The utilization of ribozyme-based synthetic switches in biotechnology has many advantages such as an increased robustness due to in
cis regulation, small coding space and a high degree of modularity. The report of small endonucleolytic twister ribozymes provides new opportunities for the development of advanced tools for engineering synthetic genetic switches. Here we show that the twister ribozyme is distinguished as an outstandingly flexible expression platform, which in conjugation with three different aptamer domains, enables the construction of many different one- and two-input regulators of gene expression in both bacteria and yeast. Besides important implications in biotechnology and synthetic biology, the observed versatility in artificial genetic control set-ups hints at possible natural roles of this widespread ribozyme class.
The nematode Caenorhabditis elegans represents an important research model. Convenient methods for conditional induction of gene expression in this organism are not available. Here we describe tetracycline-dependent ribozymes as versatile RNA-based genetic switches in C. elegans. Ribozyme insertion into the 3’-UTR converts any gene of interest into a tetracycline-inducible gene allowing temporal and, by using tissue-selective promoters, spatial control of expression in all developmental stages of the worm. Using the ribozyme switches we established inducible C. elegans polyglutamine Huntington’s disease models exhibiting ligand-controlled polyQ-huntingtin expression, inclusion body formation, and toxicity. Our approach circumvents the complicated expression of regulatory proteins. Moreover, only little coding space is necessary and natural promoters can be utilized. With these advantages tetracycline-dependent ribozymes significantly expand the genetic toolbox for C. elegans.
Recent bioinformatics studies have demonstrated a wide-spread occurrence of the hammerhead ribozyme (HHR) and similar small endonucleolytic RNA motifs in all domains of life. It is becoming increasingly evident that such ribozyme motifs participate in important genetic processes in diverse organisms. Although the HHR motif has been studied for more than three decades, only little is known about the consequences of ribozyme activity on gene expression. In the present study we analysed eight different naturally occurring HHR sequences in diverse genetic and organismal contexts. We investigated the influence of active ribozymes incorporated into mRNAs in mammalian, yeast and bacterial expression systems. The experiments show an unexpectedly high degree of organism-specific variability of ribozyme-mediated effects on gene expression. The presented findings demonstrate that ribozyme cleavage profoundly affect gene expression. However, the extent of this effect varies and depends strongly on the respective genetic context. The fast-cleaving type 3 HHRs [CChMVd(-) and sLTSV(-)] generally tended to cause the strongest effects on intracellular gene expression. The presented results are important in order to address potential functions of naturally occurring ribozymes in RNA processing and post-transcriptional regulation of gene expression. Additionally, our results are of interest for biotechnology and synthetic biology approaches that aim at the utilisation of self-cleaving ribozymes as widely applicable tools for controlling genetic processes.
In prokaryotes simple sequence repeats (SSRs) with unit sizes of 1–5
nucleotides (nt) are causative for phase and antigenic variation. Although an
increased abundance of heptameric repeats was noticed in bacteria, reports about SSRs
of 6–9 nt are rare. In particular G-rich repeat sequences with the propensity
to fold into G-quadruplex (G4) structures have received little attention. In silico
analysis of prokaryotic genomes show putative G4 forming sequences to be abundant.
This report focuses on a surprisingly enriched G-rich repeat of the type
in Xanthomonas and cyanobacteria
such as Nostoc. We studied in detail the genomes of
Xanthomonas campestris pv. campestris ATCC 33913
(Xcc), Xanthomonas axonopodis pv.
citri str. 306 (Xac), and Nostoc
sp. strain PCC7120 (Ana). In all three organisms repeats
are spread all over the genome with an over-representation in non-coding regions.
Extensive variation of the number of repetitive units was observed with repeat
numbers ranging from two up to 26 units. However a clear preference for four units
was detected. The strong bias for four units coincides with the requirement of four
consecutive G-tracts for G4 formation. Evidence for G4 formation of the consensus
repeat sequences was found in biophysical studies utilizing CD spectroscopy. The
G-rich repeats are preferably located between aligned open reading frames (ORFs) and
are under-represented in coding regions or between divergent ORFs. The G-rich repeats
are preferentially located within a distance of 50 bp upstream of an ORF on the
anti-sense strand or within 50 bp from the stop codon on the sense strand. Analysis
of whole transcriptome sequence data showed that the majority of repeat sequences are
transcribed. The genetic loci in the vicinity of repeat regions show increased
genomic stability. In conclusion, we introduce and characterize a special class of
highly abundant and wide-spread quadruplex-forming repeat sequences in bacteria.
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