“Polar mutagenesis of bacterial transcriptional units using Cas12a”

Bacterial genes are often organized in functionally related transcriptional units or operons. One such example is the fimAICDFGH operon, which codes for type I fimbriae in Escherichia coli. We tested the hypothesis that markerless polar mutations could be efficiently engineered using CRISPR/Cas12a in the fim operon. Cas12a-mediated engineering of a terminator sequence inside the fimA gene occurred with efficiencies between 10 and 30%, whilst other types of mutations, such as a 97 bp deletion, occurred with 100% efficiency. Our results showed that some of the obtained mutants, including one with a single base substitution at the fim locus, had decreased mRNA levels of fimA, suggesting that the regulation of the fim operon was disrupted. We corroborated the polar effect of these mutants by phenotypic assays and quantitative PCR, showing up to a 43 fold decrease in expression of genes downstream fimA. We believe this strategy could be useful in engineering the transcriptional shut-down of multiple genes in one single step. For bio-production in E. coli, this opens the possibility of inhibiting competing metabolic routes.

Analysis and cloning of CP 1102 gene isolated from a medicinal plant

Calotropis procera is a common medicinal plant with various properties related with its latex which functions as a rich source of biologically active compounds. Latex is chemically diverse and the chemical and biochemical differences are considerable for different plant fluids. This plant can produce large quantity of latex. The study was performed to clone the CP1102 terminator region of gene in general expression vector PTZ57R/T. The objective was to make a variant of pJITT166 (size ~5.8kb) containing CP1102 terminator sequence to study different expression levels in future. The fragment of 341bp size was isolated. The pDNOR vector containing CP1102 terminator sequence was isolated and amplified by PCR. The forward and reverse primer specific to CP1102 terminator sequence which can amplify this sequence are designed by using bioinformatics tools.

Integration into the Phage Attachment Site, attB, Impairs Multicellular Differentiation in Stigmatella aurantiaca

ABSTRACT Stigmatella aurantiaca displays a complex developmental life cycle in response to starvation conditions that results in the formation of tree-like fruiting bodies capable of producing spores. The phage Mx8, first isolated from the close relative Myxococcus xanthus, is unable to infect S. aurantiaca cells and integrate into the genome. However, plasmids containing Mx8 fragments encoding the integrase and attP are able to integrate at the attB locus in the S. aurantiaca genome by site-specific recombination. After recombination between attP and attB, the S. aurantiaca cells were incapable of building normal fruiting bodies but formed clumps and fungus-like structures characteristic of intermediate stages of development displayed by the wild type. We identified two tRNA genes, trnD and trnV, encoding tRNAAsp and tRNAVal, respectively, composing an operon at the attB locus of S. aurantiaca. Integration of attP-containing plasmids resulted in the incorporation of the tMx8 terminator sequence, in addition to a short sequence of Mx8 DNA downstream of trnD. The integrant was unable to process the trnD transcript at the normal 3′ processing site and displayed a lower level of expression of the trnVD operon. In addition, several developmentally regulated proteins were no longer produced in mutants following insertion at the attB locus. We hypothesize that the integration of the tMx8 terminator sequence results in reduced levels of mature tRNAAsp and tRNAVal and that altered protein production during development is thereby responsible for the observed phenotype. The trnVD locus thus defines a new developmental checkpoint for Stigmatella aurantiaca.

SsrA-Mediated Tagging in Bacillus subtilis

ABSTRACT A general mechanism in bacteria to rescue stalled ribosomes involves a stable RNA encoded by the ssrA gene. This RNA, termed tmRNA, encodes a proteolytic peptide tag which is cotranslationally added to truncated polypeptides, thereby targeting them for rapid proteolysis. To study this ssrA-mediated mechanism in Bacillus subtilis, a bipartite detection system was constructed that was composed of the HrcA transcriptional repressor and the bgaB reporter gene coding for a heat-stable β-galactosidase fused to an HrcA-controlled promoter. After the predicted proteolysis tag was fused to HrcA, the reporter β-galactosidase was expressed constitutively at a high level due to the instability of the tagged HrcA. Replacement of the two C-terminal alanine residues of the tag by aspartate rendered the repressor stable. Replacement of the hrcA stop codon by a transcriptional terminator sequence rendered the protein unstable; this was caused bytrans translational addition of the proteolytic tag. Inactivating the B. subtilis ssrA or smpB(yvaI) gene prevented the trans translational tagging reaction. Various protease-deficient strains of B. subtilis were tested for proteolysis of tagged HrcA. HrcA remained stable only in clpX or clpP knockouts, which suggests that this ATP-dependent protease is primarily responsible for the degradation of SsrA-tagged proteins in B. subtilis.

Genetic Locus for Streptolysin S Production by Group A Streptococcus

ABSTRACT Group A streptococcus (GAS) is an important human pathogen that causes pharyngitis and invasive infections, including necrotizing fasciitis. Streptolysin S (SLS) is the cytolytic factor that creates the zone of beta-hemolysis surrounding GAS colonies grown on blood agar. We recently reported the discovery of a potential genetic determinant involved in SLS production, sagA, encoding a small peptide of 53 amino acids (S. D. Betschel, S. M. Borgia, N. L. Barg, D. E. Low, and J. C. De Azavedo, Infect. Immun. 66:1671–1679, 1998). Using transposon mutagenesis, chromosomal walking steps, and data from the GAS genome sequencing project (www.genome.ou.edu/strep.html ), we have now identified a contiguous nine-gene locus (sagA to sagI) involved in SLS production. The sag locus is conserved among GAS strains regardless of M protein type. Targeted plasmid integrational mutagenesis of each gene in the sag operon resulted in an SLS-negative phenotype. Targeted integrations (i) upstream of the sagA promoter and (ii) downstream of a terminator sequence after sagI did not affect SLS production, establishing the functional boundaries of the operon. A rho-independent terminator sequence between sagA andsagB appears to regulate the amount of sagAtranscript produced versus transcript for the entire operon. Reintroduction of the nine-gene sag locus on a plasmid vector restored SLS activity to the nonhemolytic sagAknockout mutant. Finally, heterologous expression of the intactsag operon conferred the SLS beta-hemolytic phenotype to the nonhemolytic Lactococcus lactis. We conclude that gene products of the GAS sag operon are both necessary and sufficient for SLS production. Sequence homologies of sagoperon gene products suggest that SLS is related to the bacteriocin family of microbial toxins.

Role of the 3′ untranslated region of baculovirus p10 mRNA in high-level expression of foreign genes

The p10 gene of Autographa californica nucleopolyhedrovirus has two putative AATAAA polyadenylation signals. The downstream signal is used predominantly, as was determined by analysing 3′ cDNA ends. This downstream motif is followed by a GT-rich sequence, known to be important for efficient polyadenylation in mammalian systems. To analyse the importance of polyadenylation for p10 gene expression, recombinant viruses with altered 3′ untranslated regions (UTRs) were tested using chloramphenicol acetyltransferase (CAT) as a reporter. Surprisingly, after inactivation of the downstream AATAAA motif, CAT expression remained at the same high level as observed with a wild-type 3′ UTR. Polyadenylation occurred 24–28 nucleotides further downstream, probably due to an ATTAAA sequence motif. Replacing the p10 3′ UTR with the SV40 early terminator sequence as part of an hsp70–lacZ–SV40 gene cassette, which is commonly used in baculovirus expression vectors, resulted in a reduction in reporter gene expression. Polyadenylation occurred far more efficiently in the original p10 3′ UTR than in the SV40 terminator sequence, as was shown by testing the SV40 terminator separately. These results indicate that in order to obtain high levels of foreign gene expression, vectors that provide a wild-type p10 3′ UTR are to be preferred over those containing the hsp70–lacZ–SV40 gene cassette. Comparison of the p10 genes of various baculoviruses showed the presence of at least one AATAAA or ATTAAA motif in combination with a GT-rich sequence in the 3′ UTR, suggesting an evolutionary conservation of these two elements, thereby maintaining the high level of p10 gene expression.

Transcription inhibits the replication of autonomously replicating plasmids in human cells

This study addresses the effect of transcription on replication, using a system based on autonomously replicating plasmids in human cells. We added transcriptional elements from the human cytomegalovirus promoter/enhancer and the human beta-actin promoter to autonomously replicating plasmids based on human sequences and found that the transcriptional elements inhibited plasmid replication. Furthermore, conditional inhibition of plasmid replication was demonstrated by using a tetracycline-responsive promoter. We found that replication activity of plasmids carrying this promoter was inversely correlated with promoter activity. Replication activity was partially restored on plasmids when a transcriptional termination sequence was placed directly downstream of the promoter element. Transcriptional activity of the promoters and the efficacy of the terminator sequence were confirmed by using steady-state RNA analysis. These experiments suggest that transcription inhibits DNA replication on these plasmids and that the degree of inhibition is dependent on transcription strength. The possible significance of these results for chromosomal DNA replication are discussed.

Transcription inhibits the replication of autonomously replicating plasmids in human cells.

This study addresses the effect of transcription on replication, using a system based on autonomously replicating plasmids in human cells. We added transcriptional elements from the human cytomegalovirus promoter/enhancer and the human beta-actin promoter to autonomously replicating plasmids based on human sequences and found that the transcriptional elements inhibited plasmid replication. Furthermore, conditional inhibition of plasmid replication was demonstrated by using a tetracycline-responsive promoter. We found that replication activity of plasmids carrying this promoter was inversely correlated with promoter activity. Replication activity was partially restored on plasmids when a transcriptional termination sequence was placed directly downstream of the promoter element. Transcriptional activity of the promoters and the efficacy of the terminator sequence were confirmed by using steady-state RNA analysis. These experiments suggest that transcription inhibits DNA replication on these plasmids and that the degree of inhibition is dependent on transcription strength. The possible significance of these results for chromosomal DNA replication are discussed.