An Aspergillus nidulans nuclear protein, AnCP, involved in enhancement of Taka-amylase A gene expression, binds to the CCAAT-containing taaG2 , amdS , and gatA promoters

Using AnCP (Aspergillus nidulans CCAAT-binding protein) as a CCAAT-specific binding factor model, the possibility that one factor is able to recognize CCAAT sequences in several different genes in A.␣nidulans was examined. DNase I protection analysis showed that AnCP specifically bound to CCAAT sequence-containing regions comprising 21 to 36 bp of the taa, amdS and gatA genes. Furthermore, replacement of the CCAAT sequence with CGTAA was found to abolish the binding of AnCP and to have an inhibitory effect on taa promoter activity. This clearly demonstrates a positive function of the CCAAT element. However, amylase was induced by starch and repressed by glucose in a CCAAT-box disruptant, as in wild-type cells. Received: 28 June 1996 / Accepted: 7 October 1996     

Two uvs genes of Aspergillus nidulans with different functions in error-prone repair: uvsI , active in mutation-specific reversion, and uvsC , a recA homolog, required for all UV mutagenesis

Two genes of Aspergillus nidulans are known to function in UV mutagenesis, but have been assigned to different epistasis groups: uvsC, which is also required for meiosis and mitotic recombination, and uvsI, which may have no other function. To clarify their role in error-prone repair and to investigate their interaction, uvsI and uvsC single and uvsI;uvsC double mutant strains were further tested for mutagen sensitivities and characterized for effects on mutation. Spontaneous and induced frequencies were compared in forward and reverse mutation assays. All results confirmed that uvsI and uvsC are members of different epistasis groups, and demonstrated that these uvs mutants have very different defects in UV mutagenesis. The uvsI strains showed wild-type frequencies in all forward mutation tests, but greatly reduced spontaneous and UV-induced reversion of some, but not other, point mutations. In contrast, uvsC had similar effects in all assay systems: namely pronounced mutator effects and greatly reduced UV mutagenesis. Interestingly, the uvsI;uvsC double mutant strains differed from both single mutants; they clearly showed synergism for all types of reversion tested: none were ever obtained spontaneously, nor after induction by UV or EMS (ethylmethane sulfonate). Based on these results, we conclude that uvsI is active in a mutation-specific, specialized error-prone repair process in Aspergillus. In contrast, uvsC, which is now known to show sequence homology to recA, has a basic function in mutagenic UV repair in addition to recombinational repair, similar to recA of Escherichia coli. Received: 23 September 1996 / Accepted: 2 December 1996     

Analysis of eryBI , eryBIII and eryBVII from the erythromycin biosynthetic gene cluster in Saccharopolyspora erythraea

The gene cluster (ery) governing the biosynthesis of the macrolide antibiotic erythromycin A by Saccharopolyspora erythraea contains, in addition to the eryA genes encoding the polyketide synthase, two regions containing genes for later steps in the pathway. The region 5′ of eryA that lies between the known genes ermE (encoding the erythromycin resistance methyltransferase) and eryBIII (encoding a putative S-adenosylmethionine-dependent methyltransferase), and that contains the gene eryBI (orf2), has now been sequenced. The inferred product of the eryBI gene shows striking sequence similarity to authentic β-glucosidases. Specific mutants were created in eryBI, and the resulting strains were found to synthesise erythromycin A, showing that this gene, despite its position in the biosynthetic gene cluster, is not essential for erythromycin biosynthesis. A␣mutant in eryBIII and a double mutant in eryBI and eryBIII were obtained and the analysis of novel erythromycins produced by these strains confirmed the proposed function of EryBIII as a C-methyltransferase. Also, a chromosomal mutant was constructed for the previously sequenced ORF19 and shown to accumulate erythronolide B, as expected for an eryB mutant and consistent with its proposed role as an epimerase in dTDP-mycarose biosynthesis. Received: 13 August 1997 / Accepted: 27 November 1997     

A ras homologue of Neurospora crassa regulates morphology

In order to study the role of signal transduction pathways in the regulation of morphology in Neurospora crassa, we cloned and characterized a ras homologue, termed NC-ras2. The predicted protein product of this gene is composed of 229 amino acid residues and contains all the consensus sequences shared by the ras protein family. The gene is located in linkage group V. An NC-ras2 disruptant showed morphological characteristics very similar to those of the smco7 mutant, which also maps to linkage group V. Nucleotide sequence analysis revealed that the smco7 mutant harbored a single base deletion in the NC-ras2 gene, which is predicted to result in the truncation of the protein product. Introduction into the smco7 mutant of an NC-ras2 clone yielded stable transformants with a wild-type phenotype. The smco7 mutant exhibited very slow hyphal growth and the rate of conidial formation was approximately one two-hundredth of wild type. The smco7 mutation causes both the changes in the pattern of hyphal growth and the defects in cell wall synthesis. Both the diameter and the length of the apical compartment were shorter in the hyphae of the smco7 mutant. These results suggest that NC-ras2 is identical to smco7, and that the signal transduction pathway mediated by the NC-ras2 protein regulates the apical growth of hyphae, cell wall synthesis, and conidial formation in N. crassa. Received: 1 October 1996 / Accepted: 9 December 1996     

Characterization of a novel DNA damage-inducible gene of Saccharomyces cerevisiae , DIN7 , which is a structural homolog of the RAD2 and RAD27 DNA repair genes

A number of DNA damage-inducible genes (DIN) have been identified in Saccharomyces cerevisiae. In the present study we describe isolation of a novel gene, Din7, the expression of which is induced by exposure of cells to UV light, MMS (methyl methanesulfonate) or HU (hydoxyurea). The DNA sequence of DIN7 was determined. By comparison of the predicted Din7 amino acid sequence with those in databases we found that it belongs to a family of proteins which includes S. cerevisiae Rad2 and its Schizosaccharomyces pombe and human homologs Rad13 and XPGC; S. cerevisiae Rad27 and its S. pombe homolog Rad2, and S. pombe Exo I. All these proteins are endowed with DNA nuclease activity and are known to play an important function in DNA repair. The strongest homology to Din7 was found with the Dhs1 protein of S.␣cerevisiae, the function of which is essentially unknown. The expression of the DIN7 gene was studied in detail using a DIN7-lacZ fusion integrated into a chromosome. We show that the expression level of DIN7 rises during meiosis at a time nearly coincident with commitment to recombination. No inducibility of DIN7 was found after treatment with DNA-damaging agents of cells bearing the rad53-21 mutation. Surprisingly, a high basal level of DIN7 expression was found in strains in which the DUN1 gene was inactivated by transposon insertion. We suggest that a form of Dun1 may be a negative regulator of the DIN7 gene expression. Received: 30 May 1996 / Accepted: 26 September 1996     

Tolerance of low pH in Schizosaccharomyces pombe requires a functioning pub1 ubiquitin ligase

A strain of Schizosaccharomyces pombe carrying a disrupted Na⁺/H⁺ antiporter gene (sod2::sup3-5), in addition to the common auxotrophic mutations, ade6-216, ura4-D18 and leu1-32, is highly sensitive to media adjusted to pH 6.9. Reversion analysis of this strain yielded a group of revertants capable of growth at pH 6.9. Two of the revertants elongated and failed to form colonies at pH 3.5. Genetic characterization of one of the pH-sensitive elongated strains, J227, showed the presence of two independently segregating mutations. One, pub1 ( protein ubiquitin ligase 1), has recently been reported as an E3 protein ubiquitin ligase involved in cdc25 turnover. The second has been named elp3-1 (elongated at low pH). Genetic dissection of the original strain revealed that poor growth at high pH was due to the presence of the auxotrophic markers, suggesting a possible inhibitory effect of high pH on the function of permeases responsible for uptake of the necessary nutrients. Suppression of the high pH sensitivity required the presence of both the pub1-1 and elp3-1 mutations. While the pub1-1 mutation reduced the capacity of cells to tolerate relatively moderate concentrations of LiCl (3 mM) in liquid culture, it was capable of partially suppressing the extreme Li⁺ sensitivity caused by the sod2 disruption. Under these conditions, the growth of pub1-1 sod2::ura4 double mutant cells was improved over that of either pub1-1 or sod2::ura4 cells. The elp3-1 mutation had no effect on the Li⁺ tolerance in either wild-type or sod2::ura4 backgrounds. pub1-1 cells are elongated and incapable of colony formation at pH 3.5. In contrast, elp3-1 cells are elongated at pH 3.5 and pH␣5.5 (the normal pH of minimal medium) but can form colonies under both conditions. J227 cells are significantly longer than either single mutant at pH 3.5 and do not form colonies but are visually similar to elp3-1 cells at pH 5.5. Complementation cloning in the J227 background yielded a genomic clone of pub1, allowing us to define the intron-exon structure of the gene. Sequences with high homology to the predicted amino acid sequence of pub1 have been identified in Saccharomyces cerevisiae (RSP5/NPI1), human (hRPF1), mouse (mNedd4), and rat (rNedd4). Based on the nature of our mutant selection, the pH-sensitive phenotype of the strains selected, and the known involvement of RSP5/NPI1 in membrane permease turnover in S. cerevisiae, we hypothesize a role for pub1, either directly or indirectly, in regulating membrane transport processes. This is further supported by the broad range of effects that the pub1-1 mutation exerts on overall performance of cells at high and low external pH, and in the presence of toxic levels of Li⁺. Received: 12 September 1996 / Accepted: 19 December 1996     

Aluminum-sensitive mutants of Saccharomyces cerevisiae

We are developing budding yeast, Saccharomyces cerevisiae, as a genetic system for the study of tolerance to the trivalent aluminum cation (Al³⁺). We have isolated eight mutants that are more sensitive to Al³⁺ than the wild type. Each mutant represented a different complementation group. A number of the mutants were pleiotropic, and showed defects in other stress responses, changes in tolerance to other metal cations, or abnormal morphology. Two mutants also showed increased dependence on supplemental Mg²⁺ and Ca²⁺. One mutant with a relatively specific sensitivity to Al³⁺ was chosen for molecular complementation. Normal Al³⁺ tolerance was restored by expression of the MAP kinase gene SLT2. Strains carrying deletions of the SLT2 gene, or of the gene for the corresponding MAP kinase–kinase SLK1, showed sensitivity to Al³⁺. These results indicate that the SLT2 MAP kinase signal transduction pathway is required for yeast to sense and respond to Al³⁺ stress. Received: 17 April 1996 / Accepted: 21 October 1996     

Cloning and molecular analysis of the Arabidopsis gene Terminal Flower 1

The Arabidopsis gene Terminal Flower 1 (TFL1) controls inflorescence meristem identity. A terminal flower (tfl1) mutant, which develops a terminal flower at the apex of the inflorescence, was induced by transformation with T-DNA. Using a plant DNA fragment flanking the integrated T-DNA as a probe, a clone was selected from a wild-type genomic library. Comparative sequence analysis of this clone with an EST clone (129D7T7) suggested the existence of a gene encoding a protein similar to that encoded by the cen gene which controls inflorescence meristem identity in Antirrhinum. Nucleotide sequences of the region homologous to this putative TFL1 gene were compared between five chemically induced tfl1 mutants and their parental wild-type ecotypes. Every mutant was found to have a nucleotide substitution which could be responsible for the tfl1 phenotype. This result confirmed that the cloned gene is TFL1 itself. In our tfl1 mutant, no nucleotide substitution was found in the transcribed region of the gene, and the T-DNA-insertion site was located at 458 bp downstream of the putative polyadenylation signal, suggesting that an element important for expression of the TFL1 gene exists in this area. Received: 14 November 1996 / Accepted: 29 November 1996     

Functional dissection of a cell-division inhibitor, SulA, of Escherichia coli and its negative regulation by Lon

SulA is induced in Escherichia coli by the SOS response and inhibits cell division through interaction with FtsZ. To determine which region of SulA is essential for the inhibition of cell division, we constructed a series of N-terminal and C-terminal deletions of SulA and a series of alanine substitution mutants. Arginine at position 62, leucine at 67, tryptophan at 77 and lysine at 87, in the central region of SulA, were all essential for the inhibitory activity. Residues 3–27 and the C-terminal 21 residues were dispensable for the activity. The mutant protein lacking N-terminal residues 3–47 was inactive, as was that lacking the C-terminal 34 residues. C-terminal deletions of 8 and 21 residues increased the growth-inhibiting activity in lon ⁺ cells, but not in lon ⁻ cells. The wild-type and mutant SulA proteins were isolated in a form fused to E. coli maltose-binding protein, and tested in vitro for sensitivity to Lon protease. Lon degraded wild-type SulA and a deletion mutant lacking the N-terminal 93 amino acids, but did not degrade the derivative lacking 21 residues at the C-terminus. Futhermore, the wild-type SulA and the N-terminal deletion mutant formed a stable complex with Lon, while the C-terminal deletion did not. MBP fused to the C-terminal 20 residues of SulA formed a stable complex with, but was not degraded by Lon. When LacZ protein was fused at its C-terminus to 8 or 20 amino acid residues from the C-terminal region of SulA the protein was stable in lon ⁺ cells. These results indicate that the C-terminal 20 residues of SulA permit recognition by, and complex formation with, Lon, and are necessary, but not sufficient, for degradation by Lon. Received: 8 October 1996 / Accepted: 27 November 1996     

Flipper, a mobile Fot1-like transposable element in Botrytis cinerea

A transposable element, Flipper, was isolated from the phytopathogenic fungus Botrytis cinerea. The element was identified as an insertion sequence within the coding region of the nitrate reductase gene. The Flipper sequence is 1842 bp long with perfect inverted terminal repeats (ITRs) of 48 bp and an open reading frame (ORF) of 533 amino acids, potentially encoding for a transposase; the element is flanked by the dinucleotide TA. The encoded protein is very similar to the putative transposases of three elements from other phytopathogenic fungi, Fot1 from Fusarium oxysporum, and Pot2 and MGR586 from Magnaporthe grisea. The number of Flipper elements in strains of B. cinerea varied from 0 to 20 copies per genome. Analysis of the descendants of one cross showed that the segregation ratio of Flipper elements was 2:2 and that the copies were not linked. Received: 4 December 1996 / Accepted: 21 January 1997     

Homologous recombination involving cox2 is responsible for a mutation in the CMS-specific mitochondrial locus of Petunia

We have characterized the only mutation detected so far in S-Pcf, the mitochondrial cytoplasmic male sterility (CMS)-specific locus of petunia. This locus consists of three open reading frames (ORFs): the first contains part of atp9, an intron-less cox2 pseudogene (which does not contain the original cox2 ATG) and the unidentified reading frame urf-s; the second and third ORFs correspond to the only copies of nad3 and rps12 genes in the genome, respectively. In the cell line R13-138, which was generated from a male-sterile somatic hybrid (line SH13-138), a change in the first ORF of the S-Pcf locus has been characterized: the atp9 sequence has been lost, while exon1 of the normal copy of the cox2 gene (including the original ATG sequence) and the adjacent 5′ sequence of the petunia recombination repeat, have been introduced. The data suggest that this reorganization of mtDNA is the consequence of a homologous recombination event involving part of the cox2 coding region, and that the cox2 coding region may serve as an active site for inter- or intra-mtDNA homologous recombination. The results further suggest that in line SH13-138 (or during its maintenance in tissue culture), segregation of the S-Pcf-containing mtDNA molecules has occurred, and the mutant mtDNA is now predominant in the population. Received: 9 September 1996 / Accepted: 27 January 1997     

A germline restricted, highly repetitive DNA sequence in Paramyxineatami : an interspecifically conserved, but somatically eliminated, element

In some species of hagfish, the phenomenon of chromosome elimination occurs during embryogenesis. However, only two repetitive DNA families are known to be represented in chromosomes that are eliminated from somatic cells of the Japanese hagfish Eptatretus okinoseanus. Using molecular analyses, another germ line-restricted, highly repetitive DNA family has been detected in another Japanese hagfish, Paramyxine atami. The repeat unit of this family, which is 83 bp long, has been designated “EEPa1”, for Eliminated Element of P. atami 1. DNA filter hybridization using EEPa1 as a probe revealed that this family is shared among several species and is conserved in the germline DNA. Although eliminated, repetitive DNA that is shared interspecifically has not been reported in hagfish species, cases of chromatin diminution and chromosome elimination processes have been described previously in other organisms.The patterns and intensities of hybridization signals suggest that members of the repetitive DNA family defined by EEPa1 have undergone concerted molecular evolution. Received: 7 January 1997 / Accepted: 13 May 1997     

A novel fission yeast gene, kms1 +, is required for the formation of meiotic prophase-specific nuclear architecture

In the meiotic prophase nucleus of the fission yeast Schizosaccharomyces pombe, chromosomes are arranged in an oriented manner: telomeres cluster in close proximity to the spindle pole body (SPB), while centromeres form another cluster at some distance from the SPB. We have isolated a mutant, kms1, in which the structure of the meiotic prophase nucleus appears to be distorted. Using specific probes to localize the SPB and telomeres, multiple signals were observed in the mutant nuclei, in contrast to the case in wild-type. Genetic analysis showed that in the mutant, meiotic recombination frequency was reduced to about one-quarter of the wild-type level and meiotic segregation was impaired. This phenotype strongly suggests that the telomere-led rearrangement of chromosomal distribution that normally occurs in the fission yeast meiotic nucleus is an important prerequisite for the efficient pairing of homologous chromosomes. The kms1 mutant was also impaired in karyogamy, suggesting that the kms1 ⁺ gene is involved in SPB function. However, the kms1 ⁺ gene is dispensable for mitotic growth. The predicted amino acid sequence of the gene product shows no significant similarity to known proteins. Received: 5 September 1996 / Accepted: 21 November 1996