Increasing tubC beta-tubulin synthesis by placing it under the control of a benA beta-tubulin upstream sequence causes a reduction in benA beta-tubulin level but has no effect on microtubule function

We have constructed a chimeric beta-tubulin gene that places the structural gene for the tubC beta-tubulin of Aspergillus nidulans under the control of the benA beta-tubulin promoter. Introduction of either this chimeric gene or a second wild-type benA gene into a benomyl-resistant benA22 strain causes it to become benomyl sensitive, indicating that the introduced genes are functional. Analysis of the tubulin proteins synthesized in benA22 strains into which a second wild-type benA beta-tubulin gene was transformed showed that the total amount of beta-tubulin protein was the same as in the parental strain with a single benA gene. Thus the level of beta-tubulin must be regulated. This was also true of transformants carrying an extra copy of the chimeric beta-tubulin gene. The total amount of beta-tubulin was the same as in the parental strain. Two-dimensional gel analysis showed that the endogenous benA22 and the introduced chimeric tubC gene contributed equally to the total beta-tubulin pool. The fact that one-half of the benA beta-tubulin could be replaced by tubC beta-tubulin with no effect on the growth of the cells suggests that the benA and tubC beta-tubulins are functionally interchangeable.     

Involvement of a particular species of beta-tubulin (beta 3) in conidial development in Aspergillus nidulans

Strains of Aspergillus containing the benA22 mutation are resistant to benomyl for vegetative growth but do not produce conidia. To test whether conidiation involved an additional benomyl-sensitive tubulin (i.e., was mediated by a tubulin other than the tubulins coded for by the benA locus), a collection of mutants was produced that formed conidia in the presence of benomyl, i.e., were conidiation-resistant (CR-) mutants. We analyzed the tubulins of these CR- mutants using two-dimensional gel electrophoresis and found that the mutants lacked one species of beta-tubulin (designated beta 3). We have examined two of these mutants in detail. In crosses with strains containing wild-type tubulins, we found that the absence of the beta 3-tubulin co-segregated perfectly with the CR- phenotype. In diploids containing both the benA22 and CR- mutations, we found that the CR- phenotype was recessive and that beta 3-tubulin was present on two-dimensional gels of tubulins prepared from these diploids. In another set of crosses, these two CR- strains and seven others were first made auxotrophic for uridine and then crossed against strains that had homologously integrated a plasmid containing an incomplete internal fragment of the beta 3-tubulin gene and the pyr4 gene of Neurospora crassa (which confers uridine prototrophy on transformants). If the CR- phenotype were produced by a mutation in a gene distinct from the structural gene for beta 3-tubulin (designated the tubC gene), then crossing over should have produced some CR+ segregants among the uridine auxotrophic progeny of the second cross. All of the uridine auxotrophs from this type of cross, however, showed the CR- phenotype, suggesting that the mutation in these strains is at or closely linked to the tubC locus. The most obvious explanation of these results is that beta 3-tubulin is ordinarily used during conidiation and the presence of this species of beta-tubulin renders conidiation sensitive to benomyl. In the CR- mutants, beta 3-tubulin is absent, and in the presence of the benA22 mutation the benomyl-resistant beta 1-and/or beta 2-tubulin substitutes for beta 3 to make conidiation benomyl resistant. We discuss these results and give two models to explain the interactions between these beta-tubulin species.     

Characterization of an inducible expression system in Aspergillus nidulans using alcA and tubulin-coding genes

Plasmids have been constructed in which expression of a gene can be placed under the control of the inducible promoter of the alcA gene encoding alcohol dehydrogenase I in Aspergillus nidulans. Simplified shuttle vectors carrying pyr4 which complements pyrG89 mutations have also been constructed. These are based on pUC19 and retain alpha-peptide expression. The beta-tubulin genes, tubC and benA, have been placed under the control of alcA and their expression studied. Levels of expression can be assayed phenotypically because increased synthesis of beta-tubulin inhibits vegetative growth. Sensitivity of asexual spore formation to the anti-microtubule drug benomyl provides a means of detecting very low levels of expression of the chimeric genes. Glucose almost completely represses the chimeric genes. Induction is rapid and is maximal within an hour. When a strain carrying seven copies of an alcA::tubC gene fusion was grown under inducing conditions, 6.5% of total sulfate labelled protein consisted of tubC product. Cyclopentanone was the most potent inducer of the chimeric genes on solid media but it also partially inhibited growth. Chimeric alcA::tubC and alcA::benA genes were expressed to very similar levels despite the fact that tubC utilizes many rare codons.     

Tubulins in Aspergillus nidulans

The discovery and characterization of the tubulin superfamily in Aspergillus nidulans is described. Remarkably, the genes that encode alpha-, beta-, and gamma-tubulins were all identified first in A. nidulans. There are two alpha-tubulin genes, tubA and tubB, two beta-tubulin genes, benA and tubC, and one gamma-tubulin gene, mipA. Hyphal tubulin is encoded mainly by the essential genes tubA and benA. TubC is expressed during conidiation and tubB is required for the sexual cycle. Promoter swapping experiments indicate that the alpha-tubulins encoded by tubA and tubB are functionally interchangeable as are the beta-tubulins encoded by benA and tubC. BenA mutations that alter resistance to benzimidazole antimicrotubule agents are clustered and define a putative binding region for these compounds. gamma-Tubulin localizes to the spindle pole body and is essential for mitotic spindle formation. The phenotypes of mipA mutants suggest, moreover, that gamma-tubulin has essential functions in addition to microtubule nucleation.     

Identification of an amino acid substitution in the benA, beta-tubulin gene of Aspergillus nidulans that confers thiabendazole resistance and benomyl supersensitivity

We are using molecular genetic techniques to identify sites of interaction of beta-tubulin with benzimidizole anti-microtubule agents. We have developed a marker-rescue technique for cloning mutant alleles of the benA, beta-tubulin gene of Aspergillus nidulans and have used the technique to clone two mutant benA alleles, benA16 and benA19. These are the only A. nidulans alleles known to confer resistance to the benzimidazole antimicrotubule agent thiabendazole and supersensitivity to other benzimidazole antimicrotubule agents including benomyl and its active breakdown product, carbendazim. benA16 has been shown, moreover, to reduce thiabendazole binding to beta-tubulin. We have sequenced the two mutant alleles and have found that they carry different nucleotide changes that cause the same single amino acid substitution, valine for alanine at amino acid 165. Since thiabendazole and carbendazim differ at only one side chain, the R2 group, we conclude that the region around amino acid 165 is involved in the binding of the R2 group of benzimidazole antimicrotubule agents to beta-tubulin.     

Isolation and sequence analysis of a beta-tubulin gene from Aspergillus flavus and its use as a selectable marker

An altered beta-tubulin gene that confers resistance to benomyl [whose active ingredient is 2-(methoxycarbonylamino)benzimidazole (MBC)] was isolated from a DNA library of Aspergillus flavus and used as a selectable marker for transformation. The beta-tubulin gene was cloned into a plasmid vector containing the pyr-4 gene of Neurospora crassa, and transformants were selected either for uracil prototrophy or MBC resistance. Transformants selected for uracil prototrophy were of three phenotypic classes: sensitive, intermediate, and resistant to MBC. Transforming DNA appeared to integrate at several sites in the genome, with the more resistant phenotypes having more copies of the altered beta-tubulin gene than the sensitive and intermediate phenotypes. Transformants were also selected on medium containing MBC. The average frequency of transformation (1 to 3 transformants per micrograms of transforming DNA) was lower than that obtained by selection for uracil prototrophy, presumably because of failure to select transformants that contained few copies of the altered beta-tubulin gene. The sequence of the beta-tubulin gene was determined and compared with the published sequence of the benA gene of A. nidulans; the beta-tubulin gene was found to be highly conserved between the two Aspergillus species. Notable differences were that the beta-tubulin gene of A. flavus lacks intron 6 present in benA and has an additional leucine at position 148. This is the first gene sequence reported from an aflatoxin-producing fungus and adds to the growing body of knowledge of the beta-tubulin genes and their use as selectable markers for transformation of filamentous fungi.     

Aspergillus contains multiple tubulin genes

Previous work with benomyl-resistant mutants of Aspergillus nidulans has demonstrated that the benA locus is a structural gene for beta-tubulin. Two of the benA mutants, benA22 and benA85, show altered electrophoretic mobilities on two-dimensional gels for two beta-tubulins (designated beta 1 and beta 2). These shifts of the beta 1- and beta 2-tubulins uncover a spot in the region where wild-type beta-tubulins migrate that is occluded on gels of wild-type extracts by the beta 1- and beta 2-tubulins. Evidence has now been obtained indicating that this spot represents an additional beta-tubulin (designated beta 3). Tubulin was partially purified from Aspergillus and run on one- and two-dimensional gels and the band or spot uncovered by the shift of the beta 1- and beta 2-tubulins was identified as a beta-tubulin by immunoblotting with monoclonal and affinity-purified polyclonal anti-tubulin antibodies and by one-dimensional peptide mapping. These observations show that Aspergillus contains at least two structural genes for beta-tubulins. Similar techniques have also been applied to a mutant showing altered alpha-tubulins to confirm and modify earlier observations suggesting that at least two structural genes for alpha-tubulins are also present.     

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.     

Sequences that confer beta-tubulin autoregulation through modulated mRNA stability reside within exon 1 of a beta-tubulin mRNA

Synthesis of alpha- and beta-tubulin is controlled in animal cells by a novel autoregulatory mechanism: the concentration of unpolymerized subunits specifies the level of tubulin mRNAs. Using transient DNA transfection, we have localized the sequences that identify a beta-tubulin RNA as a substrate for autoregulation. Insertion of as few as 106 nucleotides (57 bases of 5' untranslated region and 49 coding nucleotides) from a beta-tubulin gene into a thymidine kinase gene is sufficient to make expression of the resultant chimeric RNA regulated as if it were an authentic beta-tubulin mRNA. Furthermore, all 5' untranslated region sequences can be deleted without disrupting regulation. We conclude that this novel autoregulatory pathway is specified by cytoplasmic events that modulate mRNA stability through sequences lying within the first 16 translated codons of a beta-tubulin mRNA.     

Replication of a plasmid containing two origins of bacteriophage f1

A chimeric plasmid was constructed that contains a tandem duplication of the bacteriophage f1 origin of DNA replication. This plasmid replicates stably in the absence of phage. When cells carrying this plasmid are infected with f1, two new plasmid-derived DNA species are generated: a smaller, chimeric plasmid containing only one f1 origin of replication, and a miniphage, the genome of which consists of the f1 fragment that was located between the two f1 origins of the original plasmid. These data support the hypothesis (Horiuchi, 1980) that the nucleotide sequence recognized for initiation of plus strand synthesis in f1 DNA replication is also the signal for its termination.     

Identification and functional analysis of beta-tubulin genes by site specific integrative transformation in Aspergillus nidulans

We have cloned two different beta-tubulin sequences from the filamentous fungus Aspergillus nidulans. Each was used in the construction of transforming plasmids that carry the pyr4 gene of Neurospora crassa. We used these plasmids to transform a pyrG-strain of Aspergillus to uridine prototrophy. Both plasmids were shown to integrate site specifically into the homologous chromosomal sequences. We then used transformant strains in genetic crosses to demonstrate that one of the cloned beta-tubulin sequences was the benA beta-tubulin gene, which codes for the beta 1-and beta 2-tubulins. The other cloned beta-tubulin sequence was shown to be the structural gene for beta 3-tubulin by gene disruption and to participate in conidial development. This is the first report of a gene disruption by site specific, integrative recombination in Aspergillus nidulans.     

Isolation of mip (microtubule-interacting protein) mutations of Aspergillus nidulans.

We identified four mutations in two previously undescribed loci involved in microtubule function in Aspergillus nidulans as extragenic suppressors of benA33, a heat-sensitive beta-tubulin mutation. Three of the four mutations map to a locus closely linked to riboB on linkage group VIII; we designated this locus mipA (for microtubule-interacting protein). We were not able to map the remaining suppressor because of chromosomal rearrangements. However, since it recombines with riboB at a significantly higher frequency than the mipA alleles, it is unlikely to be in mipA; thus, we designated it mipB1. The mip mutations are not allelic to the previously identified loci that encode alpha- and beta-tubulin, and it is likely that mipA and mipB encode previously unidentified nontubulin proteins involved in microtubule function. Each of the mip mutations suppresses the heat sensitivity conferred by benA33 and suppresses the blockage of nuclear division and movement conferred by this mutation at high temperatures. Interactions between mipA and benA are allele specific. All of the mipA mutations are cryptic in a wild-type benA background but cause cold sensitivity in combination with benA33. These mutations also confer cold sensitivity in combination with benA31 and benA32 and reduce the resistance conferred by these mutations to the antimicrotubule agent benomyl but do not suppress the heat sensitivity conferred by these alleles. Finally, the mipA alleles suppress the heat sensitivity conferred by benA11, benA17, and benA21 but do not confer cold sensitivity in combination with these alleles.     

Construction of recA mutants of Acholeplasma laidlawii by insertional inactivation with a homologous DNA fragment.

Mycoplasmas (class Mollicutes) are wall-less prokaryotes phylogenetically related to gram-positive bacteria. This study describes the construction of recA mutants of the mycoplasma Acholeplasma laidlawii. An internal fragment of the recA gene from A. laidlawii was cloned into a plasmid that does not replicate in this organism. When this plasmid construct was used to transform A. laidlawii, it inserted into the chromosome, disrupting the recA gene. The phenotype of the resulting recA mutant was compared to that of wild-type cells and to that of a strain that has a naturally occurring ochre mutation in its recA gene. As found in other bacterial systems, loss of RecA activity resulted in cells deficient in DNA repair.     

Restriction map of the Escherichia coli malA region and identification of the malT product.

A series of plaque-forming lambda h80 transducing phages carrying various portions of the malA region were isolated. A 5,800-base pair HindIII-EcoRI DNA fragment from one of these phages was cloned into pBR322 and shown to contain malT, which is the positive regulator gene of the maltose regulon, and most of malP, the structural gene for maltodextrin phosphorylase. A restriction map of the HindIII-EcoRI fragment was established, and it was correlated with the genetic map of the malA region (i) by mapping deletions which had been generated in vitro on the plasmid and (ii) by locating on the restriction map a DNA insertion of known genetic position. A 600-base pair HincII-HaeII segment was shown to contain all or part of the promoters for malT and malP, which are known to be transcribed in opposite directions. Strains carrying gene malT on a plasmid synthesized a 94,000-dalton polypeptide which was not produced by identical strains carrying similar plasmids in which malT was partially deleted. Estimates of the size of the malT gene support the conclusion that the 94,000-dalton polypeptide is the malT product.     

Cloning of a gene cluster encoding biphenyl and chlorobiphenyl degradation in Pseudomonas pseudoalcaligenes.

A gene cluster encoding biphenyl- and chlorobiphenyl-degrading enzymes was cloned from a soil pseudomonad into Pseudomonas aeruginosa PAO1161. Chromosomal DNA from polychlorinated biphenyl-degrading Pseudomonas pseudoalcaligenes KF707 was digested with restriction endonuclease XhoI and cloned into the unique XhoI site of broad-host-range plasmid pKF330. Of 8,000 transformants tested, only 1, containing the chimeric plasmid pMFB1, rendered the host cell able to convert biphenyls and chlorobiphenyls to ring meta cleavage compounds via dihydrodiols and dihydroxy compounds. The chimeric plasmid contained a 7.9-kilobase XhoI insert. Subcloning experiments revealed that the genes bphA (encoding biphenyl dioxygenase), bphB (encoding dihydrodiol dehydrogenase), and bphC (encoding 2,3-dihydroxybiphenyl dioxygenase) were coded for by the 7.9-kilobase fragment. The gene order was bphA-bphB-bphC. The hydrolase activity, which converted the intermediate meta cleavage compounds to the final product, chlorobenzoic acids, and was encoded by a putative bphD gene, was missing from the cloned 7.9-kilobase fragment.     

fii, a bacterial locus required for filamentous phage infection and its relation to colicin-tolerant tolA and tolB.

We describe mutations in a new bacterial locus, designated fii, which do not allow the filamentous bacteriophage f1 to infect bacteria harboring the F plasmid. Mutations at this locus do not affect the ability of F plasmid-containing bacteria to undergo conjugation or be infected by the F plasmid-specific RNA phage f2. The filamentous phage can still adsorb to the F sex pilus, but the DNA is unable to enter the bacteria. All fii mutants become tolerant to colicins E1, E2, and E3. Strains with amber mutations in fii also are unable to plaque P1, even though they can be infected with this phage. Mutations in fii also prevent infection of bacteria harboring the N plasmid by the filamentous bacteriophage IKe. The fii locus maps adjacent to tolA, mutants of which demonstrate tolerance to high levels of the E and K colicins. The three genes tolA, tolB, and fii are shown to reside on a 4.3-kilobase fragment of the Escherichia coli chromosome. Each gene has been cloned into a chimeric plasmid and shown to complement, in trans, mutations at the corresponding chromosomal locus. Studies in maxicells show that the product of fii appears to be a 24-kilodalton protein which copurifies with the cell envelope. The product of tolA has been identified tentatively as a 51-kilodalton protein. Data from cloning, Tn5 mutagenesis, and P1 transduction studies are consistent with the gene order sucA-fii-tolA-tolB-aroG near 17 min on the E. coli map.     

Direct and indirect gene replacements in Aspergillus nidulans.

We performed three sets of experiments to determine whether cloned DNA fragments can be substituted for homologous regions of the Aspergillus nidulans genome by DNA-mediated transformation. A linear DNA fragment containing a heteromorphic trpC+ allele was used to transform a trpC- strain to trpC+. Blot analysis of DNA from the transformants showed that the heteromorphic allele had replaced the trpC- allele in a minority of the strains. An A. nidulans trpC+ gene was inserted into the argB+ gene, and a linear DNA fragment containing the resultant null argB allele was used to transform a trpC- argB+ strain to trpC+. Approximately 30% of the transformants were simultaneously argB-. The null argB allele had replaced the wild-type allele in a majority of these strains. The A. nidulans SpoC1 C1-C gene was modified by removal of an internal restriction fragment and introduced into a trpC- strain by transformation with a circular plasmid. A transformant containing a tandem duplication of the C1-C region separated by plasmid DNA was self-fertilized, and trpC- progeny were selected. All of these had lost the introduced plasmid DNA sequences, whereas about half had retained the modified C1-C gene and lost the wild-type copy. Thus, it is possible with A. nidulans to replace chromosomal DNA sequences with DNA fragments that have been cloned and modified in vitro by using either one- or two-step procedures similar to those developed for Saccharomyces cerevisiae.     

Construction of recA mutants of Acholeplasma laidlawii by insertional inactivation with a homologous DNA fragment

Mycoplasmas (class Mollicutes) are wall-less prokaryotes phylogenetically related to gram-positive bacteria. This study describes the construction of recA mutants of the mycoplasma Acholeplasma laidlawii. An internal fragment of the recA gene from A. laidlawii was cloned into a plasmid that does not replicate in this organism. When this plasmid construct was used to transform A. laidlawii, it inserted into the chromosome, disrupting the recA gene. The pheno-type of the resulting recA mutant was compared to that of wild-type cells and to that of a strain that has a naturally occurring ochre mutation in its recA gene. As found in other bacterial systems, loss of RecA activity resulted in cells deficient in DNA repair.     

Isolation of an autonomously replicating DNA fragment from the region of defective bacteriophage PBSX of Bacillus subtilis

We have isolated a 5.4-kilobase fragment of Bacillus subtilis DNA that confers the ability to replicate upon a nonreplicative plasmid. The B. subtilis 168 EcoRI fragment was ligated into the chimeric plasmid pCs540, which contains a chloramphenicol resistance determinant from the Staphylococcus aureus plasmid pC194 and an HpaII fragment from the Escherichia coli plasmid, pSC101. A recE B. subtilis derivative, strain BD224, is capable of maintaining this DNA as an autonomously replicating plasmid. In rec+ recipients, chloramphenicol-resistant transformants do not contain free plasmid. The plasmid is integrated as demonstrated by alterations in the pattern of chromosomal restriction enzyme fragments to which the plasmid hybridizes. The site of plasmid integration was mapped by PBS1-mediated transduction to the metC-PBSX region. A strain was a deletion in the region of defective bacteriophage PBSX differs in the hybridization profile obtained by probing EcoRI digests with this cloned fragment. This same deletion mutant, though proficient in normal recombinational pathways, permits autonomous replication of the plasmid apparently owing to the lack of an homologous chromosomal region with which to recombine. We believe that, like E. coli. B. subtilis contains at least one DNA fragment capable of autonomous replication when liberated from its normally integrated chromosomal site and that this cloned DNA fragment comes from the region of defective bacteriophage PBSX.