The prokaryotic clusters of regularly interspaced palindromic repeats (CRISPR) system utilizes genomically encoded CRISPR RNA (crRNA), derived from invading viruses and incorporated into ribonucleoprotein complexes with CRISPR-associated (CAS) proteins, to target and degrade viral DNA or RNA on subsequent infection. RNA is targeted by the CMR complex. In Sulfolobus solfataricus, this complex is composed of seven CAS protein subunits (Cmr1-7) and carries a diverse "payload" of targeting crRNA. The crystal structure of Cmr7 and low-resolution structure of the complex are presented. S. solfataricus CMR cleaves RNA targets in an endonucleolytic reaction at UA dinucleotides. This activity is dependent on the 8 nt repeat-derived 5' sequence in the crRNA, but not on the presence of a protospacer-associated motif (PAM) in the target. Both target and guide RNAs can be cleaved, although a single molecule of guide RNA can support the degradation of multiple targets.
SummaryClusters of regularly interspaced short palindromic repeats (CRISPRs) of Sulfolobus fall into three main families based on their repeats, leader regions, associated cas genes and putative recognition sequences on viruses and plasmids. Spacer sequence matches to different viruses and plasmids of the Sulfolobales revealed some bias particularly for family III CRISPRs. Transcription occurs on both strands of the five repeat-clusters of Sulfolobus acidocaldarius and a repeat-cluster of the conjugative plasmid pKEF9. Leader strand transcripts cover whole repeat-clusters and are processed mainly from the 3Ј-end, within repeats, yielding heterogeneous 40-45 nt spacer RNAs. Processing of the pKEF9 leader transcript occurred partially in spacers, and was incomplete, probably reflecting defective repeat recognition by host enzymes. A similar level of transcripts was generated from complementary strands of each chromosomal repeat-cluster and they were processed to yield discrete~55 nt spacer RNAs. Analysis of the partially identical repeat-clusters of Sulfolobus solfataricus strains P1 and P2 revealed that spacer-repeat units are added upstream only when a leader and certain cas genes are linked. Downstream ends of the repeat-clusters are conserved such that deletions and recombination events occur internally.
Clusters of regularly spaced direct repeats, separated by unconserved spacer sequences, are ubiquitous in archaeal chromosomes and occur in some plasmids. Some clusters constitute around 1% of chromosomal DNA. Similarly structured clusters, generally smaller, also occur in some bacterial chromosomes. Although early studies implicated these clusters in segregation/partition functions, recent evidence suggests that the spacer sequences derive from extrachromosomal elements, and, primarily, viruses. This has led to the proposal that the clusters provide a defence against viral propagation in cells, and that both the mode of inhibition of viral propagation and the mechanism of adding spacer-repeat units to clusters, are dependent on RNAs transcribed from the clusters. Moreover, the putative inhibitory apparatus (piRNA-based) may be evolutionarily related to the interference RNA systems (siRNA and miRNA), which are common in eukarya. Here, we analyze all the current data on archaeal repeat clusters and provide some new insights into their diverse structures, transcriptional properties and mode of structural development. The results are consistent with larger cluster transcripts being processed at the centers of the repeat sequences and being further trimmed by exonucleases to yield a dominant, intracellular RNA species, which corresponds approximately to the size of a spacer. Furthermore, analysis of the extensive clusters of Sulfolobus solfataricus strains P1 and P2B provides support for the presence of a flanking sequence adjoining a cluster being a prerequisite for the incorporation of new spacer-repeat units, which occurs between the flanking sequence and the cluster. An archaeal database summarizing the data will be maintained at http://dac.molbio.ku.dk/dbs/SRSR/.
Sulfolobus acidocaldarius is an aerobic thermoacidophilic crenarchaeon which grows optimally at 80°C and pH 2 in terrestrial solfataric springs. Here, we describe the genome sequence of strain DSM639, which has been used for many seminal studies on archaeal and crenarchaeal biology. The circular genome carries 2,225,959 bp (37% G؉C) with 2,292 predicted protein-encoding genes. Many of the smaller genes were identified for the first time on the basis of comparison of three Sulfolobus genome sequences. Of the protein-coding genes, 305 are exclusive to S. acidocaldarius and 866 are specific to the Sulfolobus genus. Moreover, 82 genes for untranslated RNAs were identified and annotated. Owing to the probable absence of active autonomous and nonautonomous mobile elements, the genome stability and organization of S. acidocaldarius differ radically from those of Sulfolobus solfataricus and Sulfolobus tokodaii. The S. acidocaldarius genome contains an integrated, and probably encaptured, pARN-type conjugative plasmid which may facilitate intercellular chromosomal gene exchange in S. acidocaldarius. Moreover, it contains genes for a characteristic restriction modification system, a UV damage excision repair system, thermopsin, and an aromatic ring dioxygenase, all of which are absent from genomes of other Sulfolobus species. However, it lacks genes for some of their sugar transporters, consistent with it growing on a more limited range of carbon sources. These results, together with the many newly identified protein-coding genes for Sulfolobus, are incorporated into a public Sulfolobus database which can be accessed at http://dac.molbio.ku.dk/dbs/Sulfolobus.Sulfolobus acidocaldarius strain DSM639, the type strain of the archaeal genus Sulfolobus, was the first hyperthermoacidophile to be characterized from terrestrial solfataras by Brock et al. (12). It grows optimally at 75 to 80°C and pH 2 to 3, under strictly aerobic conditions, on complex organic substrates, including yeast extract, tryptone, and Casamino Acids and a limited number of sugars.Many of the seminal studies on archaea and crenarchaea were performed on S. acidocaldarius. Thus, S. acidocaldarius was employed to demonstrate the similarity of the archaeal and eukaryal transcription apparatuses (6, 36, 46). Moreover, its sensitivity to a wide range of ribosomal antibiotics (1) and ease of transformation (3) have rendered S. acidocaldarius a focus for in vivo genetic studies. Proteins responsible for chromatin folding (Sac7c) and the highly abundant Sac10b (Alba) protein, implicated in the regulation of chromatin and/or cellular RNAs in Sulfolobus (7, 30), were first characterized for this organism (29).S. acidocaldarius has also been used for studying genetic fidelity at high temperatures and is the only hyperthermophilic archaeon for which the rate and type of spontaneous mutation have been quantified in vivo (26). Its relatively low mutation rate, despite its high-temperature environment, has stimulated a strong interest in its efficient repair systems. It ...
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