Identification of pig-specific Cryptosporidium species in mixed infections using Illumina sequencing technology.

Nowadays molecular methods are widely used in epidemiological studies of Cryptosporidium infections in humans and animals. However to gain better understanding of parasite species or genotypes, especially when mixed infections are noticed, highly sensitive tools with adequate resolution power need to be employed. In this article, we report an application of the next generation sequencing method (NGS) for detection and characterisation of Cryptosporidium species concurrently present in pig faeces. A mixture of Cryptosporidium DNA obtained from two faecal samples was amplified at the 18 SSU rRNA gene locus and the resulting amplicons were subsequently used for MiSeq sequencing. Although initial molecular analyses indicated the possible presence of another Cryptosporidium species other than Cryptosporidium scrofarum and Cryptosporidium suis, deep sequencing only confirmed the presence of pig-specific Cryptosporidium.

Evaluation of the Escherichia coli HK82 and BS87 strains as tools for AlkB studies.

Within a decade the family of AlkB dioxygenases has been extensively studied as a one-protein DNA/RNA repair system in Escherichia coli but also as a group of proteins of much wider functions in eukaryotes. Two strains, HK82 and BS87, are the most commonly used E. coli strains for the alkB gene mutations. The aim of this study was to assess the usefulness of these alkB mutants in different aspects of research on AlkB dioxygenases that function not only in alkylated DNA repair but also in other metabolic processes in cells. Using of HK82 and BS87 strains, we found the following differences among these alkB(-) derivatives: (i) HK82 has shown more than 10-fold higher MMS-induced mutagenesis in comparison to BS87; (ii) different specificity of Arg(+) revertants; (iii) increased induction of SOS and Ada responses in HK82; (iv) the genome of HK82, in comparison to AB1157 and BS87, contains additional mutations: nalA, sbcC, and nuoC. We hypothesize that in HK82 these mutations, together with the non-functional AlkB protein, may result in much higher contents of ssDNA, thus higher in comparison to BS87 MMS-induced mutagenesis. In the light of our findings, we strongly recommend using BS87 strain in AlkB research as HK82, bearing several additional mutations in its genome, is not an exact derivative of the AB1157 strain, and shows additional features that may disturb proper interpretation of obtained results.

Paramecium genome survey: a pilot project.

A consortium of laboratories undertook a pilot sequencing project to gain insight into the genome of Paramecium. Plasmid-end sequencing of DNA fragments from the somatic nucleus together with similarity searches identified 722 potential protein-coding genes. High gene density and uniform small intron size make random sequencing of somatic chromosomes a cost-effective strategy for gene discovery in this organism.

The KRR1 gene encodes a protein required for 18S rRNA synthesis and 40S ribosomal subunit assembly in Saccharomyces cerevisiae.

The newly discovered Saccharomyces cerevisiae gene KRR1 (YCL059c) encodes a protein essential for cell viability. Krr1p contains a motif of clustered basic amino acids highly conserved in the evolutionarly distant species from yeast to human. We demonstrate that Krr1p is localized in the nucleolus. The KRR1 gene is highly expressed in dividing cells and its expression ceases almost completely when cells enter the stationary phase. In vivo depletion of Krr1p leads to drastic reduction of 40S ribosomal subunits due to defective 18S rRNA synthesis. We propose that Krr1p is required for proper processing of pre-rRNA and the assembly of preribosomal 40S subunits.

Disruption of six novel yeast genes located on chromosome II reveals one gene essential for vegetative growth and two required for sporulation and conferring hypersensitivity to various chemicals.

A PCR-based method for targeted gene deletion by kanMX4 module was used to construct complete deletion mutants of six individual open reading frames from chromosome II: YBR128c, YBR131w, YBR133c, YBR137w, YBR138c and YBR142w. The ORFs were deleted in two diploid strains, FY1679 and W303. Sporulation and tetrad analysis revealed that only one ORF, YBR142w, encoding a putative DEAD-box RNA helicase, is an essential gene. A systematic phenotypic analysis of the deleted mutants was carried out. Homozygous diploids ybr128cDelta/ybr128cDelta and ybr131wDelta/ybr131wDelta did not sporulate. The ybr131cDelta mutant whether haploid or homozygous diploid, in addition displayed an increased sensitivity to Caffeine, Calcium and Zinc, and to emphasize this phenotype we named the gene CCZ1. ORF YBR133c was independently reported by others as Histone Synthetic Lethal (HSL7) (Ma et al., 1996). We found that the aberrant morphology characteristic for ybr133cDelta (hsl7Delta) cells was observed in W303 but not in FY1679 genetic background. Furthermore, we observed that deletion of YBR133c had a pleiotropic effect under a wide range of conditions, including increased sensitivity to calcium, caffeine, calcofluor white, vanadate and verapamil. The effects of the deletion were reinforced in W303 background. We found no phenotypic effects of the two remaining deletions, ybr137wDelta and ybr138cDelta.

Large-scale phenotypic analysis--the pilot project on yeast chromosome III.

In 1993, a pilot project for the functional analysis of newly discovered open reading frames, presumably coding for proteins, from yeast chromosome III was launched by the European Community. In the frame of this programme, we have developed a large-scale screening for the identification of gene/protein functions via systematic phenotypic analysis. To this end, some 80 haploid mutant yeast strains were constructed, each carrying a targeted deletion of a single gene obtained by HIS3 or TRP1 transplacement in the W303 background and a panel of some 100 growth conditions was established, ranging from growth substrates, stress to, predominantly, specific inhibitors and drugs acting on various cellular processes. Furthermore, co-segregation of the targeted deletion and the observed phenotype(s) in meiotic products has been verified. The experimental procedure, using microtiter plates for phenotypic analysis of yeast mutants, can be applied on a large scale, either on solid or in liquid media. Since the minimal working unit of one 96-well microtiter plate allows the simultaneous analysis of at least 60 mutant strains, hundreds of strains can be handled in parallel. The high number of monotropic and pleiotropic phenotypes (62%) obtained, together with the acquired practical experience, have shown this approach to be simple, inexpensive and reproducible. It provides a useful tool for the yeast community for the systematic search of biochemical and physiological functions of unknown genes accounting for about a half of the 6000 genes of the complete yeast genome.

A novel cross-phylum family of proteins comprises a KRR1 (YCL059c) gene which is essential for viability of Saccharomyces cerevisiae cells.

We demonstrate here that the open reading frame (ORF) YCL059c, discovered during the systematic sequencing of chromosome III [Oliver et al., Nature 357 (1992) 38-46], codes for a protein essential for yeast: neither spore germination nor cell division occur in strains deleted for this gene. We have cloned the wild-type (wt) gene and shown that it complements the deletion. A relatively abundant RNA transcript corresponds to the gene. The protein has no similarity to proteins of known function. Interestingly, however, it is homologous to several expressed sequence tags (EST) of unknown function from Caenorhabditis elegans, Oryza sativa and Homo sapiens. Thus, a novel family of proteins of presumably nuclear localization, with a characteristic highly basic motif, KRR-R, transcends various phyla, and plays an important role in cellular processes. We propose to call this essential gene KRR1.

Subtelomeric duplications in Saccharomyces cerevisiae chromosomes III and XI: topology, arrangements, corrections of sequence and strain-specific polymorphism.

We have determined the sequence of a 3.42 kb segment from the left arm of chromosome III (coordinates 5394-8815 of Oliver et al., 1992). Instead of four open reading frames (ORFs) listed previously, the verified sequence reveals the presence of only one ORF, renamed YCL070/73c, encoding a protein of 615 amino acids. The putative product of ORF YCL070/73c shows 98.5% identity and 99% similarity with the protein of the same length encoded by ORF YKR106w from the right arm of chromosome XI and displays a topology characteristic for the Major Facilitators Superfamily of membrane proteins. These corrections will be deposited in the EMBL data library under the Accession Number X59720. In strain S288C the subtelomeric sequence 4319-11 215 of chromosome III is 98.3% identical with the subtelomeric sequence of 658 204-665 061 from the right arm of chromosome XI. Using various subtelomeric probes from chromosome III (coordinates 2097-3646 of S288C) we have analysed eight different Saccharomyces cerevisiae strains and the closely related species S. douglasii: some S. cerevisiae strains have additional duplications and longer chromosomes XI; in all strains chromosome III contains the 1200-11 000 segment (strain FL100 is disomic) while S. douglasii does not show any hybridization in this region.

The sequence of 24.3 kb from chromosome X reveals five complete open reading frames, all of which correspond to new genes, and a tandem insertion of a Ty1 transposon.

We have determined the complete nucleotide sequence of a 24.3 kb segment from chromosome X carried by the cosmid pEJ103. The sequence encodes five complete open reading frames (ORFs), none of which correspond to previously described genes; however, four of these ORFs display interesting similarities with sequences present in the databanks. The sequence also contains a tandem insertion of a Ty1 element. An investigation of the Ty1 polymorphism in other strains has revealed that the original insertion occurred within an ORF. Finally, the structure of the Ty1 repeat suggests a mechanism by which it may have been generated.

A new essential gene located on Saccharomyces cerevisiae chromosome IX.

A new 1150 amino acids long open reading frame (ORF), coding for an essential protein of unknown function was found in Saccharomyces cerevisiae by sequencing 3754 bp of geonomic DNA. The clone was isolated in a search for a fatty acid-binding protein (FABP) and was localized on chromosome IX. The ORF bears no homology to FABP, but it shows weak similarity to Plasmodium vivax reticulocyte binding protein 1 and to aggregation-specific adenylate cyclase from Dictyostelium discoideum. The new gene is constitutively transcribed regardless of the carbon source used.