Molecular & general genetics : MGG最新文献

Excess DNA in the single-copy component is rarely recognized as a contributor to the C-value paradox yet the single-copy component of the pine genome is reported to comprise over 3000 Mb of DNA, in large excess over the estimated 100 Mb required for gene expression. Two hypotheses regarding the factors that might contribute to the excess low-copy-number DNA were tested. The first hypothesis proposes that the excess low-copy kinetic component is actually overestimated by reassociation data analysis. To test this, a previously published C0t curve for Pinus strobus was reanalyzed using a new estimate of genome size based on laser flow cytometry. Part of the excess low-copy-number DNA in the pine genome could be attributed to the choice of parameters used in the analysis of the reassociation data. The second hypothesis holds that diverged retrotransposons contribute to the excess low-copy DNA. Sequences randomly sampled from single-copy and low-repetitive kinetic components of the P. taeda genome were characterized. Twelve of 46 fragments cloned from these fractions were found to show sequence similarity to retroelements: hence diverged retroelements contribute to the excess low-repetitive kinetic component in the pine genome. Similarity search was shown to be a conservative method for identifying retroelements, and thus the number of retroelements in the low-copy component was actually underestimated. Most of the retroelements in this fraction were nonfunctional. divergent from known retroelement families and previously reported only for flowering plants. Divergent retrotransposons are thus a major factor contributing to the expansion of the low-repetitive DNA component in higher plants.

The salAB genes of Azospirillum irakense KBC1, which encode two aryl-beta-glucosidases, are required for growth on salicin. In the 4-kb region upstream of the salAB genes, two additional genes, salC and salR, were identified. SalC shows characteristics of the outer membrane receptors in the FepA/FhuA family. The salC AB genes are transcribed as a polycistronic mRNA. The salR gene encodes a protein homologous to the LacI/GalR family of transcriptional repressors. Expression of the sal operon, measured by means of a salC-gusA translational fusion in A. irkense KBC1, requires the presence of aryl-beta-glucosides such as arbutin and salicin. Expression is markedly enhanced when a simple carbon source, like glucose, cellobiose or malate, is added to the medium. In a salR mutant, expression of the salC-gusA fusion does not require an aryl-beta-glucoside inducer. Expression of a salR-gusA fusion is constitutive. The product of arbutin hydrolysis (hydroquinone) partly inhibits the expression of a salC-gusA fusion in arbutin- or salicin-containing minimal medium. This effect is independent of SalR. Salicylalcohol, the hydrolysis product of salicin, also partly inhibits salC expression in a SalR-independent fashion, but only in salicin-containing minimal medium.

The replication origin and both terminal segments were cloned from the large linear plasmid pSLA2-L in Streptomyces rochei 7434AN4. The basic replicon consists of a 1.9-kb DNA fragment, which contains the genetic information required for autonomous replication in circular form. Sequence analysis revealed two ORFs, RepL1 and RepL2, with no similarity to any of the replication initiator proteins in the database. Deletion and mutational analysis showed that RepL1 is essential for replication and RepL2 has a subsidiary function. The origin of replication may be located 800 bp upstream of repL1. Sequencing of the left and right terminal segments revealed the presence of 12 palindromes. The sequence of the first 90 bp, including palindromes I-IV, shows great similarity to that of other Streptomyces linear chromosomes and plasmids. These results suggest that the internal replication origins of the linear replicons vary widely, in contrast to the high degree of conservation of their telomeres.

To construct a vector for high-level expression of heterologous genes in Lentinus edodes, the L. edodes GPD promoter, which is expressed constitutively and strongly, was fused to a hygromycin B phosphotransferase gene (hph) derived from Escherichia coli as a selective marker. Using the resulting pLG-hph construct, L. edodes was efficiently transformed to hygromycin resistance by restriction enzyme-mediated integration (REMI). The restriction enzyme concentrations yielding the maximal numbers of transformants by the REMI method were 10 U per transformation in the case of BglII and 25-50 U in the case of HindIII. Southern analysis of the transformants indicated that some 50% of plasmid integrations were REMI-mediated events. These results indicate that pLG is a useful vector for transformation of L. edodes. Deletion analysis of the GPD promoter region suggested that the segment between positions -442 bp and -270 bp relative to the transcription start point may be essential for function.

Retroelements are ubiquitous features of eukaryotic genomes, often accounting for a substantial fraction of their total DNA content. One major group of retroelements, which includes the gypsy and copia-like elements, is distinguished by the presence of long terminal repeats (LTRs). We have identified and partially characterized a sequence from banana (Musa acuminata cv. Grand Nain) which shows significant homology to gypsy-like LTR retroelements from other species. The element, named monkey, shows a high degree of homology to the reverse transcriptase, RNase H and integrase genes of retroelements from plants, fungi and yeast. However, several stop codons are present in the major ORF of this element, suggesting that this copy of monkey, if functional, is non-autonomous. Southern analysis indicated that monkey is present in both the A and B genomes of Musa, and that it is found in 200-500 copies per haploid genome in cv. Grand Nain. Chromosomal localization by fluorescent in-situ hybridization indicates that copies of monkey are concentrated in the nucleolar organizer regions and colocalize with rRNA genes. Other copies of monkey appear to be dispersed throughout the genome.

We previously characterized a female-specific randomly amplified polymorphic DNA (RAPD), designated W-Kabuki, derived from the W chromosome of the silkworm, Bombyx mori. To further analyze the W chromosome of B. mori, we obtained a lambda phage clone which contains the W-Kabuki RAPD sequence and sequenced the 18.1-kb DNA insert. We found that this DNA comprises a nested structure of at least seven elements; three retrotransposons, two retroposons, one functionally unknown insertion, and one Bombyx repetitive sequence. The non-LTR retrotransposon BMC1, the retroposon Bm1, a functionally unknown inserted DNA (FUI), and a copia-like LTR retrotransposon (Yokozuma) are themselves inserted into a novel gypsy-Ty3-like LTR retrotransposon, named Kabuki. Furthermore, this Kabuki element is itself inserted into another copy of Bm1. The BMCI and Yokozuna elements inserted in the Kabuki sequence are intact. Moreover, the Kabuki element is largely intact. These results suggest that many retrotransposable elements have accumulated on the W chromosome, and these elements are expected to evolve more slowly than those on other chromosomes.

A degenerate DNA transposon, Pat, was identified in the genomes of various wild-type strains of the filamentous fungus Podospora anserina. In these strains, the number (approximately 20-25 copies per genome) and location of Pat sequences appear to be conserved. Two copies of Pat, one complete and one partial, were cloned and characterized. The sequence of the complete element is 1856 bp long and contains imperfect inverted terminal repeats (ITRs) of 53 bp. The target site duplication comprises the sequence TA. The amino acid sequence derived from one reading frame of Pat shows significant homology to members of the Fot1 family of transposons. However, this reading frame is interrupted by numerous stop codons. Since no transcripts of Pat were identified in different P. anserina strains grown under standard conditions and under increased stress, we conclude that none of the copies of Pat is active in the strains analyzed, under the environmental conditions investigated. Comparison of the sequences of the two cloned Pat sequences revealed 89% (589/747 nucleotides) identity. Most of the differences (82%, 129/158) can be attributed to transitions preferentially at CpA:TpG and CpT:ApG dinucleotides. The dinucleotide ratios in Pat are similar to those in a Neurospora crassa transposon which was subject to repeat-induced mutation (RIP), but differ significantly from those found in single-copy genes of P. anserina and in fungal DNA transposons not modified by this mechanism. Molecular analysis of the progeny of a cross between the wild-type strain and a transgenic strain in which a nuclear gene was duplicated by transformation yielded the first clear evidence that a RIP-like process is active in P. anserina.

This paper describes the characterization of atrC and atrD (ABC transporters C and D), two novel ABC transporter-encoding genes from the filamentous fungus Aspergillus nidulans, and provides evidence for the involvement of atrD in multidrug transport and antibiotic production. BLAST analysis of the deduced amino acid sequences of AtrCp and AtrDp reveals high homology to ABC transporter proteins of the P-glycoprotein cluster. AtrDp shows a particularly high degree of identity to the amino acid sequence of Afu Mdr1p, a previously characterized ABC transporter from the human pathogen A. fumigatus. Northern analysis demonstrates an increase in transcript levels of atrC and atrD in fungal germlings upon treatment with natural toxic compounds and xenobiotics. The atrC gene has a high constitutive level of expression relative to attrD, which suggests its involvement in a metabolic function. Single knock-out mutants for atrC and atrD were generated by gene replacement using pyrG from A. oryzae as a selectable marker. DeltatrD mutants display a hypersensitive phenotype to compounds such as cycloheximide, the cyclosporin derivative PSC 833, nigericin and valinomycin, indicating that AtrDp is involved in protection against cytotoxic compounds. Energy-dependent efflux of the azole-related fungicide fenarimol is inhibited by substrates of AtrDp (e.g. PSC 833, nigericin and valinomycin), suggesting that AtrDp plays a role in efflux of this fungicide. Most interestingly, (delta)atrD mutants display a decrease in penicillin production, measured indirectly as antimicrobial activity against Micrococcus luteus. These results suggest that ABC transporters may be involved in secretion of penicillin from fungal cells.

A cDNA for an S-like RNase (RNase PD2) has been isolated from a pistil cDNA library of Prunus dulcis cv. Ferragnés. The cDNA encodes an acidic protein of 226 amino acid residues with a molecular weight of 25 kDa. A potential N-glycosylation site is present at the N-terminus in RNase PD2. A signal peptide of 23 amino acid residues and a transmembrane domain are predicted. The two active-site histidines present in enzymes of the T2/S RNase superfamily were detected in RNase PD2. Its amino acid sequence shows 71.2% similarity to RNSI of Arabidopsis and RNase T2 of chickpea, respectively. Northern blotting and RT-PCR analyses indicate that PD2 is expressed predominantly in petals, pistils of open flowers and leaves of the almond tree. Analyses of shoots cultured in vitro suggested that the expression of RNase PD2 is associated with phosphate starvation. Southern analysis detected two sequences related to RNase PD2 in the P. dulcis genome. RFLP analysis showed that S-like RNase genes are polymorphic in different almond cultivars. The PD2 gene sequence was amplified by PCR and two introns were shown to interrupt the coding region. Based on sequence analysis, we have defined three classes of S-like RNase genes, with the PD2 RNase gene representing a distinct class. The significance of the structural divergence of S-like RNase genes is further discussed.

Ectomycorrhizal fungi contribute to the nitrogen nutrition of their host plants, but no information is available on the molecular control of their nitrogen metabolism. The cloning and pattern of transcriptional regulation of two nitrite reductase genes of the symbiotic basidiomycete Hebeloma cylindrosporum are presented. The genomic copy of one of these genes (nar1) was entirely sequenced; the coding region is interrupted by 12 introns. The nar1 gene, which is transcribed and codes for a putative 908-amino acid polypeptide complemented nitrate reductase-deficient mutants of H. cylindrosporum upon transformation, thus demonstrating that the gene is functional. The second gene (nar2), for which no mRNA transcripts were detected, is considered to be an ancestral, non-functional duplication of nar1. In a 462-nt partial sequence of nar2 two introns were identified at positions identical to those of introns 8 and 9 of nar1, although their respective nucleotide sequences were highly divergent; the exon sequences were much more conserved. In wild-type strains, transcription of nar1 is repressed in the presence of a high concentration of ammonium. High levels of transcription are observed in the presence of either very low nitrogen concentrations or high concentrations of nitrate or organic N sources such as urea, glycine or serine. This indicates that in H. cylindrosporum, in contrast to all nitrophilous organisms studied so far, an exogenous supply of nitrate is not required to induce transcription of a nitrate reductase gene. In contrast, repression by ammonium suggests the existence of a wide-domain regulatory gene, as already characterized in ascomycete species.