39 research outputs found
The identification of protein and RNA interactors of the splicing factor Caper in the adult Drosophila nervous system
Post-transcriptional gene regulation is a fundamental mechanism that helps regulate the development and healthy aging of the nervous system. Mutations that disrupt the function of RNA-binding proteins (RBPs), which regulate post-transcriptional gene regulation, have increasingly been implicated in neurological disorders including amyotrophic lateral sclerosis, Fragile X Syndrome, and spinal muscular atrophy. Interestingly, although the majority of RBPs are expressed widely within diverse tissue types, the nervous system is often particularly sensitive to their dysfunction. It is therefore critical to elucidate how aberrant RNA regulation that results from the dysfunction of ubiquitously expressed RBPs leads to tissue specific pathologies that underlie neurological diseases. The highly conserved RBP and alternative splicing factor Caper is widely expressed throughout development and is required for the development of Drosophila sensory and motor neurons. Furthermore, caper dysfunction results in larval and adult locomotor deficits. Nonetheless, little is known about which proteins interact with Caper, and which RNAs are regulated by Caper. Here we identify proteins that interact with Caper in both neural and muscle tissue, along with neural specific Caper target RNAs. Furthermore, we show that a subset of these Caper-interacting proteins and RNAs genetically interact with caper to regulate Drosophila gravitaxis behavior
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Analysis of Genome Sequences from Plant Pathogenic Rhodococcus Reveals Genetic Novelties in Virulence Loci
Members of Gram-positive Actinobacteria cause economically important diseases to plants. Within the Rhodococcus genus,
some members can cause growth deformities and persist as pathogens on a wide range of host plants. The current model
predicts that phytopathogenic isolates require a cluster of three loci present on a linear plasmid, with the fas operon central
to virulence. The Fas proteins synthesize, modify, and activate a mixture of growth regulating cytokinins, which cause a
hormonal imbalance in plants, resulting in abnormal growth. We sequenced and compared the genomes of 20 isolates of
Rhodococcus to gain insights into the mechanisms and evolution of virulence in these bacteria. Horizontal gene transfer was
identified as critical but limited in the scale of virulence evolution, as few loci are conserved and exclusive to
phytopathogenic isolates. Although the fas operon is present in most phytopathogenic isolates, it is absent from
phytopathogenic isolate A21d2. Instead, this isolate has a horizontally acquired gene chimera that encodes a novel fusion
protein with isopentyltransferase and phosphoribohydrolase domains, predicted to be capable of catalyzing and activating
cytokinins, respectively. Cytokinin profiling of the archetypal D188 isolate revealed only one activate cytokinin type that was
specifically synthesized in a fas-dependent manner. These results suggest that only the isopentenyladenine cytokinin type is
synthesized and necessary for Rhodococcus phytopathogenicity, which is not consistent with the extant model stating that a
mixture of cytokinins is necessary for Rhodococcus to cause leafy gall symptoms. In all, data indicate that only four
horizontally acquired functions are sufficient to confer the trait of phytopathogenicity to members of the genetically diverse
clade of Rhodococcus
The 5p15.33 Locus Is Associated with Risk of Lung Adenocarcinoma in Never-Smoking Females in Asia
Genome-wide association studies of lung cancer reported in populations of European background have identified three regions on chromosomes 5p15.33, 6p21.33, and 15q25 that have achieved genome-wide significance with p-values of 10−7 or lower. These studies have been performed primarily in cigarette smokers, raising the possibility that the observed associations could be related to tobacco use, lung carcinogenesis, or both. Since most women in Asia do not smoke, we conducted a genome-wide association study of lung adenocarcinoma in never-smoking females (584 cases, 585 controls) among Han Chinese in Taiwan and found that the most significant association was for rs2736100 on chromosome 5p15.33 (p = 1.30×10−11). This finding was independently replicated in seven studies from East Asia totaling 1,164 lung adenocarcinomas and 1,736 controls (p = 5.38×10−11). A pooled analysis achieved genome-wide significance for rs2736100. This SNP marker localizes to the CLPTM1L-TERT locus on chromosome 5p15.33 (p = 2.60×10−20, allelic risk = 1.54, 95% Confidence Interval (CI) 1.41–1.68). Risks for heterozygote and homozygote carriers of the minor allele were 1.62 (95% CI; 1.40–1.87), and 2.35 (95% CI: 1.95–2.83), respectively. In summary, our results show that genetic variation in the CLPTM1L-TERT locus of chromosome 5p15.33 is directly associated with the risk of lung cancer, most notably adenocarcinoma
A Set of 100 Chloroplast DNA Primer Pairs to Study Population Genetics and Phylogeny in Monocotyledons
Chloroplast DNA sequences are of great interest for population genetics and phylogenetic studies. However, only a small set of markers are commonly used. Most of them have been designed for amplification in a large range of Angiosperms and are located in the Large Single Copy (LSC). Here we developed a new set of 100 primer pairs optimized for amplification in Monocotyledons. Primer pairs amplify coding (exon) and non-coding regions (intron and intergenic spacer). They span the different chloroplast regions: 72 are located in the LSC, 13 in the Small Single Copy (SSC) and 15 in the Inverted Repeat region (IR). Amplification and sequencing were tested in 13 species of Monocotyledons: Dioscorea abyssinica, D. praehensilis, D. rotundata, D. dumetorum, D. bulbifera, Trichopus sempervirens (Dioscoreaceae), Phoenix canariensis, P. dactylifera, Astrocaryum scopatum, A. murumuru, Ceroxylon echinulatum (Arecaceae), Digitaria excilis and Pennisetum glaucum (Poaceae). The diversity found in Dioscorea, Digitaria and Pennisetum mainly corresponded to Single Nucleotide Polymorphism (SNP) while the diversity found in Arecaceae also comprises Variable Number Tandem Repeat (VNTR). We observed that the most variable loci (rps15-ycf1, rpl32-ccsA, ndhF-rpl32, ndhG-ndhI and ccsA) are located in the SSC. Through the analysis of the genetic structure of a wild-cultivated species complex in Dioscorea, we demonstrated that this new set of primers is of great interest for population genetics and we anticipate that it will also be useful for phylogeny and bar-coding studies
Female chromosome X mosaicism is age-related and preferentially affects the inactivated X chromosome
To investigate large structural clonal mosaicism of chromosome X, we analysed the SNP
microarray intensity data of 38,303 women from cancer genome-wide association studies
(20,878 cases and 17,425 controls) and detected 124 mosaic X events42Mb in 97 (0.25%)
women. Here we show rates for X-chromosome mosaicism are four times higher than mean
autosomal rates; X mosaic events more often include the entire chromosome and participants
with X events more likely harbour autosomal mosaic events. X mosaicism frequency
increases with age (0.11% in 50-year olds; 0.45% in 75-year olds), as reported for Y and
autosomes. Methylation array analyses of 33 women with X mosaicism indicate events
preferentially involve the inactive X chromosome. Our results provide further evidence that
the sex chromosomes undergo mosaic events more frequently than autosomes, which could
have implications for understanding the underlying mechanisms of mosaic events and their
possible contribution to risk for chronic diseases
Analysis of genome sequences from plant pathogenic rhodococcus reveals genetic novelties in virulence Loci.
Members of Gram-positive Actinobacteria cause economically important diseases to plants. Within the Rhodococcus genus, some members can cause growth deformities and persist as pathogens on a wide range of host plants. The current model predicts that phytopathogenic isolates require a cluster of three loci present on a linear plasmid, with the fas operon central to virulence. The Fas proteins synthesize, modify, and activate a mixture of growth regulating cytokinins, which cause a hormonal imbalance in plants, resulting in abnormal growth. We sequenced and compared the genomes of 20 isolates of Rhodococcus to gain insights into the mechanisms and evolution of virulence in these bacteria. Horizontal gene transfer was identified as critical but limited in the scale of virulence evolution, as few loci are conserved and exclusive to phytopathogenic isolates. Although the fas operon is present in most phytopathogenic isolates, it is absent from phytopathogenic isolate A21d2. Instead, this isolate has a horizontally acquired gene chimera that encodes a novel fusion protein with isopentyltransferase and phosphoribohydrolase domains, predicted to be capable of catalyzing and activating cytokinins, respectively. Cytokinin profiling of the archetypal D188 isolate revealed only one activate cytokinin type that was specifically synthesized in a fas-dependent manner. These results suggest that only the isopentenyladenine cytokinin type is synthesized and necessary for Rhodococcus phytopathogenicity, which is not consistent with the extant model stating that a mixture of cytokinins is necessary for Rhodococcus to cause leafy gall symptoms. In all, data indicate that only four horizontally acquired functions are sufficient to confer the trait of phytopathogenicity to members of the genetically diverse clade of Rhodococcus.Journal ArticleSCOPUS: ar.jinfo:eu-repo/semantics/publishe
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Analysis of genome sequences from plant pathogenic Rhodococcus reveals genetic novelties in virulence loci
We report the sequence and characterization of the genomes of 21 isolates of Rhodococcus. Next generation sequencing technology was used to generate genome sequences. The reads for each genome were de novo assembled. The contigs were re-ordered, using the genome sequence of A44a as a reference. The program, Prokka, was used to automate the annotation of the genome sequences. The genome sequences, genbank files, and nucleotide and amino acid sequences for the predicted coding sequences are provided
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CreasonAllisonBotanyPlantPathologyAnalysisGenomeSequences.pdf
Members of Gram-positive Actinobacteria cause economically important diseases to plants. Within the Rhodococcus genus,
some members can cause growth deformities and persist as pathogens on a wide range of host plants. The current model
predicts that phytopathogenic isolates require a cluster of three loci present on a linear plasmid, with the fas operon central
to virulence. The Fas proteins synthesize, modify, and activate a mixture of growth regulating cytokinins, which cause a
hormonal imbalance in plants, resulting in abnormal growth. We sequenced and compared the genomes of 20 isolates of
Rhodococcus to gain insights into the mechanisms and evolution of virulence in these bacteria. Horizontal gene transfer was
identified as critical but limited in the scale of virulence evolution, as few loci are conserved and exclusive to
phytopathogenic isolates. Although the fas operon is present in most phytopathogenic isolates, it is absent from
phytopathogenic isolate A21d2. Instead, this isolate has a horizontally acquired gene chimera that encodes a novel fusion
protein with isopentyltransferase and phosphoribohydrolase domains, predicted to be capable of catalyzing and activating
cytokinins, respectively. Cytokinin profiling of the archetypal D188 isolate revealed only one activate cytokinin type that was
specifically synthesized in a fas-dependent manner. These results suggest that only the isopentenyladenine cytokinin type is
synthesized and necessary for Rhodococcus phytopathogenicity, which is not consistent with the extant model stating that a
mixture of cytokinins is necessary for Rhodococcus to cause leafy gall symptoms. In all, data indicate that only four
horizontally acquired functions are sufficient to confer the trait of phytopathogenicity to members of the genetically diverse
clade of Rhodococcus
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CreasonAllisonBotanyPlantPathologyAnalysisGenomeSequences_SupportingInformation.zip
Members of Gram-positive Actinobacteria cause economically important diseases to plants. Within the Rhodococcus genus,
some members can cause growth deformities and persist as pathogens on a wide range of host plants. The current model
predicts that phytopathogenic isolates require a cluster of three loci present on a linear plasmid, with the fas operon central
to virulence. The Fas proteins synthesize, modify, and activate a mixture of growth regulating cytokinins, which cause a
hormonal imbalance in plants, resulting in abnormal growth. We sequenced and compared the genomes of 20 isolates of
Rhodococcus to gain insights into the mechanisms and evolution of virulence in these bacteria. Horizontal gene transfer was
identified as critical but limited in the scale of virulence evolution, as few loci are conserved and exclusive to
phytopathogenic isolates. Although the fas operon is present in most phytopathogenic isolates, it is absent from
phytopathogenic isolate A21d2. Instead, this isolate has a horizontally acquired gene chimera that encodes a novel fusion
protein with isopentyltransferase and phosphoribohydrolase domains, predicted to be capable of catalyzing and activating
cytokinins, respectively. Cytokinin profiling of the archetypal D188 isolate revealed only one activate cytokinin type that was
specifically synthesized in a fas-dependent manner. These results suggest that only the isopentenyladenine cytokinin type is
synthesized and necessary for Rhodococcus phytopathogenicity, which is not consistent with the extant model stating that a
mixture of cytokinins is necessary for Rhodococcus to cause leafy gall symptoms. In all, data indicate that only four
horizontally acquired functions are sufficient to confer the trait of phytopathogenicity to members of the genetically diverse
clade of Rhodococcus
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dataset_files.zip
We report the sequence and characterization of the genomes of 21 isolates of Rhodococcus. Next generation sequencing technology was used to generate genome sequences. The reads for each genome were de novo assembled. The contigs were re-ordered, using the genome sequence of A44a as a reference. The program, Prokka, was used to automate the annotation of the genome sequences. The genome sequences, genbank files, and nucleotide and amino acid sequences for the predicted coding sequences are provided