Identification of a gene for beta-tubulin in Aspergillus nidulans.

The tubulins of Aspergillus nidulans have been characterized in wild-type and ben A, B and C benomyl-resistant strains by two-dimensional gel electrophoresis, co-polymerization with porcine brain tubulin and peptide mapping. Four α-tubulins and at least four β-tubulins were resolved by two-dimensional gel electrophoresis of wild-type proteins. Eighteen of 26 benA mutants studied had electrophoretically abnormal β-tubulins. In these strains, one or more of the β-tubulins had either an altered isoelectric point or an altered electrophoretic mobility in the SDS gel dimension, or was diminished in amount. The a-tubulins were normal. Two-dimensional gels of protein extracts of a ben A/wild-type diploid strain demonstrated co-expression of the wild-type β-tubulins with the variant ben A tubulin. This experiment rules out post-translational modification as the source of the β-tubulin abnormalities in the benA mutants. We therefore conclude that benA must be a structural gene for β-tubulin. Due to the variety of abnormalities affecting β-tubulins in ben A mutants, and the absence of abnormalities affecting α-tubulins in any of the benomyl-resistant mutants, we also believe that the benomyl binding site must be located on the β-subunit of the tubulin dimer. The benA mutants of A. nidulans promise to be useful not only for characterizing the biochemical determinants of the benomyl binding site of tubulin but also for understanding the relationship between tubulin structure and function.     

Darwinism and human affairs: By R. D. Alexander. Seattle: University of Washington Press. 317 pp. $14.95

We have examined nuclear transport in Aspergillus nidulans to determine whether microtubles function in the movement of this organelle. Nuclear movement was found to be inhibited in germinating conidia (uninucleate asexual spores) by the microtubule inhibitor benomyl. To show that the benomyl inhibition was due to its effect on microtubules, the test was repeated with mutants which have genetic lesions in β-tubulin which produce resistance to benomyl in one case (benA15) and super-sensitivity in another (benA16). Nuclear movement was resistant to benomyl in the strain carrying benA15 and super-sensitive in the strain carrying benAl6. Since altered sensitivity to benomyl in these strains is specifically due to alterations in β-tubulin, these results show that β-tubulin is involved in nuclear movement. To eliminate the possibility that nuclear movement blockage was a secondary consequence of nuclear division blockage, this experiment was repeated with temperature-sensitive nuclear division mutants. At restrictive temperature, nuclear division was blocked in these mutants but nuclear movement was not. In the presence of benomyl, nuclear division and migration were blocked at permissive and restrictive temperatures. Thus nuclear division blockage alone is not sufficient to block nuclear movement. These experiments were corroborated by similar experiments on a temperature-sensitive nuclear movement mutant. Five previously isolated nonallelic temperature-sensitive nuclear movement mutants, nudA-E, were analyzed genetically and found not to be allelic to the benA (β-tubulin) tubA α-tubulin genes.     

Genetic Variation During Persistent Reovirus Infection: Presence of Extragenically Suppressed Temperature-Sensitive Lesions in Wild-Type Virus Isolated from Persistently Infected L Cells

Persistent reovirus infection of L cells was established with a serially passaged stock of temperature-sensitive (ts) mutant C(447) containing greater than 90% defective interfering particles. Within a month after establishment of the carrier culture, the ts mutant was replaced by virus that expressed the wild-type (ts⁺) temperature phenotype (R. Ahmed and A. F. Graham, J. Virol. 23:250-262, 1977). To determine whether the ts⁺ phenotype of the virus was due to intragenic reversion or to the presence of an extragenic mutation suppressing the original ts defect, several clones were backcrossed to wild-type reovirus, and the progeny of each cross were screened for temperature sensitivity. The results indicated that the original tsC lesion had reverted. However, in two of the seven clones examined, new ts lesions were found. These new ts lesions appeared phenotypically as ts⁺ due to the presence of extragenic suppressor mutations. Temperature-sensitive mutants representing three different groups were rescued from one suppressed clone, indicating that this ts⁺ clone contained multiple ts lesions. Among the ts mutants rescued were the initial isolates of a new recombination group which we have designated H. Some of the ts mutants rescued from the suppressed clones are capable of interfering with the growth of wild-type reovirus and may play a role in maintaining the carrier state. The results of this study show that persistently infected L cells contain a genetically heterogeneous population of reovirus even though all virus clones express the ts⁺ phenotype. It is thus critical to distinguish between genotype and phenotype when analyzing viruses that emerge during persistent infection.     

Double-sides sticking mechanism of vinblastine interacting with α,β-tubulin to get activity against cancer cells

Abstract

Vinblastine (VLB) and its derivatives have been used for clinical first-line drugs to treat various cancers. Due to the resistance and serious side effects from using VLB and its derivatives, there is a need to discover and develop novel VLB derivatives with high activity against cancer cells. In order to better discover and develop new VLB derivatives, we need to study the structural basis of VLB's anti-cancer cytotoxicity and the mechanism of its interaction with α,β-tubulins. Based on the crystal structure of α,β-microtubule complex protein, the molecular dynamics method including the sampling PMF method was used to study the variation of dissociation free energy (ΔG) of α,β-tubulins under different system conditions, and then from which to study the mechanism of the interaction between VLB and α,β-tubulins. The obtained results show that the dissociation of pure α,β-tubulins requires 197.8?kJ·mol^?1 for ΔG. When the VLB molecule exists between the interface of α,β-tubulins, the dissociation ΔG of α,β-tubulins reaches 220.5?kJ·mol^?1, which is greater than that of pure α,β-tubulin. The VLB molecule is formed by connecting a vindoline moiety (VM) molecule with a catharanthine moiety (CM) molecule through a carbon-carbon bond, which is a larger molecule. When the CM molecule exists in the middle of α,β-tubulin interface, the dissociation ΔG of α,β-tubulins is 46.2?kJ·mol^?1, during which the CM moves with β-tubulin. When the VM molecule exists between the middle of α,β-tubulin interface, the dissociation ΔG of α,β-tubulins is 86.7?kJ·mol^?1, during which it moves with α-tubulin. Therefore, the VLB molecule is like a double-sides tape to stick α-tubulin and β-tubulin together. The VLB molecule intervenes the dynamic equilibrium between dissociation and aggregation of α-tubulin and β-tubulin by a double-sides sticking mechanism to exert high activity with toxicity against cancer cell. Besides, our results demonstrate that VLB has its structural basis for anticancer cytotoxicity due to its two compositions composed of a CM molecule and a VM molecule although they have little toxicity against cancer cell alone.     

Extragenic suppressor mutations of a β-tubulin mutation in the basidiomyceteCoprinus cinereus: Isolation and genetic and biochemical analyses

In total, 111 revertants were isolated from the oidia of a heat-sensitive, -tubulin mutant BEN193 (benA193) of the basidiomyceteCoprinus cinereus after mutagenesis by ultraviolet. Of the 111 revertants, 48 were genetically analyzed. In 15 of the 48 revertants, reversion was due to mutations at loci unlinked tobenA, whereas in the remaining 33 revertants, reversion was due to mutations withinbenA or at loci closely linked tobenA. The 15 extragenic suppressor mutations comprised three groups in terms of genetic linkage; two of them were designated asmipA andmipB. Suppressor mutations in the third group were found to bebenC, one of the four loci we have previously identified as genes conferring benomyl resistance. Biochemical analysis revealed thatbenC ⁺ is a structural gene for a major -tubulin in vegetative hyphae.     

Evolution of the multi-tubulin hypothesis

Microtubules are organized into diverse cellular structures in multicellular organisms. How is such diversity generated? Although highly conserved overall, variable regions within α- and β-tubulins show divergence from other α- and β-tubulins in the same species, but show conservation among different species. Such conservation raises the question of whether diversity in tubulin structure mediates diversity in microtubule organization. Recent studies probing the function of β-tubulin isotypes in axonemes of insects⁽¹⁾ suggest that tubulin structure, through interactions with extrinsic proteins, can direct the architecture and supramolecular organization of microtubules.     

Tubulin Genes in the Algal Protist Euglena gracilis

ABSTRACT Alpha- and beta-tubulin cDNA were selected from a Euglenaλgt11 expression library, recloned and either sequenced (α-tubulin cDNA) or hybridized to Euglena RNA and DNA (α- and β-tubulin cDNA). RNA for hybridization was extracted at 30 minute intervals after flagellar amputation and quantitated for cDNA binding. Unlike previous reports on most other flagellates, no net increase in either α- or β-tubulin RNA could be detected during regeneration—suggesting steady state or constitutive tubulin RNA synthesis. Incubation of the cDNA with genomic DNA after restriction digestion produced patterns of hybridization consistent with the presence of one to two kinds each of the α- and β-tubulin genes. The deduced amino acid sequence of the α-tubulin cDNA was more than 90% identical to the α-tubulins of Trypanosoma, Chlamydomonas, Naegleria, Tetrahymena and higher plants. The carboxy terminus of the α-tubulin cDNA and the previously sequenced β-tubulin of Euglena showed greatest identity to the carboxy terminus of the tubulins from Trypanosoma brucei. The sequence data for α and β-tubulins of Euglena provides direct evidence for the similarity of two gene products from euglenas and trypanosomes and adds support to earlier suggestions that these organisms are phylogenetically related.     

Molecular cloning and biochemical characterization of α- and β-tubulin from potato plants (Solanum tuberosum L.)

Few studies have investigated microtubules from plants that host pathogenic fungi. Considerable efforts are underway to find an antimitotic agent against plant pathogens like Phytophthora infestans. However, screening the effects of antifungal agents on plant tubulin in vivo or using purified native microtubule in vitro is a time consuming process. A recombinant, correctly folded, microtubule-like structure forming tubulin could accelerate research in this area. In this study, we cloned full length cDNAs isolated from potato leaves using reverse-transcribed polymerase chain reaction (RT-PCR). Solanum tuberosum (Stub) α-tubulin and β-tubulin were predicted to encode 449 and 451 amino acid long proteins with molecular masses of 57 kDa and 60 kDa, respectively. Average yields of α- and β-tubulin were 2.0–3.5 mg l^?1 and 1.3–3.0 mg l^?1 of culture, respectively. The amino acids, His6, Glu198, and Phe170 involved in benomyl sensitivity were conserved in Stub tubulin. The dimerization of tubulin monomers was confirmed by western blot analysis. When combined under appropriate conditions, these recombinant α- and β-tubulins were capable of polymerizing into microtubules. Accessibility of cysteine residues of tubulin revealed that important ligand binding sites were folded correctly. This recombinant tubulin could serve as a control of phytotoxicity of selected antimitotic fungicide compounds during in vitro screening experiments.     

Phenethyl isothiocyanate induces cell cycle arrest and reduction of alpha- and beta-tubulin isotypes in human prostate cancer cells

This study was to investigate the effect of phenethyl isothiocyanate (PEITC), a constituent of many edible cruciferous vegetables, on the expression of α- and β-tubulins, which are the main components of microtubules in prostate cancer cells. Flow cytometry, light microscopy and western blot were used to study the cell cycle distribution, morphology changes and the expression of α- and β-tubulins in prostate cancer cells treated with PEITC. The results showed that PEITC-induced G2-M cell phase arrest and inhibited the expression of α- and β-tubulin proteins in a number of human prostatic carcinoma cell lines. Further, it is showed that this inhibitory effect could be reversed by antioxidant N-acetyl cysteine and proteasome inhibitor MG132. Finally, it is concluded that PEITC inhibited the expression of α- and β-tubulins in prostate cancer cells, which is at least related to the oxygen reaction species and protein degradation.     

New Late Gene, dar, Involved in DNA Replication of Bacteriophage T4 I. Isolation, Characterization, and Genetic Location

Suppressors of gene 59-defective mutants were isolated by screening spontaneous, temperature-sensitive (ts) revertants of the amber mutant, amC5, in gene 59. Six ts revertants were isolated. No gene 59-defective ts recombinant was obtained by crossing each ts revertant with the wild type, T4D. However, suppressors of gene 59-defective mutants were obtained from two of these ts revertants. These suppressor mutants are referred to as dar (DNA arrested restoration). dar mutants specifically restored the abnormalities, both in DNA synthesis and burst size, caused by gene 59-defective mutants to normal levels. It is unlikely that dar mutants are nonsense suppressors since theý failed to suppress amber mutations in 11 other genes investigated. The genetic expression of dar is controlled by gene 55; therefore, dar is a late gene. The genetic location of dar has been mapped between genes 24 and 25, a region contiguous to late genes. dar appears to be another nonessential gene of T4 since burst sizes of dar were almost identical to those of the wild type. Mutations in dar did not affect genetic recombination and repair of UV-damaged DNA, but caused a sensitivity to hydroxyurea in progeny formation. The effect of the dar mutation on host DNA degradation cannot account for its hydroxyurea sensitivity. dar mutant alleles were recessive to the wild-type allele as judged by restoration of arrested DNA synthesis. The possible mechanisms for the suppression of defects in gene 59 are discussed.     

Host mutant (tabD)-induced inhibition of bacteriophage T4 late transcription: II. Genetic characterization of mutants

In this paper we show that the tabD mutants, selected with ts553 or tsCB53, and described in the accompanying paper (Coppo et al., 1975): (a) are recessive to tab⁺; (b) fail to complement each other, and thus map in the same cistron; (c) by their linkage to rif and their dominance relationships with well characterized amber mutations in the Escherichia coli RNA polymerase operon, probably all map in the gene controlling the synthesis of the β′ subunit of the enzyme. We also describe the isolation of a ts⁺, k^D mutant in phage T4 gene 55, used in the selection of a new tabD mutant (tabD^k292). This tab mutant: (a) generates a defective phenotype which differs somewhat from that of the other tabD mutants; (b) complements the other tabD mutants; (c) by its dominance relationship to amber mutants in the RNA polymerase operon, can be assigned to the structural gene coding for the β subunit of the enzyme.A new type of interaction between T4 genes 55 and 45 is also described. The k^D properties of ts553 (gene 55) are suppressed at 30 °C, by a temperature-sensitive mutation in gene 45. This type of interaction between missense mutations in genes 45 and 55 apparently occurs even in tab⁺ strains, since temperature-sensitive mutations in gene 45 accumulate in lysates of two gene 55 mutants (ts553 and tsA81).     

Analysis of β-tubulin cDNAs from taxol-resistant Pestalotiopsis microspora and taxol-sensitive Pythium ultimum and comparison of the taxol-binding properties of their products

The anti-cancer drug taxol binds to β-tubulin in assembled microtubules and causes cell cycle arrest in animal cells; in contrast, in fungi, the effect of taxol varies. For instance, the taxol-producer Pestalotiopsis microspora Ne32, an ascomycete, is resistant to taxol (IC₅₀ greater than 11.7?μM), whereas Pythium ultimum, an oomycete, is sensitive to taxol (IC₅₀ 0.1?μM). In order to understand the differential fungal response to taxol, we isolated cDNAs encoding β-tubulin from both P. microspora and P. ultimum. The deduced amino acid sequence of β-tubulin from P. microspora is very similar to those from other Ascomycetes, many of which are resistant to taxol. The sequence of β-tubulin from P. ultimum is very similar to those from Oomycetes and non-fungal organisms, many of which are sensitive to taxol. To examine the interaction between taxol and fungal microtubules, binding studies were performed with fungal cells, using [³H]taxol. The labeled taxol was found to bind specifically to P. ultimum, but not to P. microspora. In addition, the amount of [³H]taxol specifically bound to P. ultimum was reduced by the microtubule-depolymerizing drug thiabendazole, in a dose-dependent manner. These results suggest efficient binding of taxol to microtubules in P. ultimum, but not in P. microspora, and are consistent with the differential taxol sensitivity of these two organisms. Finally a comparison of previously characterized taxol binding sites in various β-tubulin sequences showed that β-tubulins of taxol-sensitive organisms, including P. ultimum, contain Thr219, but β-tubulins of resistant organisms, including P. microspora, contain Asn or Gln at this position, suggesting an important role for residue 219 in the interaction between taxol and β-tubulin.     

Ovary-autonomous maternal inheritance at a developmental locus in Drosophila

The sex-linked temperature-sensitive mutation shibire^ts of Drosophila melanogaster shows a maternal effect causing embryonic lethality at 29°C. The maternal influence is due to gene action autonomous to the ovary. Embryos carrying the paternally derived wild-type gene can survive at 29°C but only if heat pulses are begun at least 9 hr after oviposition. The paternal rescue is presumably due to zygotic gene action at this locus beginning part way through embryogenesis. A maternal wild-type genome, however, can produce shi embryos that have sufficient shi⁺ product to support embryogenesis up to the hatching stage even at 29°C.     

Genetic evidence for interaction between eta- and beta-tubulins

The thermosensitive allelic mutations sm19-1 and sm19-2 of Paramecium tetraurelia cause defective basal body duplication: growth at the nonpermissive temperature yields smaller and smaller cells with fewer and fewer basal bodies. Complementation cloning of the SM19 gene identified a new tubulin, eta-tubulin, showing low homology with each of the other five tubulins, α to , characterized in P. tetraurelia. In order to analyze η-tubulin functions, we used a genetic approach to identify interacting molecules. Among a series of extragenic suppressors of the sm19-1 mutation, the su3-1 mutation was characterized as an E288K substitution in the β-PT2 gene coding for a β-tubulin, while the mutation noc^r1 conferring nocodazole resistance and localized in another β-tubulin gene, β-PT3, was shown to enhance the mutant phenotype. The interaction between η-tubulin and microtubules, revealed by genetic data, is supported by two further types of evidence: first, the mutant phenotype is rescued by taxol, which stabilizes microtubules; second, molecular modeling suggests that η-tubulin, like γ- and δ-tubulins, might be a microtubule minus-end capping molecule. The likely function of η-tubulin as part of a complex specifically involved in basal body biogenesis is discussed.     

Cytochrome c peroxidase from a methylotrophic yeast: physiological role and isolation

Mutant strains of the methylotrophic yeast Hansenula polymorpha defective in catalase (cat) and in glucose repression of alcohol oxidase synthesis (gcr1) have been isolated following multiple UV mutagenesis steps. One representative gcr1 cat mutant C-105 grows during batch cultivation in a glucose/methanol medium. However, growth is preceded by a prolonged lag period. C-105 and other gcr1 cat mutants do not grow on methanol medium without an alternative carbon source. A large collection of second-site suppressor catalase-defective (scd) revertants were isolated with restored ability for methylotrophic growth (Mth⁺) in the absence of catalase activity. These Mth⁺ gcr1 cat scd strains utilize methanol as a sole source of carbon and energy, although biomass yields are reduced relative to the wild-type strain. In contrast to the parental C-105 strain, H₂O₂ does not accumulate in the methanol medium of the revertants. We show that restoration of methylotrophic growth in the suppressor strains is strongly correlated with increased levels of the alternative H₂O₂-destroying enzyme, cytochrome c peroxidase. Cytochrome c peroxidase from cell-free extracts of one of the scd revertants has been purified to homogeneity and crystallized. Received: 9 December 1996 / Received revision: 5 May 1997 / Accepted: 25 May 1997     

Conditionally lethal tubA alpha-tubulin mutations in Aspergillus nidulans

Summary We have mapped 17 extragenic suppressors of benA 33, a heat-sensitive -tubulin mutation of Aspergillus nidulans, to the tubA tubulin locus. Fifteen of these tubA mutations cause cold sensitivity in a genetic background with benA 33 and appear to cause lethality in a background with the wild-type benA allele. We examined the microtubule-mediated processes, nuclear division and nuclear migration, in seven different cold-sensitive double mutants, each carrying benA 33 and a different cold-sensitive tubA allele. Nuclear division and migration were inhibited at a restrictive temperature in each case, suggesting that cold sensitivity is due to the inhibition of microtubule function at low temperatures. A single allele, tubA4, suppressed the heat sensitivity conferred by benA33 but did not confer cold sensitivity in a benA33 background, however in a wildtype benA background, tubA4 conferred supersensitivity to antimicrotubule agents and weak cold sensitivity. TubA4 did not suppress the heat sensitivity conferred by two other benA alleles. The cold sensitivity conferred by tubA4 was suppressed by the microtubule stabilizing agent deuterium oxide, and the suppression of heat sensitivity conferred by four other tubA mutations was reversed by deuterium oxide. These results suggest that these mutations may affect hydrophobic interactions between -and -tubulin.     

Cotransformation of Aspergillus nidulans: a tool for replacing fungal genes

Summary When a non-selected DNA sequence was added during the transformation of amdS320 deletion strains of Aspergillus nidulans with a vector containing the wild-type amdS gene the AmdS⁺ transformants were cotransformed at a high frequency. Cotransformation of an amdS320, trpC801 double mutant strain showed that both the molar ratio of the two vectors and the concentration of the cotransforming vector affected the cotransformation frequency. The maximum frequency obtained was defined by the gene chosen as selection marker for transformation. Cotransformation was used to induce a gene replacement in A. nidulans. An amdS320 strain was transformed to AmdS⁺ and cotransformed with a DNA fragment containing a fusion between a non-functional A. nidulans trpC gene and the Escherichia coli lacZ gene. Ten AmdS⁺, LacZ⁺ transformants with a Trp^– mutant phenotype were selected. All of these strains could be transformed with a functional copy of the A. nidulans trpC gene, but only two strains yielded TrpC⁺ transformants which, with a low frequency, had a LacZ^– phenotype. These latter transformants had also lost the AmdS⁺ phenotype. Southern blotting analysis of DNA from these transformants confirmed the inactivation of the wild-type trpC gene, but revealed that amdS vector sequences were also involved in the gene replacement events.     

During mitosis ZEB1 “switches” from being a chromatin-bound epithelial gene repressor,to become a microtubule-associated protein

Microtubules are polymers of α/β-tubulin, with microtubule organization being regulated by microtubule-associated proteins (MAPs). Herein, we describe a novel role for the epithelial gene repressor, zinc finger E-box-binding homeobox 1 (ZEB1), that “switches” from a chromatin-associated protein during interphase, to a MAP that associates with α-, β- and γ-tubulin during mitosis. Additionally, ZEB1 was also demonstrated to associate with γ-tubulin at the microtubule organizing center (MTOC). Using confocal microscopy, ZEB1 localization was predominantly nuclear during interphase, with α/β-tubulin being primarily cytoplasmic and the association between these proteins being minimal. However, during the stages of mitosis, ZEB1 co-localization with α-, β-, and γ-tubulin was significantly increased, with the association commonly peaking during metaphase in multiple tumor cell-types. ZEB1 was also observed to accumulate in the cleavage furrow during cytokinesis. The increased interaction between ZEB1 and α-tubulin during mitosis was also confirmed using the proximity ligation assay. In contrast to ZEB1, its paralog ZEB2, was mainly perinuclear and cytoplasmic during interphase, showing some co-localization with α-tubulin during mitosis. Considering the association between ZEB1 with α/β/γ-tubulin during mitosis, studies investigated ZEB1's role in the cell cycle. Silencing ZEB1 resulted in a G₂-M arrest, which could be mediated by the up-regulation of p21^Waf1/Cip1 and p27^Kip1 that are known downstream targets repressed by ZEB1. However, it cannot be excluded the G₂/M arrest observed after ZEB1 silencing is not due to its roles as a MAP. Collectively, ZEB1 plays a role as a MAP during mitosis and could be functionally involved in this process.