7,751 research outputs found
A laboratory methodology for dual RNA-sequencing of bacteria and their host cells in vitro
© 2017 Marsh, Humphrys and Myers. Dual RNA-Sequencing leverages established next-generation sequencing (NGS)-enabled RNA-Seq approaches to measure genome-wide transcriptional changes of both an infecting bacteria and host cells. By simultaneously investigating both organisms from the same biological sample, dual RNA-Seq can provide unique insight into bacterial infection processes and reciprocal host responses at once. However, the difficulties involved in handling both prokaryotic and eukaryotic material require distinct, optimized procedures. We previously developed and applied dual RNA-Seq to measure prokaryotic and eukaryotic expression profiles of human cells infected with bacteria, using in vitro Chlamydia-infected epithelial cells as proof of principle. Here we provide a detailed laboratory protocol for in vitro dual RNA-Seq that is readily adaptable to any host-bacteria system of interest
Ion torrent-based transcriptional assessment of a Corynebacterium pseudotuberculosis equi strain reveals denaturing high-performance liquid chromatography a promising rRNA depletion method
Corynebacterium pseudotuberculosis equi is a Gram-positive pathogenic bacterium which affects a variety of hosts. Besides the great economic losses it causes to horse-breeders, this organism is also known to be an important infectious agent to cattle and buffaloes. As an outcome of the efforts in characterizing the molecular basis of its virulence, several complete genome sequences were made available in recent years, enabling the large-scale assessment of genes throughout distinct isolates. Meanwhile, the RNA-seq stood out as the technology of choice for comprehensive transcriptome studies, which may bring valuable information regarding active genomic regions, despite of the still impeditive associated costs. In an attempt to increase the use of generated reads per instrument run, by effectively eliminating unwanted rRNAs from total RNA samples without relying on any commercially available kits, we applied denaturing high-performance liquid chromatography (DHPLC) as an alternative method to assess the transcriptional profile of C. pseudotuberculosis. We have found that the DHPLC depletion method, allied to Ion Torrent sequencing, allows mapping of transcripts in a comprehensive way and identifying novel transcripts when a de novo approach is used. These data encourage us to use DHPLC in future transcriptional evaluations in C. pseudotuberculosis
RNA-seq – Revealing Biological Insights in Bacteria
New technologies are constantly being released and the improvements therein bring advances not only to transcriptome, the focus of this chapter, but also to diverse areas of biological research. Since the announcement and application of the RNA-seq approach, discoveries are being made in this field, but when we consider bacterial species, this progress proceeded a few years behind. However, with the application of RNA-seq derivative approaches, we can gain biological insights into the bacterial world and aspire to uncover the mysteries involving gene expression, organization and other functional genomic features
Dual RNA sequencing (dRNA-Seq) of bacteria and their host cells
Bacterial pathogens subvert host cells by manipulating cellular pathways for survival and replication; in turn, host cells respond to the invading pathogen through cascading changes in gene expression. Deciphering these complex temporal and spatial dynamics to identify novel bacterial virulence factors or host response pathways is crucial for improved diagnostics and therapeutics. Dual RNA sequencing (dRNA-Seq) has recently been developed to simultaneously capture host and bacterial transcriptomes from an infected cell. This approach builds on the high sensitivity and resolution of RNA-Seq technology and is applicable to any bacteria that interact with eukaryotic cells, encompassing parasitic, commensal or mutualistic lifestyles. We pioneered dRNA-Seq to simultaneously capture prokaryotic and eukaryotic expression profiles of cells infected with bacteria, using in vitro Chlamydia-infected epithelial cells as proof of principle. Here we provide a detailed laboratory and bioinformatics protocol for dRNA-seq that is readily adaptable to any host-bacteria system of interest
Harnessing type I and type III CRISPR-Cas systems for genome editing
CRISPR-Cas (clustered regularly interspaced short palindromic repeats-CRISPR-associated) systems are widespread in archaea and bacteria, and research on their molecular mechanisms has led to the development of genome-editing techniques based on a few Type II systems. However, there has not been any report on harnessing a Type I or Type III system for genome editing. Here, a method was developed to repurpose both CRISPR-Cas systems for genetic manipulation in Sulfolobus islandicus, a thermophilic archaeon. A novel type of genome-editing plasmid (pGE) was constructed, carrying an artificial mini-CRISPR array and a donor DNA containing a non-target sequence. Transformation of a pGE plasmid would yield two alternative fates to transformed cells: wild-type cells are to be targeted for chromosomal DNA degradation, leading to cell death, whereas those carrying the mutant gene would survive the cell killing and selectively retained as transformants. Using this strategy, different types of mutation were generated, including deletion, insertion and point mutations. We envision this method is readily applicable to different bacteria and archaea that carry an active CRISPR-Cas system of DNA interference provided the protospacer adjacent motif (PAM) of an uncharacterized PAM-dependent CRISPR-Cas system can be predicted by bioinformatic analysis
GENETIC REMOVAL OF TOXIN AND INTEGRASE GENES FROM A STAPHYLOCOCCAL BACTERIOPHAGE
Bacteriophages, or phages, are viruses that specifically infect and kill bacterial cells. Phages are the most numerous biological entities on Earth, with an estimated population size of 1031 (1). Discovery, purification, and characterization of phages illuminate the composition of the microbial world and provide potential applications in medicine. To combat antibiotic-resistant bacteria, phages are being investigated as supplements or alternatives to antibiotics. Methicillin-resistant Staphylococcus aureus (MRSA) is a commonly acquired infection in hospitals that has become difficult to treat due to its resistance to antibiotics commonly used to treat ordinary S. aureus infections (20). Bacteriophage, JB, isolated from dairy cow hair samples by Tyler Nygaard at Montana State University, has the ability to infect MRSA USA300 strain LAC. Genome annotation of this phage characterized it as a 42,683 bp circularly permuted genome with 68 putative protein coding genes, and a G/C content of 35.2%. Through bioinformatic analysis it was discovered that in a cluster of reverse transcribed (genes 30-33), putative integrase and toxin genes were present (21). In order for this phage to be used therapeutically in mammalian organisms, the deletion of these genes is essential to prevent the possibility for the phage to produce viable lysogen bacterial cells with enhanced pathogenicity. Genetic engineering to remove genes 30-33 was performed using type the type II CRISPR-Cas9 system to generate a strictly lytic deletion mutant JB bacteriophage, JBΔ30-33. The creation of the lytic derivative of JB bacteriophage, JBΔ30-33, was confirmed by clear plaque morphology, polymerase chain reaction, and DNA sequencing
A transient homotypic interaction model for the influenza A virus NS1 protein effector domain
Influenza A virus NS1 protein is a multifunctional virulence factor consisting of an RNA binding domain (RBD), a short linker, an effector domain (ED), and a C-terminal 'tail'. Although poorly understood, NS1 multimerization may autoregulate its actions. While RBD dimerization seems functionally conserved, two possible apo ED dimers have been proposed (helix-helix and strand-strand). Here, we analyze all available RBD, ED, and full-length NS1 structures, including four novel crystal structures obtained using EDs from divergent human and avian viruses, as well as two forms of a monomeric ED mutant. The data reveal the helix-helix interface as the only strictly conserved ED homodimeric contact. Furthermore, a mutant NS1 unable to form the helix-helix dimer is compromised in its ability to bind dsRNA efficiently, implying that ED multimerization influences RBD activity. Our bioinformatical work also suggests that the helix-helix interface is variable and transient, thereby allowing two ED monomers to twist relative to one another and possibly separate. In this regard, we found a mAb that recognizes NS1 via a residue completely buried within the ED helix-helix interface, and which may help highlight potential different conformational populations of NS1 (putatively termed 'helix-closed' and 'helix-open') in virus-infected cells. 'Helix-closed' conformations appear to enhance dsRNA binding, and 'helix-open' conformations allow otherwise inaccessible interactions with host factors. Our data support a new model of NS1 regulation in which the RBD remains dimeric throughout infection, while the ED switches between several quaternary states in order to expand its functional space. Such a concept may be applicable to other small multifunctional proteins
ClgR regulation of chaperone and protease systems is essential for Mycobacterium tuberculosis parasitism of the macrophage
Chaperone and protease systems play essential roles in cellular homeostasis and have vital functions in controlling the abundance of specific cellular proteins involved in processes such as transcription, replication, metabolism and virulence. Bacteria have evolved accurate regulatory systems to control the expression and function of chaperones and potentially destructive proteases. Here, we have used a combination of transcriptomics, proteomics and targeted mutagenesis to reveal that the clp gene regulator (ClgR) of Mycobacterium tuberculosis activates the transcription of at least ten genes, including four that encode protease systems (ClpP1/C, ClpP2/C, PtrB and HtrA-like protease Rv1043c) and three that encode chaperones (Acr2, ClpB and the chaperonin Rv3269). Thus, M. tuberculosis ClgR controls a larger network of protein homeostatic and regulatory systems than ClgR in any other bacterium studied to date. We demonstrate that ClgR-regulated transcriptional activation of these systems is essential for M. tuberculosis to replicate in macrophages. Furthermore, we observe that this defect is manifest early in infection, as M. tuberculosis lacking ClgR is deficient in the ability to control phagosome pH 1 h post-phagocytosis
Transcription Analysis of Streptococcus thermophilus Phages in the Lysogenic State
AbstractThe transcription of prophage genes was studied in two lysogenic Streptococcus thermophilus cells by Northern blot and primer-extension experiments. In the lysogen containing the cos-site phage Sfi21 only two gene regions of the prophage were transcribed. Within the lysogeny module an 1.6-kb-long mRNA started at the promoter of the phage repressor gene and covered also the next two genes, including a superinfection exclusion (sie) gene. A second, quantitatively more prominent 1-kb-long transcript was initiated at the promoter of the sie gene. Another prophage transcript of 1.6-kb length covered a group of genes without database matches that were located between the lysin gene and the right attachment site. The rest of the prophage genome was transcriptionally silent. A very similar transcription pattern was observed for a S. thermophilus lysogen containing the pac-site phage O1205 as a prophage. Prophages from pathogenic streptococci encode virulence genes downstream of the lysin gene. We speculate that temperate phages from lactic streptococci also encode nonessential phage genes (“lysogenic conversion genes”) in this region that increase the ecological fitness of the lysogen to further their own evolutionary success. A comparative genome analysis revealed that many temperate phages from low GC content Gram-positive bacteria encode a variable number of genes in that region and none was linked to known phage-related function. Prophages from pathogenic streptococci encode toxin genes in this region. In accordance with theoretical predictions on prophage–host genome interactions a prophage remnant was detected in S. thermophilus that had lost most of the prophage DNA while transcribed prophage genes were spared from the deletion process
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