ABSTRACT
Neisseria gonorrhoeae is capable of causing gonorrhoea and more complex diseases in the human host. Within the gonococcal genome are over 100 copies of the insertion sequence-like Correia repeat enclosed element (CREE), which has been predicted to be mobile within the neisserial genomes. Although there is evidence of ancestral movement of these elements, no previous study has provided evidence for current mobilization. CREE has the ability to alter gene expression and regulation in many ways: by insertional mutagenesis, by introducing promoter elements, by generating mRNA processing sites and by association with non-coding RNAs. Previous studies have compared the genomic locations of CREEs in the Neisseria spp., demonstrating that otherwise identical regions have either the element or the target TA insertion site. In this study, we report for the first time, to our knowledge, movement of CREEs, through inversion of the element at its chromosomal location. Analysis of Ion Torrent generated genome sequence data from N. gonorrhoeae strain NCCP11945 passaged for 8 weeks in the laboratory under standard conditions and stress conditions revealed a total of 37 inversions: 24 were exclusively seen in the stressed sample, 7 were seen in the control sample and the remaining 3 were seen in both samples. These inversions have the capability to alter gene expression in N. gonorrhoeae through the previously determined activities of the sequence features of these elements, potentially resulting in reversible phase-variable gene expression.
ABSTRACT
Neisseria gonorrhoeae is capable of causing gonorrhoea and more complex diseases in the human host. Neisseria meningitidis is a closely related pathogen that shares many of the same genomic features and virulence factors, but causes the life threatening diseases meningococcal meningitis and septicaemia. The importance of non-coding RNAs in gene regulation has become increasingly evident having been demonstrated to be involved in regulons responsible for iron acquisition, antigenic variation, and virulence. Neisseria spp. contain an IS-like element, the Correia Repeat Enclosed Element, which has been predicted to be mobile within the genomes or to have been in the past. This repeat, present in over 100 copies in the genome, has the ability to alter gene expression and regulation in several ways. We reveal here that Correia Repeat Enclosed Elements tend to be near non-coding RNAs in the Neisseria spp., especially N. gonorrhoeae. These results suggest that Correia Repeat Enclosed Elements may have disrupted ancestral regulatory networks not just through their influence on regulatory proteins but also for non-coding RNAs.
ABSTRACT
DNA uptake sequences are widespread throughout the Neisseria gonorrhoeae genome. These short, conserved sequences facilitate the exchange of endogenous DNA between members of the genus Neisseria. Often the DNA uptake sequences are present as inverted repeats that are able to form hairpin structures. It has been suggested previously that DNA uptake sequence inverted repeats present 3' of genes play a role in rho-independent termination and attenuation. However, there is conflicting experimental evidence to support this role. The aim of this study was to determine the role of DNA uptake sequences in transcriptional termination. Both bioinformatics predictions, conducted using TransTermHP, and experimental evidence, from RNA-seq data, were used to determine which inverted repeat DNA uptake sequences are transcriptional terminators and in which direction. Here we show that DNA uptake sequences in the inverted repeat configuration occur in N. gonorrhoeae both where the DNA uptake sequence precedes the inverted version of the sequence and also, albeit less frequently, in reverse order. Due to their symmetrical configuration, inverted repeat DNA uptake sequences can potentially act as bi-directional terminators, therefore affecting transcription on both DNA strands. This work also provides evidence that gaps in DNA uptake sequence density in the gonococcal genome coincide with areas of DNA that are foreign in origin, such as prophage. This study differentiates for the first time, to our knowledge, between DNA uptake sequences that form intrinsic transcriptional terminators and those that do not, providing characteristic features within the flanking inverted repeat that can be identified.