contain a coded C-terminal tyrosine.

On the basis of analysis of cDNA clones of alpha-tubulin RNAs expressed during spermiogenesis in chickens, we report the identification of a novel alpha-tubulin which is expressed exclusively in chicken testes. Comparison of its sequence with those previously determined not only demonstrates that the encoded polypeptide is significantly divergent from other alpha-tubulins but also supports the hypothesis that alpha-tubulin isotypes are distinguished by a carboxy-terminal variable region sequence and, to a lesser extent, by a domain near the amino terminus. Since essentially all previously known alpha-tubulins undergo a unique cycle of removal and posttranslational readdition of a tyrosine residue at the extreme carboxy terminus, the presence in this testes alpha-tubulin of a very divergent carboxy terminus that does not contain an encoded tyrosine raises the possibility that this polypeptide does not participate in the usual cycle of tyrosination/detyrosination.     

Two functional alpha-tubulin genes of the yeast Saccharomyces cerevisiae encode divergent proteins.

Two alpha-tubulin genes from the budding yeast Saccharomyces cerevisiae were identified and cloned by cross-species DNA homology. Nucleotide sequencing studies revealed that the two genes, named TUB1 and TUB3, encoded gene products of 447 and 445 amino acids, respectively, that are highly homologous to alpha-tubulins from other species. Comparison of the sequences of the two genes revealed a 19% divergence between the nucleotide sequences and a 10% divergence between the amino acid sequences. Each gene had a single intervening sequence, located at an identical position in codon 9. Cell fractionation studies showed that both gene products were present in yeast microtubules. These two genes, along with the TUB2 beta-tubulin gene, probably encode the entire complement of tubulin in budding yeast cells.     

Comparative analysis of tubulin sequences

1. Information on the structure and evolution of tubulin has been obtained by comparing the available sequence data on 31 alpha-tubulins and 31 beta-tubulins. 2. Similar numbers of conserved amino acids are found amongst both alpha- and beta-tubulins (alpha: 48%, plus conservative substitutions: 72%; beta: 48%, plus conservative substitutions: 70%). About half of them are common to both subunits (23%, plus conservative substitutions: 45%). Four cysteines in the alpha-tubulins and 2 cysteines in the beta-tubulins are conserved. Only one cysteine (position 129) is conserved in all alpha- and beta-tubulins. 3. The longest unbroken stretch of identical amino acids between all the alpha- and beta-tubulins is found in positions 180-186 (Val-Val-Glu-Pro-Tyr-Asn), a region that appears to be important for binding the ribose moiety of GTP. Two other groups of amino acids implicated in GTP binding, one near position 70 and a glycine cluster at position 144 are also quite conserved. 4. Extra length differences between tubulin subunits, presumably present as extensions on the dimer surface, have been observed at position 50 and near position 360 in alpha-tubulins and in one case at position 57 in a beta-tubulin. 5. The introns of tubulin genes, many of them clustered in the first quarter of the tubulin coding region, do not appear to correspond to any particular structural or functional regions. 6. Mutation rates of tubulins vary considerably. The lowest alpha-tubulin homology (62.3%) is between a very divergent Drosophila alpha-tubulin and an alpha-tubulin from the yeast S. cerevisiae. The lowest beta-tubulin homology (63.3%) is between a yeast (S. cerevisiae) beta-tubulin and a mouse beta-tubulin expressed in hematopoietic tissue. In contrast, some mammalian and bird tubulins are almost identical. 7. Tubulin's heterogeneous C-termini are useful for identifying corresponding tubulins of different vertebrate species, many of which are remarkably conserved. Exceptions are the divergent beta-tubulins of erythrocyte and thrombocyte marginal bands. 8. We have proposed a model for tubulin evolution in metazoan organisms in which the release of structural constraints after gene duplication is a major cause of relatively rapid change.     

A survey of the alpha-tubulin gene family in chicken: unexpected sequence heterogeneity in the polypeptides encoded by five expressed genes.

To characterize the alpha-tubulin gene family in chicken, we have isolated five chicken alpha-tubulin genes and determined the majority of the sequences of the encoded polypeptides. Three of these (c alpha 3, c alpha 5/6 and c alpha 8) encode novel, expressed alpha-tubulins that have not previously been analyzed, whereas one gene segment is a pseudogene and another appears capable of encoding a functional subunit (although we were unable to document its expression in a survey of chicken tissues). Together with two additional expressed, functional alpha-tubulins reported earlier, we conclude that the chicken alpha-tubulin family is comprised of at least five functional genes whose polypeptide products are substantially more heterogeneous than found in preceding analyses of vertebrate alpha-tubulins. Comparison of the amino acid sequences reveals that the five polypeptides are between 96 and 83% identical, with the extreme carboxy-terminal residues representing a highly heterogeneous variable domain. Since some alpha-tubulins undergo cyclic post-translational removal and readdition of a carboxy-terminal tyrosine, the notable sequence divergence in this domain suggests that individual tubulins probably participate to different extents in this modification cycle.     

Isolation of α-tubulin genes from the human malaria parasite, Plasmodium falciparum: sequence analysis of α-tubulin

As a step towards identifying exploitable differences between host and parasite at the molecular level, we have isolated and sequenced genomic clones encompassing an entire alpha-tubulin gene (designated alpha-tubulin I) from the human malaria parasite, Plasmodium falciparum. The gene, which contains two introns, encodes a product with a predicted length of 453 amino acid residues (50.3 kD). The protein sequence shows a high degree of homology to other alpha-tubulins, particularly that of the coccidian parasite, Toxoplasma gondii (94%), whose gene carries introns in identical positions. Only one copy of the alpha-tubulin I gene itself was found, although a second gene designated alpha-II was also identified which is closely related but which differs at both the nucleotide and amino acid sequence levels. The alpha-I and beta-tubulin genes were found to reside on different chromosomes.     

Primary structure of profilins from two species of Echinoidea and Physarum polycephalum

Profilin is a small G-actin-binding protein, the amino acid sequence of which was previously reported for calf, human, Acanthamoeba and yeast. Here the amino acid sequences of three profilins obtained from eggs of two species of Echinoidea, Clypeaster japonicus (order, Clypeasteroida) and Anthocidaris crassispina (order, Echinoida), and plasmodium of Physarum polycephalum were determined. Two echinoid profilins were composed of 139 amino acid residues, N-termini were acylated and the molecular mass was calculated to be 14.6 kDa, slightly larger than that of 13 kDa estimated by SDS/PAGE [Mabuchi, I. & Hosoya, H. (1982) Biomed. Res. 3, 465-476]. On the other hand, Physarum profilin was composed of 124 amino acid residues, the N-terminus was acylated, and the calculated molecular mass was 13132 Da. The sequences of C. japonicus and A. crassispina profilins were homologous (84% identical). However, the similarity of these profilins with those form other organisms was low. The sequence of Physarum profilin was homologous with Acanthamoeba profilin isoforms (51% identical) and with yeast profilin (42% identical), but not with other profilins. The relatively conservative sequence of profilins from yeast, Physarum, Acanthamoeba, echinoid eggs and mammalian cells was found in the N-terminal region, which was suggested to be a common actin-binding region. The C-terminal region was also conserved, although to a lesser extent than the N-terminal region.     

Genetic evidence for a dystrophin-glycoprotein complex (DGC) in Caenorhabditis elegans

A novel alpha-tubulin gene (alpha6) was cloned from a genomic library of Naegleria gruberi strain NB-1 and characterized. The open reading frame of alpha6 contained 1359 nucleotides encoding a protein of 452 amino acids (aa) with a calculated molecular weight of 50.5 kDa. The nucleotide sequence of the open reading frame of alpha6 showed considerable divergence (68.4% identity) when compared with previously cloned N. gruberi alpha-tubulin genes, which share about 97% identity in DNA sequences. The deduced aa sequence of alpha6-tubulin was 61.9% identical to that of alpha13-tubulin, which was cloned from the same strain, and showed similar identities to those of alpha-tubulins from other species (54 approximately 62%). These data showed that alpha6-tubulin is one of the most divergent alpha-tubulins so far known. Alpha6-tubulin was found to be expressed in actively growing cells and repressed quickly when these cells were induced to differentiate. Immunostaining with an antibody against alpha6-tubulin showed that alpha6-tubulin is present in the nuclei and mitotic spindle-fibers but absent in flagellar axonemes or cytoskeletal microtubules. These data finally established the presence of an alpha-tubulin that is specifically utilized for spindle-fiber microtubules and distinct from the flagellar axonemal alpha-tubulins in N. gruberi, hence confirmed the multi-tubulin hypothesis in this organism.     

Identification and characterization of axopodial tubulins from Echinosphaerium nucleofilum

Isolated microtubule protein from axopodia of the heliozoan Echinosphaerium nucleofilum, consisting of two major bands on SDS-polyacrylamide gel electrophoresis (SDS-PAGE), has been compared to axonemal and cytoplasmic tubulins from both animal and non-animal sources. The upper E. nucleofilum protein band migrated faster than the alpha-tubulins of bovine brain and sea anemone sperm tails but with approximately the same electrophoretic mobility as the axonemal alpha-tubulins of Tetrahymena pyriformis and the alga Chlorogonium elongatum and cytoplasmic alpha-tubulin from the slime mold Physarum polycephalum. The lower E. nucleofilum protein band, however, had a higher electrophoretic mobility than all the beta-tubulins which we have so far examined. It was, nevertheless, a true beta-tubulin as shown by its migration on two-dimensional gel electrophoresis and the general resemblance of its one- and two-dimensional peptide maps to those of other beta-tubulins. The Staphylococcus aureus protease cleavage pattern of the upper axopodial protein band was similar to those of other non-animal alpha-tubulins but quite different from those of the animal alpha-tubulins. In contrast, the two-dimensional tryptic peptide map of axopodial alpha-tubulin was distinct from all of them. For example, a characteristic constellation of peptides common to the peptide maps of the other alpha-tubulins was absent from that of E. nucleofilum. In contrast to Physarum and metazoan tubulins but similar to Tetrahymena tubulin, the axopodial alpha-tubulin had a more basic isoelectric point than the beta-subunit as shown by two dimensional gel electrophoresis. Some of the unusual characteristics of E. nucleofilum axopodial tubulin may not only reflect phylogenetic variation, but also the different functional requirements of axopodial microtubules.     

The F-actin capping proteins of Physarum polycephalum: cap42(a) is very similar, if not identical, to fragmin and is structurally and functionally very homologous to gelsolin; cap42(b) is Physarum actin.

We have carried out a primary structure analysis of the F-actin capping proteins of Physarum polycephalum. Cap42(b) was completely sequenced and was found to be identical with Physarum actin. Approximately 88% of the sequence of cap42(a) was determined. Cap42(a) and fragmin were found to be identical by amino acid composition, isoelectric point, mol. wt, elution time on reversed-phase chromatography and amino acid sequence of their tryptic peptides. The available sequence of cap42(a) is greater than 36% homologous with the NH2-terminal 42-kd domain of human gelsolin. A highly homologous region of 16 amino acids is also shared between cap42(a), gelsolin and the Acanthamoeba profilins. Cap42(a) binds two actin molecules in a similar way to gelsolin suggesting a mechanism of F-actin modulation that has been conserved during evolution.     

Recognition of specific Physarum alpha-tubulin isotypes by a monoclonal antibody. Sequence heterogeneity around the acetylation site at lysine 40

The monoclonal antibody 6-11B-1 recognises specifically the acetylated form of alpha-tubulin. The acetylation event occurs on a unique lysine residue, lysine 40. Using 6-11B-1, acetylated alpha-tubulin was detected in myxamoebae but not plasmodia of Physarum polycephalum. Following chemical acetylation plasmodial alpha-tubulin was detected by 6-11B-1. The monoclonal antibody KMP-1 recognises certain Physarum alpha-tubulin isotypes but only in non-acetylated form. Whilst recognising all the non-acetylated fraction of myxamoebal alpha-tubulin only a proportion of plasmodial alpha-tubulin was recognised by KMP-1. Peptides were synthesised corresponding to the acetylation domains (containing lysine 40) of myxamoebal alpha-tubulin and the inferred acetylation domains of two plasmodial-specific alpha-tubulin isotypes. The only difference between the two peptides was at a single residue corresponding to amino acid 44 in the polypeptide. Tyrosine was present in myxamoebal alpha-tubulin and glycine was present in the plasmodial specific peptides; the peptides are referred to as the Tyr44 and Gly44 peptides respectively. Both peptides in acetylated form blocked 6-11B-1 reactivity towards acetylated myxamoebal alpha-tubulin. The Tyr44 but not the Gly44 peptide blocked KMP-1 reactivity towards non-acetylated myxamoebal alpha-tubulin. Tyrosine at position 44 is not found in any other known alpha-tubulin. Thus a unique antigenic determinant exists in certain Physarum alpha-tubulin isotypes, close to the acetylation site at lysine 40. This antigenic determinant forms part of the KMP-1 recognition epitope and explains the unique isotype selectivity of this monoclonal antibody.     

Three Drosophila beta-tubulin sequences: a developmentally regulated isoform (beta 3), the testis-specific isoform (beta 2), and an assembly-defective mutation of the testis-specific isoform (B2t8) reveal both an ancient divergence in metazoan isotypes and structural constraints for beta-tubulin function.

The genomic DNA sequence and deduced amino acid sequence are presented for three Drosophila melanogaster beta-tubulins: a developmentally regulated isoform beta 3-tubulin, the wild-type testis-specific isoform beta 2-tubulin, and an ethyl methanesulfonate-induced assembly-defective mutation of the testis isoform, B2t8. The testis-specific beta 2-tubulin is highly homologous to the major vertebrate beta-tubulins, but beta 3-tubulin is considerably diverged. Comparison of the amino acid sequences of the two Drosophila isoforms to those of other beta-tubulins indicates that these two proteins are representative of an ancient sequence divergence event which at least preceded the split between lines leading to vertebrates and invertebrates. The intron/exon structures of the genes for beta 2- and beta 3-tubulin are not the same. The structure of the gene for the variant beta 3-tubulin isoform, but not that of the testis-specific beta 2-tubulin gene, is similar to that of vertebrate beta-tubulins. The mutation B2t8 in the gene for the testis-specific beta 2-tubulin defines a single amino acid residue required for normal assembly function of beta-tubulin. The sequence of the B2t8 gene is identical to that of the wild-type gene except for a single nucleotide change resulting in the substitution of lysine for glutamic acid at residue 288. This position falls at the junction between two major structural domains of the beta-tubulin molecule. Although this hinge region is relatively variable in sequence among different beta-tubulins, the residue corresponding to glu 288 of Drosophila beta 2-tubulin is highly conserved as an acidic amino acid not only in all other beta-tubulins but in alpha-tubulins as well.     

Molecular cloning and characterization of Hymenolepis diminuta alpha-tubulin gene.

To isolate a full-length alpha-tubulin cDNA from an eucestode, Hymenolepis diminuta, a lambda phage cDNA library was constructed. The alpha-tubulin gene was cloned, sequenced and characterized. The H. diminuta alpha-tubulin consisted of 450 amino acids. This protein contained putative sites for all posttranslational modifications as detyrosination/tyrosination at the carboxyl-terminal of protien, phosphorylation at residues R79 and K336, glycylation/glutamylation at residue G445 and acetylation at residue K40. Comparisons of H. diminuta alpha-tubulin with all full-length alpha-tubulin proteins revealed that H. diminuta alpha-tubulin possesses 10 distinctive residues, which are not found in any other alpha-tubulins. Phylogenetic analysis showed that H. diminuta alpha-tubulin has grouped in a separated branch adjacent eucestode and trematodes branch with 92% bootstrap value (1000 replicates). In conclusion, this is the first report of H. diminuta cDNA library construction, cloning and characterization of H. diminuta alpha-tubulin gene.