scholarly journals Development of an on-disc isothermal in vitro amplification and detection of bacterial RNA

2017 ◽  
Vol 239 ◽  
pp. 235-242 ◽  
Author(s):  
Des Brennan ◽  
Helena Coughlan ◽  
Eoin Clancy ◽  
Nikolay Dimov ◽  
Thomas Barry ◽  
...  
Keyword(s):  
Bacterial Rna

scholarly journals Nucleic acid cleavage with a hyperthermophilic Cas9 from an uncultured Ignavibacterium

2019 ◽  
Vol 116 (46) ◽  
pp. 23100-23105 ◽  
Author(s):  
Stephanie Tzouanas Schmidt ◽  
Feiqiao Brian Yu ◽  
Paul C. Blainey ◽  
Andrew P. May ◽  
Stephen R. Quake
Keyword(s):  
Dna Cleavage ◽  
Elevated Temperatures ◽  
Hot Spring ◽  
Metagenomic Sequencing ◽  
Rna Seq ◽  
Bacterial Rna ◽  
Acid Cleavage ◽  
Cas9 Protein ◽  
Ribosomal Rrna

Clustered regularly interspaced short palindromic repeats (CRISPR)-associated 9 (Cas9) systems have been effectively harnessed to engineer the genomes of organisms from across the tree of life. Nearly all currently characterized Cas9 proteins are derived from mesophilic bacteria, and canonical Cas9 systems are challenged by applications requiring enhanced stability or elevated temperatures. We discovered IgnaviCas9, a Cas9 protein from a hyperthermophilic Ignavibacterium identified through mini-metagenomic sequencing of samples from a hot spring. IgnaviCas9 is active at temperatures up to 100 °C in vitro, which enables DNA cleavage beyond the 44 °C limit of Streptococcus pyogenes Cas9 (SpyCas9) and the 70 °C limit of both Geobacillus stearothermophilus Cas9 (GeoCas9) and Geobacillus thermodenitrificans T12 Cas9 (ThermoCas9). As a potential application of this enzyme, we demonstrate that IgnaviCas9 can be used in bacterial RNA-seq library preparation to remove unwanted cDNA from 16s ribosomal rRNA without increasing the number of steps, thus underscoring the benefits provided by its exceptional thermostability in improving molecular biology and genomic workflows. IgnaviCas9 is an exciting addition to the CRISPR-Cas9 toolbox and expands its temperature range.

scholarly journals Rifampin Resistance in Mycobacterium kansasii Is Associated with rpoB Mutations

2001 ◽  
Vol 45 (11) ◽  
pp. 3056-3058 ◽  
Author(s):  
John L. Klein ◽  
Timothy J. Brown ◽  
Gary L. French
Keyword(s):  
Mycobacterium Tuberculosis ◽  
Molecular Basis ◽  
Strong Association ◽  
Missense Mutations ◽  
Β Subunit ◽  
Mycobacterium Kansasii ◽  
Bacterial Rna ◽  
Rifampin Resistance ◽  
Potent Drug

ABSTRACT Rifampin is the most potent drug used in the treatment of disease due to Mycobacterium kansasii. A 69-bp fragment ofrpoB, the gene that encodes the β subunit of the bacterial RNA polymerase, was sequenced and found to be identical in five rifampin-susceptible clinical isolates of M. kansasii. This sequence showed 87% homology with the Mycobacterium tuberculosis gene, with an identical deduced amino acid sequence. In contrast, missense mutations were detected in the same fragment amplified from five rifampin-resistant isolates. A rifampin-resistant strain generated in vitro also harbored an rpoB gene missense mutation that was not present in the parent isolate. All mutations detected (in codons 513, 526, and 531) have previously been described in rifampin-resistant M. tuberculosis isolates. Rifampin MICs determined by E-test were <1 mg/liter for all rifampin-susceptible isolates and >256 mg/liter for all rifampin-resistant ones. In addition, four of the five rifampin-resistant isolates were also resistant to rifabutin. We have thus shown a strong association between rpoB gene missense mutations and rifampin resistance in M. kansasii. Although our results are derived from a small number of isolates and confirmation with larger numbers would be useful, they strongly suggest that mutations within rpoB form the molecular basis of rifampin resistance in this species.

scholarly journals Substitution of a Highly Conserved Histidine in the Escherichia coli Heat Shock Transcription Factor, σ32, Affects Promoter Utilization In Vitro and Leads to Overexpression of the Biofilm-Associated Flu Protein In Vivo

2007 ◽  
Vol 189 (23) ◽  
pp. 8430-8436 ◽  
Author(s):  
Olga V. Kourennaia ◽  
Pieter L. deHaseth
Keyword(s):  
Escherichia Coli ◽  
Heat Shock ◽  
Rna Polymerase ◽  
Sigma Factor ◽  
Stable Complex ◽  
Tryptophan Residue ◽  
Specific Sequence ◽  
Bacterial Rna

ABSTRACT The heat shock sigma factor (σ32 in Escherichia coli) directs the bacterial RNA polymerase to promoters of a specific sequence to form a stable complex, competent to initiate transcription of genes whose products mitigate the effects of exposure of the cell to high temperatures. The histidine at position 107 of σ32 is at the homologous position of a tryptophan residue at position 433 of the main sigma factor of E. coli, σ70. This tryptophan is essential for the strand separation step leading to the formation of the initiation-competent RNA polymerase-promoter complex. The heat shock sigma factors of all gammaproteobacteria sequenced have a histidine at this position, while in the alpha- and deltaproteobacteria, it is a tryptophan. In vitro the alanine-for-histidine substitution at position 107 (H107A) destabilizes complexes between the GroE promoter and RNA polymerase containing σ32, implying that H107 plays a role in formation or maintenance of the strand-separated complex. In vivo, the H107A substitution in σ32 impedes recovery from heat shock (exposure to 42°C), and it also leads to overexpression at lower temperatures (30°C) of the Flu protein, which is associated with biofilm formation.

scholarly journals Temperature-responsive in vitro RNA structurome of Yersinia pseudotuberculosis

2016 ◽  
Vol 113 (26) ◽  
pp. 7237-7242 ◽  
Author(s):  
Francesco Righetti ◽  
Aaron M. Nuss ◽  
Christian Twittenhoff ◽  
Sascha Beele ◽  
Kristina Urban ◽  
...  
Keyword(s):  
Structural Changes ◽  
Yersinia Pseudotuberculosis ◽  
Dynamic Condition ◽  
Rna Structures ◽  
Bacterial Rna ◽  
Different Temperatures ◽  
Metabolic Transition ◽  
Regulatory Potential ◽  
Response To Temperature

RNA structures are fundamentally important for RNA function. Dynamic, condition-dependent structural changes are able to modulate gene expression as shown for riboswitches and RNA thermometers. By parallel analysis of RNA structures, we mapped the RNA structurome of Yersinia pseudotuberculosis at three different temperatures. This human pathogen is exquisitely responsive to host body temperature (37 °C), which induces a major metabolic transition. Our analysis profiles the structure of more than 1,750 RNAs at 25 °C, 37 °C, and 42 °C. Average mRNAs tend to be unstructured around the ribosome binding site. We searched for 5′-UTRs that are folded at low temperature and identified novel thermoresponsive RNA structures from diverse gene categories. The regulatory potential of 16 candidates was validated. In summary, we present a dynamic bacterial RNA structurome and find that the expression of virulence-relevant functions in Y. pseudotuberculosis and reprogramming of its metabolism in response to temperature is associated with a restructuring of numerous mRNAs.

scholarly journals RNA helicase–regulated processing of the Synechocystis rimO–crhR operon results in differential cistron expression and accumulation of two sRNAs

2020 ◽  
Vol 295 (19) ◽  
pp. 6372-6386 ◽  
Author(s):  
Albert Remus R. Rosana ◽  
Denise S. Whitford ◽  
Anzhela Migur ◽  
Claudia Steglich ◽  
Sonya L. Kujat-Choy ◽  
...  
Keyword(s):  
Small Rnas ◽  
Rna Helicase ◽  
Rnase E ◽  
Gene Encoding ◽  
Modeling And Analysis ◽  
Dead Box ◽  
Bacterial Rna ◽  
Additional Processing ◽  
Operon Expression

The arrangement of functionally-related genes in operons is a fundamental element of how genetic information is organized in prokaryotes. This organization ensures coordinated gene expression by co-transcription. Often, however, alternative genetic responses to specific stress conditions demand the discoordination of operon expression. During cold temperature stress, accumulation of the gene encoding the sole Asp–Glu–Ala–Asp (DEAD)-box RNA helicase in Synechocystis sp. PCC 6803, crhR (slr0083), increases 15-fold. Here, we show that crhR is expressed from a dicistronic operon with the methylthiotransferase rimO/miaB (slr0082) gene, followed by rapid processing of the operon transcript into two monocistronic mRNAs. This cleavage event is required for and results in destabilization of the rimO transcript. Results from secondary structure modeling and analysis of RNase E cleavage of the rimO–crhR transcript in vitro suggested that CrhR plays a role in enhancing the rate of the processing in an auto-regulatory manner. Moreover, two putative small RNAs are generated from additional processing, degradation, or both of the rimO transcript. These results suggest a role for the bacterial RNA helicase CrhR in RNase E-dependent mRNA processing in Synechocystis and expand the known range of organisms possessing small RNAs derived from processing of mRNA transcripts.

scholarly journals Small subunits of RNA polymerase: localization, levels and implications for core enzyme composition

Microbiology ◽  
2010 ◽  
Vol 156 (12) ◽  
pp. 3532-3543 ◽  
Author(s):  
Geoff P. Doherty ◽  
Mark J. Fogg ◽  
Anthony J. Wilkinson ◽  
Peter J. Lewis
Keyword(s):  
Fluorescent Protein ◽  
Gram Negative Bacteria ◽  
Gram Positive ◽  
Gram Negative ◽  
Gram Positive Bacteria ◽  
The Core ◽  
Bacterial Rna ◽  
Green Fluorescent

Bacterial RNA polymerases (RNAPs) contain several small auxiliary subunits known to co-purify with the core α, β and β′ subunits. The ω subunit is conserved between Gram-positive and Gram-negative bacteria, while the δ subunit is conserved within, but restricted to, Gram-positive bacteria. Although various functions have been assigned to these subunits via in vitro assays, very little is known about their in vivo roles. In this work we constructed a pair of vectors to investigate the subcellular localization of the δ and ω subunits in Bacillus subtilis with respect to the core RNAP. We found these subunits to be closely associated with RNAP involved in transcribing both mRNA and rRNA operons. Quantification of these subunits revealed δ to be present at equimolar levels with RNAP and ω to be present at around half the level of core RNAP. For comparison, the localization and quantification of RNAP β′ and ω subunits in Escherichia coli was also investigated. Similar to B. subtilis, β′ and ω closely associated with the nucleoid and formed subnucleoid regions of high green fluorescent protein intensity, but, unlike ω in B. subtilis, ω levels in E. coli were close to parity with those of β′. These results indicate that δ is likely to be an integral RNAP subunit in Gram-positives, whereas ω levels differ substantially between Gram-positives and -negatives. The ω subunit may be required for RNAP assembly and subsequently be turned over at different rates or it may play roles in Gram-negative bacteria that are performed by other factors in Gram-positives.

scholarly journals A Phylogeny of Bacterial RNA Nucleotidyltransferases: Bacillus halodurans Contains Two tRNA Nucleotidyltransferases

2005 ◽  
Vol 187 (17) ◽  
pp. 5927-5936 ◽  
Author(s):  
Patricia Bralley ◽  
Samantha A. Chang ◽  
George H. Jones
Keyword(s):  
Bacterial Species ◽  
Bacillus Halodurans ◽  
Bacterial Rna ◽  
Unrooted Phylogenetic Tree ◽  
The Family ◽  
Protein Functions ◽  
Polymerase I ◽  
Rna Polyadenylation

ABSTRACT We have analyzed the distribution of RNA nucleotidyltransferases from the family that includes poly(A) polymerases (PAP) and tRNA nucleotidyltransferases (TNT) in 43 bacterial species. Genes of several bacterial species encode only one member of the nucleotidyltransferase superfamily (NTSF), and if that protein functions as a TNT, those organisms may not contain a poly(A) polymerase I like that of Escherichia coli. The genomes of several of the species examined encode more than one member of the nucleotidyltransferase superfamily. The function of some of those proteins is known, but in most cases no biochemical activity has been assigned to the NTSF. The NTSF protein sequences were used to construct an unrooted phylogenetic tree. To learn more about the function of the NTSFs in species whose genomes encode more than one, we have examined Bacillus halodurans. We have demonstrated that B. halodurans adds poly(A) tails to the 3′ ends of RNAs in vivo. We have shown that the genes for both of the NTSFs encoded by the B. halodurans genome are transcribed in vivo. We have cloned, overexpressed, and purified the two NTSFs and have shown that neither functions as poly(A) polymerase in vitro. Rather, the two proteins function as tRNA nucleotidyltransferases, and our data suggest that, like some of the deep branching bacterial species previously studied by others, B. halodurans possesses separate CC- and A-adding tRNA nucleotidyltransferases. These observations raise the interesting question of the identity of the enzyme responsible for RNA polyadenylation in Bacillus.

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