Genetics of the Tubulin Gene Families of Physarum

The organization of the alpha- and beta-tubulin gene families in Physarum was investigated by Mendelian analysis. Restriction endonuclease-generated DNA fragments homologous to alpha- and beta-tubulin show length polymorphisms that can be used as markers for genetic mapping. Analysis of meiotic assortment among progeny of heterozygotes allowed alpha- and beta-tubulin sequence loci to be defined. There are four unlinked alpha-tubulin sequence loci (altA, altB, altC and altD) and at least three unlinked beta-tubulin sequence loci (betA, betB and betC). The alpha-tubulin loci are not linked to the beta-tubulin loci. --Segregation of tubulin sequence loci with respect to ben mutations that confer resistance to antitubulin benzimidazole drugs was used to investigate whether any members of the alpha- or beta-tubulin gene families are allelic to ben loci. The beta-tubulin sequence locus betB is allelic to the resistance locus benD, the betA locus is probably allelic to benA and the alpha-tubulin sequence locus altC may be allelic to benC. The molecular implications of benzimidazole resistance phenotypes when only one of the expressed beta-tubulin gene family members mutates to drug resistance are discussed in relation to tubulin function.     

Cloning and expression of a beta tubulin gene of Physarum polycephalum

A beta tubulin gene of Physarum polycephalum has been isolated from a genomic library in the phage EMBL4. Southern-blot hybridization to genomic DNA indicates that the cloned DNA is derived from the betB1 locus of the beta tubulin gene family. A tubulin-specific subfragment of the phage DNA was used as a hybridization probe to construct a restriction map of the betB1 locus. The probe consisted of the almost complete coding region of the 5' half of the tubulin gene, interrupted by one intron. The derived amino acid sequence of this subclone deviates from the protein sequence for Physarum amoebal beta tubulin (amino acids 4-207) in two of 207 amino acids. We used both recA and recBC sbcB bacterial host strains, which have been recommended for cloning of instability-conferring sequences of the Physarum genome, but were unable to subclone the 3' part of the gene from the phage DNA. Primer-extension analysis indicates that the betB gene is expressed in the vegetatively proliferating amoebal and plasmodial stages of the life cycle as well as in differentiating (sporulating) plasmodia.     

Cell type-dependent expression of tubulins in Physarum

Three alpha-tubulins and two beta-tubulins have been resolved by two-dimensional gel electrophoresis of whole cell lysates of Physarum myxamoebae or plasmodia. Criteria used to identify the tubulins included migration on two-dimensional gels with myxamoebal tubulins purified by self-assembly into microtubules in vitro, peptide mapping with Staphylococcus V8 protease and with chymotrypsin, immunoprecipitation with a monoclonal antibody specific for beta-tubulin, and, finally, hybrid selection of specific mRNA by cloned tubulin DNA sequences, followed by translation in vitro. Differential expression of the Physarum tubulins was observed. The alpha 1- and beta 1-tubulins were detected in both myxamoebae and plasmodia; alpha 2 and beta 2 were detected only in plasmodia, alpha 3 was detected only in the myxamoebal phase, and may be specific to the flagellate. Observation of more tubulin species in plasmodia than in myxamoebae was remarkable; the only microtubules detected in plasmodia are those of the mitotoic spindle, whereas myxamoebae display cytoplasmic, centriolar, flagellar, and mitotic-spindle microtubules. In vitro translation of myxamoebal and plasmodial RNAs indicated that there are distinct mRNAs, and therefore probably separate genes, for the alpha 1-, alpha 2-, beta 1-, and beta 2-tubulins. Thus, the different patterns of tubulin expression in myxamoebae and plasmodia reflect differential expression of tubulin genes.     

Location of a single beta-tubulin gene product in both cytoskeletal and mitotic-spindle microtubules in Physarum polycephalum

In the mutant BEN210 of Physarum polycephalum several beta-tubulins are detectable. beta 1-tubulin is unique to the myxamoeba, beta 2-tubulin is unique to the plasmodium, and the mutant beta 1-210 tubulin encoded by the benD210 allele is present in both cell types. In order to analyse the subcellular distribution of the beta 1-210 polypeptide, we prepared cytoskeletons from myxamoebae and mitotic spindles from plasmodia, and examined the tubulin polypeptide composition of these microtubular organelles by two-dimensional gel electrophoresis and immunoblotting. The results show that the beta 1-210 tubulin is present in microtubules of both the cytoskeleton and the intranuclear mitotic spindle. Thus a single beta-tubulin gene product can participate in multiple microtubular organelles in distinct cellular compartments.     

Physarum amoebae express a distinct fragmin-like actin-binding protein that controls in vitro phosphorylation of actin by the actin-fragmin kinase.

Amoebae and plasmodia constitute the two vegetative growth phases of the Myxomycete Physarum. In vitro and in vivo phosphorylation of actin in plasmodia is tightly controlled by fragmin P, a plasmodium-specific actin-binding protein that enables actin phosphorylation by the actin-fragmin kinase. We investigated whether amoebal actin is phosphorylated by this kinase, in spite of the lack of fragmin P. Strong actin phosphorylation was detected only following addition of recombinant actin-fragmin kinase to cell-free extracts of amoebae, suggesting that amoebae contain a protein with properties similar to plasmodial fragmin. We purified the complex between actin and this protein to homogeneity. Using an antibody that specifically recognizes phosphorylated actin, we demonstrate that Thr203 in actin can be phosphorylated in this complex. A full-length amoebal fragmin cDNA was cloned and the deduced amino acid sequence shows 65% identity with plasmodial fragmin. However, the fragmins are encoded by different genes. Northern blots using RNA from a developing Physarum strain demonstrate that this fragmin isoform (fragmin A) is not expressed in plasmodia. In situ localization showed that fragmin A is present mainly underneath the plasma membrane. Our results indicate that Physarum amoebae express a fragmin P-like isoform which shares the property of binding actin and converting the latter into a substrate for the actin-fragmin kinase.     

Molecular cloning, physical mapping and expression of the bet genes governing the osmoregulatory choline-glycine betaine pathway of Escherichia coli

An analysis of the bet genes governing the osmoregulatory choline-glycine betaine pathway of Escherichia coli was performed. A 9 kb BamHI fragment, located 30 to 39 kb counterclockwise of the EcoRI site of lacZ, coded for all known Bet activities. The following genes were identified: the betA gene for the choline dehydrogenase, the betB gene for the betaine aldehyde dehydrogenase, and the betT gene or operon for the high-affinity choline transport. The betB and the betT genes were named in this paper, and the clockwise gene order was shown to be betA,B,T. Subcloning gave plasmids which expressed each of the three Bet activities separately. The cloned bet genes remained osmotically regulated, indicating the existence of several osmotically regulated promoters in the bet region. Salmonella typhimurium, which carried the bet region of E. coli in the broad-host-range vector pRK293 expressed the three Bet activities and displayed increased osmotic tolerance in the presence of choline.     

Sequence of chicken c beta 7 tubulin. Analysis of a complete set of vertebrate beta-tubulin isotypes

In chicken, beta-tubulin is encoded by a family of seven genes. We have now isolated and sequenced overlapping cDNA clones corresponding to gene c beta 7 (previously designated c beta 4'), the only chicken beta-tubulin not previously characterized. The inferred amino acid sequence of c beta 7 tubulin is identical with the class I beta-tubulin isotype found in human, mouse and rat. Moreover, c beta 7 is highly expressed in almost all tissue and cell types in chicken, a pattern similar to those of the genes for class I beta-tubulin isotypes in other vertebrates. Comparison of the complete family of chicken beta-tubulin gene sequences reveals that the heterogeneity of beta-tubulin polypeptides encoded in a higher eukaryote is confined to six distinct beta-tubulin isotypes. Five of these are members of evolutionarily conserved isotypic classes (I to V), whereas the sixth represents a divergent erythroid-specific tubulin whose sequence has not been conserved.     

Mating type and the differentiated state in Physarum polycephalum.

In the acellular slime mold, Physarum polycephalum, the differentiation of amoebae into plasmodia is controlled by a mating type locus, mt. Amoebae carrying heterothallic alleles usually do not differentiate within clones; plasmodia form when two amoebae carrying different alleles fuse and undergo karyogamy. In this paper, we show that amoebae heterozygous for heterothallic alleles can be isolated and maintained as amoebae; the amoebae form plasmodia in clones without a change in ploidy. Plasmodia were also found to be formed, infrequently, by heterothallic amoebae of a single mating type. The plasmodia are healthy and are also formed without a change in ploidy. Thus, the presence of two different heterothallic mating type genes in a single nucleus is compatible with the amoebal state and one heterothallic mating type gene is compatible with the plasmodial state, once established.     

Cloning and expression of the tubulin genes in barley

Tubulins are encoded by small gene families in plants. Based on the barley EST collection, cDNAs for alpha-, beta-, and gamma-tubulins were selected. Five genes for alpha-tubulin, eight newly identified beta-tubulin sequences and one gamma-tubulin gene were found to be expressed in barley. In silico analysis of relative abundance of the distinct tubulin sequences among ESTs derived from different libraries revealed that the various tubulin genes differed in their level of expression, and to some extent were tissue specific.     

Sequence heterogeneity, multiplicity, and genomic organization of alpha- and beta-tubulin genes in sea urchins.

We analyzed the multiplicity, heterogeneity, and organization of the genes encoding the alpha and beta tubulins in the sea urchin Lytechinus pictus by using cloned complementary deoxyribonucleic acid (cDNA) and genomic tubulin sequences. cDNA clones were constructed by using immature spermatogenic testis polyadenylic acid-containing ribonucleic acid as a template. alpha- and beta-tubulin clones were identified by hybrid selection and in vitro translation of the corresponding messenger ribonucleic acids, followed by immunoprecipitation and two-dimensional gel electrophoresis of the translation products. The alpha cDNA clone contains a sequence that encodes the 48 C-terminal amino acids of alpha tubulin and 104 base pairs of the 3' nontranslated portion of the messenger ribonucleic acid. The beta cDNA insertion contains the coding sequence for the 100-C terminal amino acids of beta tubulin and 83 pairs of the 3' noncoding sequence. Hybrid selections performed at different criteria demonstrated the presence of several heterogeneous, closely related tubulin messenger ribonucleic acids, suggesting the existence of heterogeneous alpha- and beta-tubulin genes. Hybridization analyses indicated that there are at least 9 to 13 sequences for each of the two tubulin gene families per haploid genome. Hybridization of the cDNA probes to both total genomic DNA and cloned germline DNA fragments gave no evidence for close physical linkage of alpha-tubulin genes with beta-tubulin genes at the DNA level. In contrast, these experiments indicated that some genes within the same family are clustered.     

Building a plasmodium: Development in the acellular slime mould Physarum polycephalum

The two vegetative cell types of the acellular slime mould Physarum polycephalum - amoebae and plasmodia - differ greatly in cellular organisation and behaviour as a result of differences in gene expression. The development of uninucleate amoebae into multinucleate, syncytial plasmodia is under the control of the mating-type locus matA, which is a complex, multi-functional locus. A key period during plasmodium development is the extended cell cycle, which occurs in the developing uninucleate cell. During this long cell cycle, many of the changes in cellular organisation that accompany development into the multinucleate stage are initiated including, for example, alterations in microtubule organisation. Genes have been identified that show cell-type specific expression in either amoebae or plasmodia and many of these genes alter their pattern of expression during the extended cell cycle. With the introduction of a DNA transformation system for P. polycephalum, it is now possible to investigate the functions of genes in the vegetative cell types and their roles in the cellular reorganisations accompanying development.