Project description:Mycobacterium tuberculosis has the ability to survive inside macrophages under acid-nitrosative stress. M. tuberculosis Rv1685c and its orthologue in M. smegmatis, MSMEG_3765, are induced on exposure to acid-nitrosative stress. Both genes are annotated as TetR transcriptional regulators, a family of proteins that regulate a wide range of cellular activities, including multidrug resistance, carbon catabolism and virulence. Here we demonstrate that MSMEG_3765 is co-transcribed with the upstream genes MSMEG_3762 and MSMEG_3763, encoding efflux pump components. RTq-PCR and GFP-reporter assays showed that the MSMEG_3762/63/65 gene cluster, and the orthologous region in M. tuberculosis (Rv1687c/86c/85c), was up-regulated in a MSMEG_3765 null mutant, suggesting that MSMEG_3765 acts as a repressor, typical of this family of regulators. We further defined the MSMEG_3765 regulon using genome-wide transcriptional profiling and confirmed that the MSMEG_3762/63/65 promoter is induced under acid-nitrosative stress. A putative 36 bp regulatory motif was identified upstream of the gene clusters in both M. smegmatis and M. tuberculosis and purified recombinant MSMEG_3765 protein was found to bind to DNA fragments containing this motif from both M. smegmatis and M. tuberculosis upstream regulatory regions. These results suggest that the TetR repressor MSMEG_3765/Rv1685c controls expression of an efflux pump with an, as yet, undefined role in the mycobacterial response to acid-nitrosative stress.

Project description:Carbon metabolism in Mycobacterium smegmatis was analysed using reverse-phase chromatography coupled to orbitrap high-resolution mass spectrometer using trypsin digestion. MS/MS files were searched against the Mycobacterium smegmatis strain MC2-155 database Release 1 - July 2010 ) by MaxQuant software (version 1.3.0.5). Mass spectra were searched with an initial mass tolerance of 7 ppm in MS mode and 0.5 Da in MS/MS mode. Up to two missed cleavages were allowed. Carbamidomethylation was set as a fixed modification, whereas oxidation (M), acetylation (Protein N-term) and Phospho (S, T, Y) were considered as variable modifications. Minimum required peptide length was set to seven amino acids and at least two (unique + razor) peptides were required for protein identification. A cut-off was fixed at 1% FDR at the peptide and protein level. Reverse and contaminants sequences were removed and proteins with a Posterior Error Probability (PEP) lower than 0.1 were accepted for further data treatment. Protein quantification was performed with razor and unique peptides, using only unmodified, oxidated (M) and acetylated (Protein N-term) peptides. A minimum of two ratio counts was required to quantify proteins.

Project description:Emerging evidence suggests that the cryptic translation beyond the annotated translatome may yield proteins with important function. However, the role and function mechanism of these cryptic ORFs in complex diseases such as cancer remain largely unknown. To fill this gap, we combined ribosome profiling and CRISPR/Cas9 screen to systematically identify the colorectal cancer (CRC) dependency on cryptic ORFs.

Project description:The delineation of genes in bacteria has remained an important challenge because prokaryotic genomes are often tightly packed frequently resulting in overlapping genes. We hereby present a de novo approach called REPARATION (RibosomeE Profiling Assisted (Re-)AnnotaTION) to delineate translated open reading frames (ORFs) in bacteria independent of (available) genome annotation. By deep sequencing of ribosome protected mRNA fragments (RPF) to map translating ribosomes across the entire genome, REPARATION takes advantage of the recently developed ribosome profiling (Ribo-seq) technique. REPARATION starts by traversing the entire genome to generate all possible ORFs and then collects their corresponding RPF signal information. Based on a growth curve model to estimate minimum ORF read density and Ribo-seq RPF coverage, thresholds indicative of translation is estimated. Finally, our algorithm applies a random forest model to build a classifier to classify putative protein coding ORFs. We evaluated the performance of REPARATION on 3 annotated bacterial species using in-house generated Ribo-seq data and matching N-terminal and shotgun proteomics data next to publically available Ribo-seq data. In all cases, about 80% of the ORFs predicted by REPARATION were previously annotated as protein coding. While 13-20% were variants of previously annotated ORFs and about 3-4% point to novel translated ORFs within intergenic or other regions previously annotated as non-coding. Without stringent length restrictions REPARATION was able to identify several small ORFs (sORFs). Multiple supportive evidence from matching MS data and sequence conservation analysis was obtained to validate predicted ORFs.

Project description:The gene expression during early (30min) and late (2.5hrs) infection of Mycobacteriophage Giles was analyzed, as well as in a Giles lysogen. Total RNA was isolated, depleted of rRNA and prepped for sequencing (Illumina) during early and late infection of Giles and a lysogen.

Project description:Here as an attempt to explore bacterial single-colony proteomics, we describe a quantitative mass spectrometry-based protocol to isolate and analyse the proteome of a single mycobacterial colony from 7H10 media. Tryptic peptides are evaluated with high performance liquid chromatography coupled with a hybrid quadrupole mass filter Orbitrap analyser (Q Exactive) and raw data analysed using the MaxQuant Suite and downstream analysis using Perseus software . A total of 7805 unique peptides and 1387 proteins were identified

Project description:Background: During the symbiosis with legumes, Bradyrhizobium japonicum cells infect roots where they induce the formation of root nodules and differentiate into intracellular nitrogen-fixing bacteroids. We used differential RNA-seq (dRNA-seq) for the genome-wide detection of transcriptional start sites (TSSs) in B. japonicum USDA 110 cells grown free-living or as bacteroids in soybean root nodules. Results: A newly developed TSS recognition procedure based on machine learning allowed us to map 15,923 TSSs: 14,360 in free-living bacteria, 4,329 in bacteroids and 2,766 in both living conditions. Using a proteogenomics approach, we provide evidence for the translation of 107 new transcripts including 14 with TSSs in annotated genes. In addition, we provide evidence for 178 shorter or longer proteins, 109 of them with TSS support. Based on our TSS map and a new de novo promoter prediction algorithm, we identified promoter motifs mainly used in nodules (similar to RpoN-dependent promoters) or under both conditions (similar to RpoD-dependent promoters). The data is made available in a generic feature format (GFF) file along with an updated and extended genome annotation comprising promoters, TSSs and terminators. The value of such a TSS and promoter map beyond the identification of novel transcripts and ORFs is illustrated by the experimental analysis of an antisense RNA, which is a by-product of transcriptional interference in a gene encoding a cytochrome P450 highly expressed in nodules. Conclusions: The genome-wide TSS and promoter map along with the extended genome annotation represents a very useful resource for detailed analyses of gene regulation and further systems biology studies on B. japonicum in symbiosis with soybean.

Project description:Ribosome profiling was applied for the first time on S. meliloti to generate a translatome map. Our work reveals active translation for several ORFs including small ORFs (sORFs). In addition, our ribosome profiling data led to the discovery of several translated non-annotated sORFs. Translation of these non-annotated sORFs was validated by proteomics and western blotting.

Project description:Investigation of whole genome gene expression level changes in a Mycobacterium smegmatis mc2 155 delta-MSMEG_0166 mutant, compared to the wild-type strain. MSMEG_0166 is a transcriptional regulator in the gntR family. Mutations in MSMEG_0166 result in hypersensitivity to the bactericidal ubiquitin peptide Ub2, as well as oxidative stress caused by either organic or inorganic agents A three chip study using total RNA recovered from three separate wild-type cultures of Mycobacterium smegmatis mc2 155 and three separate cultures of a MSMEG_0166 mutant strain, Mycobacterium smegmatis mc2 155 delta-MSMEG_0166, in which MSMEG_0166 is interupted by the insertion of a hygromycin resistance cassette. Each chip measures the expression level of 6,588 genes from Myobacterium smegmatis with five 60-mer probes per transcript and two replicates of each probe for a total of 65,880 experimental probes.

Project description:Prokaryotic genome annotation is highly dependent on automated methods, as manual curation cannot keep up with the exponential growth of sequenced genomes. Current automated techniques depend heavily on sequence context and often underestimate the complexity of the proteome. We developed REPARATION (RibosomeE Profiling Assisted (Re-)AnnotaTION), a de novo algorithm that takes advantage of experimental evidence from ribosome profiling (Ribo-seq) to delineate translated open reading frames (ORFs) in bacteria, independent of genome annotation. Ribo-seq next generation sequencing technique that provides a genome-wide snapshot of the position translating ribosome along an mRNA at the time of the experiment. REPARATION evaluates all possible ORFs in the genome and estimates minimum thresholds to screen for spurious ORFs based on a growth curve model. We applied REPARATION to three annotated bacterial species to obtain a more comprehensive mapping of their translation landscape in support of experimental data. In all cases, we identified hundreds of novel ORFs including variants of previously annotated and novel small ORFs (<71 codons). Our predictions were supported by matching mass spectrometry (MS) proteomics data and sequence conservation analysis. REPARATION is unique in that it makes use of experimental Ribo-seq data to perform de novo ORF delineation in bacterial genomes, and thus can identify putative coding ORFs irrespective of the sequence context of the reading frame.