Electrophoretic karyotypes of the elm tree pathogen Ophiostoma ulmi (sensu lato)

Pulsed field gel electrophoresis using OFAGE, TAFE, and CHEF systems has been used to more fully characterize karyotypic variation within the two closely related fungal species of Ophiostoma ulmi sensu lato. Twelve wild-type and laboratory strains, representing the less agressive species O. ulmi and both of the biotypes of the more aggressive species O. novo-ulmi were studied and their karyotypes determined. Depending on the strain, a minimum of four to a minimum of eight chromosomal DNA bands were present that fall into three distinct size classes, with one exception. Strain CESSI6K (O. novo-ulmi, North American aggressive subgroup) contains a unique chromosomal DNA band which comigrated near a Saccharomyces cerevisiae chromosome of 0.95 Mb. This unique band was the smallest O. ulmi s. l. chromosomal DNA observed. Seven of the twelve strains shared a common chromosomal DNA banding pattern, whereas each of the other five had a unique karyotype. There was no correlation between chromosome profile and species, as some O. novo-ulmi and O. ulmi strains shared common electrophoretic karyotypes.     

Requirement for End-Joining and Checkpoint Functions, but Not RAD52-Mediated Recombination, after EcoRI Endonuclease Cleavage of Saccharomyces cerevisiae DNA

RAD52 and RAD9 are required for the repair of double-strand breaks (DSBs) induced by physical and chemical DNA-damaging agents in Saccharomyces cerevisiae. Analysis of EcoRI endonuclease expression in vivo revealed that, in contrast to DSBs containing damaged or modified termini, chromosomal DSBs retaining complementary ends could be repaired in rad52 mutants and in G₁-phase Rad⁺ cells. Continuous EcoRI-induced scission of chromosomal DNA blocked the growth of rad52 mutants, with most cells arrested in G₂ phase. Surprisingly, rad52 mutants were not more sensitive to EcoRI-induced cell killing than wild-type strains. In contrast, endonuclease expression was lethal in cells deficient in Ku-mediated end joining. Checkpoint-defective rad9 mutants did not arrest cell cycling and lost viability rapidly when EcoRI was expressed. Synthesis of the endonuclease produced extensive breakage of nuclear DNA and stimulated interchromosomal recombination. These results and those of additional experiments indicate that cohesive ended DSBs in chromosomal DNA can be accurately repaired by RAD52-mediated recombination and by recombination-independent complementary end joining in yeast cells.     

Electrophoretic Karyotypes of Fusarium spp.

Migheli, Q., Berio, T., and Gullino, M. L. 1993. Electrophoretic karyotypes of Fusarium spp. Experimental Mycology 17, 329-337. The electrophoretic karyotype of 17 antagonistic and pathogenic strains of Fusarium spp. has been established by using contour-clamped homogeneous electric field gel electrophoresis. Intact chromosomal DNA was prepared from fungal protoplasts with standard procedures. Up to 11 distinct chromosomal bands were resolved after 184 h of migration at 50 V. Polymorphic karyotypes were observed in different species of Fusarium, formae speciales of F. oxysporum , and races of F. oxysporum f.sp. dianthi. Using the Schizosaccharomyces pombe and Saccharomyces cerevisiae chromosomes as size standards, the size of the Fusarium genome was estimated to range from approximately 18.1 to 51.5 Mb. The suitability of electrophoretic karyotyping as a tool for strain characterization, as well as some applications in hybridization analysis of Fusarium spp., is discussed.     

An electrophoretic karyotype forPhytophthora megasperma

Chromosomal DNA has been prepared from mycelial spheroplasts ofPhytophthora megasperma (isolate 63, chromosome numbern = 13–14)(E. M. Hansen, C. M. Brasier, D. S. Shaw, and P. B. Hamm, 1986.Trans Brit. Mycol. Soc.87, 557–573) and resolved by a pulsed field gel electrophoresis system which uses contour-clamped homogeneous electric fields. Nine chromosomal DNA bands were separated, the smallest being about 1.4 Mb in size: several larger DNAs were unresolved under all conditions tested. The estimated size was based on migration rates relative to those of chromosomal DNA ofSaccharomyces cerevisiae, Schizosaccharomyces pombe, and aNeurospora crassa translocation strain which has a minichromosome.     

Restricted fragmentation of poliovirus type 1, 2 and 3 RNAs by ribonuclease III.

Cleavage of the genome RNAs of poliovirus type 1, 2 and 3 with the ribonuclease III of Escherichia coli has been investigated with the following results: (1) at or above physiological salt concentration, the RNAs are completely resistant to the action of the enzyme, an observation suggesting that the RNAs lack “primary cleavage sites”; (2) lowering the salt concentration to 0.1 m or below allows RNase III to cleave the RNAs at “secondary sites”. Both large and small fragments can be obtained in a reproducible manner depending on salt conditions chosen for cleavage. Fingerprints of three large fragments of poliovirus type 2 RNA show that they originate from unique segments and represent most if not all sequences of the genome. Based upon binding to poly(U) filters of poly(A)- linked fragments, a physical map of the large fragments of poliovirus type 2 RNA was constructed. The data suggest that RNase III cleavage of single-stranded RNA provides a useful method to fragment the RNA for further studies.     

Detection of nif Genes in Nitrogen-Fixing Bacterial Isolate from Tomato (Lycopersicon esculentum Mill cv Pusa Ruby)

Nitrogen-fixing bacterial isolate from the intercellular spaces of tomato root cortical cells was studied for the location of nif genes on the chromosomal or plasmid DNA. The bacterial isolate showed two plasmids of approximate molecular sizes of 220 and 120 kb. Klebsiella pneumoniae nif HDK probe hybridized with the chromosomal DNA and not with the plasmid DNA thereby showing that nif genes are localised on the chromosomal DNA.     

The Deletion of rnhB in Mycobacterium smegmatis Does Not Affect the Level of RNase HII Substrates or Influence Genome Stability

RNase HII removes RNA from RNA/DNA hybrids, such as single ribonucleotides and RNA primers generated during DNA synthesis. Both, RNase HII substrates and RNase HII deficiency have been associated with genome instability in several organisms, and genome instability is a major force leading to the acquisition of drug resistance in bacteria. Understanding the mechanisms that underlie this phenomenon is one of the challenges in identifying efficient methods to combat bacterial pathogens. The aim of the present study was set to investigate the role of rnhB, presumably encoding RNase HII, in maintaining genome stability in the M. tuberculosis model organism Mycobacterium smegmatis. We performed gene replacement through homologous recombination to obtain mutant strains of Mycobacterium smegmatis lacking the rnhB gene. The mutants did not present an altered phenotype, according to the growth rate in liquid culture or susceptibility to hydroxyurea, and did not show an increase in the spontaneous mutation rate, determined using the Luria-Delbrück fluctuation test for streptomycin resistance in bacteria. The mutants also did not present an increase in the level of RNase HII substrates, measured as the level of alkaline degradation of chromosomal DNA or determined through immunodetection. We conclude that proteins other than RnhB proteins efficiently remove RNase HII substrates in M. smegmatis. These results highlight differences in the basic biology between Mycobacteria and eukaryotes and between different species of bacteria.     

Characterization of RNase R-digested cellular RNA source that consists of lariat and circular RNAs from pre-mRNA splicing

Besides linear RNAs, pre-mRNA splicing generates three forms of RNAs: lariat introns, Y-structure introns from trans-splicing, and circular exons through exon skipping. To study the persistence of excised introns in total cellular RNA, we used three Escherichia coli 3′ to 5′ exoribonucleases. Ribonuclease R (RNase R) thoroughly degrades the abundant linear RNAs and the Y-structure RNA, while preserving the loop portion of a lariat RNA. Ribonuclease II (RNase II) and polynucleotide phosphorylase (PNPase) also preserve the lariat loop, but are less efficient in degrading linear RNAs. RNase R digestion of the total RNA from human skeletal muscle generates an RNA pool consisting of lariat and circular RNAs. RT–PCR across the branch sites confirmed lariat RNAs and circular RNAs in the pool generated by constitutive and alternative splicing of the dystrophin pre-mRNA. Our results indicate that RNase R treatment can be used to construct an intronic cDNA library, in which majority of the intron lariats are represented. The highly specific activity of RNase R implies its ability to screen for rare intragenic trans-splicing in any target gene with a large background of cis-splicing. Further analysis of the intronic RNA pool from a specific tissue or cell will provide insights into the global profile of alternative splicing.     

The Essential Function of B. subtilis RNase III Is to Silence Foreign Toxin Genes

RNase III–related enzymes play key roles in cleaving double-stranded RNA in many biological systems. Among the best-known are RNase III itself, involved in ribosomal RNA maturation and mRNA turnover in bacteria, and Drosha and Dicer, which play critical roles in the production of micro (mi)–RNAs and small interfering (si)–RNAs in eukaryotes. Although RNase III has important cellular functions in bacteria, its gene is generally not essential, with the remarkable exception of that of Bacillus subtilis. Here we show that the essential role of RNase III in this organism is to protect it from the expression of toxin genes borne by two prophages, Skin and SPβ, through antisense RNA. Thus, while a growing number of organisms that use RNase III or its homologs as part of a viral defense mechanism, B. subtilis requires RNase III for viral accommodation to the point where the presence of the enzyme is essential for cell survival. We identify txpA and yonT as the two toxin-encoding mRNAs of Skin and SPβ that are sensitive to RNase III. We further explore the mechanism of RNase III–mediated decay of the txpA mRNA when paired to its antisense RNA RatA, both in vivo and in vitro.     

In vivo species specificity of DNA polymerase α

The DNA polymerase a enzymes from human, and budding (Saccharomyces cerevisiae) and fission yeast (Schizosaccharomyces pombe) are homologous proteins involved in initiation and replication of chromosomal DNA. Sequence comparision of human DNA polymerase α with that of S. cerevisiae and S. pombe shows overall levels of amino acid sequence identity of 32% and 34%, respectively. We report here that, despite the sequence conservation among these three enzymes, functionally active human DNA polymerase a fails to rescue several different conditional lethal alleles of the budding yeast POL1 gene at nonpermissive temperature. Furthermore, human DNA polymerase α cannot complement a null allele of budding yeast POL1 either in germinating spores or in vegetatively growing cells. In fission yeast, functionally active human DNA polymerase α is also unable to complement the disrupted polα::ura4 ⁺ allele in germinating spores. Thus, in vivo, DNA polymerase α has stringent species specificity for initiation and replication of chromosomal DNA.     

Atomic Force Microscopy Analysis of the Role of Major DNA-Binding Proteins in Organization of the Nucleoid in Escherichia coli

Bacterial genomic DNA is packed within the nucleoid of the cell along with various proteins and RNAs. We previously showed that the nucleoid in log phase cells consist of fibrous structures with diameters ranging from 30 to 80 nm, and that these structures, upon RNase A treatment, are converted into homogeneous thinner fibers with diameter of 10 nm. In this study, we investigated the role of major DNA-binding proteins in nucleoid organization by analyzing the nucleoid of mutant Escherichia coli strains lacking HU, IHF, H–NS, StpA, Fis, or Hfq using atomic force microscopy. Deletion of particular DNA-binding protein genes altered the nucleoid structure in different ways, but did not release the naked DNA even after the treatment with RNase A. This suggests that major DNA-binding proteins are involved in the formation of higher order structure once 10-nm fiber structure is built up from naked DNA.     

Optimization of DNA isolation process and enhancement of RAPD PCR for low quality genomic DNA of Terminalia arjuna

Owing to the presence of higher amount of polyphenolic and polysaccharide compounds, Terminalia arjuna (Roxburgh) is a significant medicinal plant in the Indian primeval medicine system. Polyphenolic and polysaccharide compounds also acts as inhibitors during Genomic DNA isolation from young leaves of T. arjuna, resulting in recovery of low quality genomic DNA, which affects downstream applications like PCR, restriction digestion’s, etc. In this study, nine different methods of genomic DNA isolation were used, out of which two methods were modified CTAB based methods, third one was HEPES based method and remaining six methods was FTA Plant Saver Card based. Out of the six FTA card based methods, in the first method, leaves were directly pressed inside the circle of FTA card. In the second and third methods, the leaves were homogenized with PBS and DNase RNase free water and the sample was applied on the FTA card. In the fourth and fifth methods: finally recovered DNA from two modified CTAB based methods was directly applied to the FTA card. In the sixth method, DNA precipitated after first phenol:chloroform:isoamyl alcohol precipitation of modified CTAB based methods dissolved in DNase RNase free water and applied to FTA Card. To optimize the PCR conditions, BSA (400 ng/μl), formamide (2.5%), DMSO (5% and 10%) and glycerol (5%, 10%, 15%, and 20%) was added into the PCR mix as enhancement agents for amplification of low quality genomic DNA (A₂₆₀/A₂₈₀ – 1.27 ± 0.090) of T. arjuna recovered using the HEPES Based method. It was found that the BSA was the best among them followed by 10% glycerol. In addition of BSA to the PCR mixture, it specifically enhances the amplification of the low quality DNA. It reduces the noise in-between the amplified bands and increases the intensity of PCR product.     

Yeast episome: oligomycin resistance associated with a small covalently closed non-mitochondrial circular DNA

We have isolated a single step spontaneous mutant of S. cerevisiae resistant simultaneously to oligomycin, venturicidin, chloramphenicol, cycloheximide and triethyltin. This multiple drug resistance results from the interaction of two genetic factors showing both chromosomal location and episomal characteristics. One factor (π) confers oligomycin resistance, the other (τ) confers the other resistances. π can be lost spontaneously while τ can be completely eliminated with ethidium bromide. All π⁺ strains, whether grande or petite, τ⁺ or τ^?, carry a covalently closed circular DNA while π^? strains are devoid of it. We hypothesise that this circular DNA may play an informational role in the biogenesis and/or function of membranes.     

Crystal structure of <Emphasis Type="Italic">Streptomyces coelicolor</Emphasis> RraAS2, an unusual member of the RNase E inhibitor RraA protein family

Bacterial ribonuclease E (RNase E) plays a crucial role in the processing and decay of RNAs. A small protein named RraA negatively regulates the activity of RNase E via protein-protein interaction in various bacteria. Recently, RraAS1 and RraAS2, which are functional homologs of RraA from Escherichia coli, were identified in the Gram-positive species Streptomyces coelicolor. RraAS1 and RraAS2 inhibit RNase ES ribonuclease activity in S. coelicolor. RraAS1 and RraAS2 have a C-terminal extension region unlike typical bacterial RraA proteins. In this study, we present the crystal structure of RraAS2, exhibiting a hexamer arranged in a dimer of trimers, consistent with size exclusion chromatographic results. Importantly, the C-terminal extension region formed a long α-helix at the junction of the neighboring subunit, which is similar to the trimeric RraA orthologs from Saccharomyces cerevisiae. Truncation of the C-terminal extension region resulted in loss of RNase ES inhibition, demonstrating its crucial role. Our findings present the first bacterial RraA that has a hexameric assembly with a C-terminal extension α-helical region, which plays an essential role in the regulation of RNase ES activity in S. coelicolor.     

A modified DNA isolation protocol for obtaining pure RT-PCR grade RNA

We provide a simple but very efficient method for RNA preparation from Saccharomyces cerevisiae based on a standard chromosomal DNA isolation protocol. The method yields DNA-free total RNA, including mRNA, rRNA, and tRNA but can easily be adjusted to considerably enrich low molecular weight RNAs, such as tRNAs and the small rRNA species (5S and 5.8S). The procedure was proven and validated by verification of cDNAs belonging to four different genes, two of which encoding polypeptides and two tRNA genes. Besides its simpleness, the method is further advantagous in terms of safety (omitting hazardous phenol) and cost efficiency.