Ocean-V RNA motif

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Ocean-V RNA
Ocean-V-RNA.svg
Consensus secondary structure of Ocean-V RNAs
Identifiers
SymbolOcean-V
Rfam RF01714
Other data
RNA typesRNA
Domain(s) Ocean metagenome
PDB structures PDBe

The Ocean-V RNA motif is a conserved RNA structure discovered using bioinformatics. [1] Only a few Ocean-V RNA sequences have been detected, all in sequences derived from DNA that was extracted from uncultivated bacteria found in ocean water. As of 2010, no Ocean-V RNA has been detected in any known, cultivated organism. [1]

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RNAs present in environmental samples

A wide variety of non-coding RNAs have been identified in various species of organisms known to science. However, RNAs have also been identified in "metagenomics" sequences derived from samples of DNA or RNA extracted from the environment, which contain unknown species. Initial work in this area detected homologs of known bacterial RNAs in such metagenome samples. Many of these RNA sequences were distinct from sequences within cultivated bacteria, and provide the potential for additional information on the RNA classes to which they belong.

Asd RNA motif

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Gut-1 RNA motif

The Gut-1 RNA motif is a conserved RNA structure identified by bioinformatics. These RNAs are present in environmental sequences, and as of 2010 are not known to be present in any species that has been grown under laboratory conditions. Gut-1 RNA is exclusively found in DNA from uncultivated bacteria present in samples from the human gut.

L17DE RNA motif

The L17 downstream element RNA motif is a conserved RNA structure identified in bacteria by bioinformatics. All known L17 downstream elements were detected immediately downstream of genes encoding the L17 subunit of the ribosome, and therefore might be in the 3' untranslated regions of these genes. The element is found in a variety of lactic acid bacteria and in the genus Listeria.

Lacto-<i>rpoB</i> RNA motif

The Lacto-rpoB RNA motif is a conserved RNA structure identified by bioinformatics. It has been detected only in lactic acid bacteria, and is always located in the presumed 5' untranslated regions of rpoB genes. These genes encode a subunit of RNA polymerase, and it is hypothesized that Lacto-rpoB RNA participate in the regulation of these genes.

ManA RNA motif

The manA RNA motif refers to a conserved RNA structure that was identified by bioinformatics. Instances of the manA RNA motif were detected in bacteria in the genus Photobacterium and phages that infect certain kinds of cyanobacteria. However, most predicted manA RNA sequences are derived from DNA collected from uncultivated marine bacteria. Almost all manA RNAs are positioned such that they might be in the 5' untranslated regions of protein-coding genes, and therefore it was hypothesized that manA RNAs function as cis-regulatory elements. Given the relative complexity of their secondary structure, and their hypothesized cis-regulatory role, they might be riboswitches.

The wcaG RNA motif is an RNA structure conserved in some bacteria that was detected by bioinformatics. wcaG RNAs are found in certain phages that infect cyanobacteria. Most known wcaG RNAs were found in sequences of DNA extracted from uncultivated marine bacteria. wcaG RNAs might function as cis-regulatory elements, in view of their consistent location in the possible 5' untranslated regions of genes. It was suggested the wcaG RNAs might further function as riboswitches.

The nuoG RNA motif is a conserved RNA structure detected by bioinformatics. It is located in the presumed 5' untranslated regions of nuoG genes. This gene and the downstream genes probably comprise an operon that encodes various subunits of ubiquinone reductase enzyme.

PhotoRC RNA motifs

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potC RNA motif

The potC RNA motif is a conserved RNA structure discovered using bioinformatics. The RNA is detected only in genome sequences derived from DNA that was extracted from uncultivated marine bacteria. Thus, this RNA is present in environmental samples, but not yet found in any cultivated organism. potC RNAs are located in the presumed 5' untranslated regions of genes predicted to encode either membrane transport proteins or peroxiredoxins. Therefore, it was hypothesized that potC RNAs are cis-regulatory elements, but their detailed function is unknown.

psaA RNA motif

The psaA RNA motif describes a class of RNAs with a common secondary structure. psaA RNAs are exclusively found in locations that presumably correspond to the 5' untranslated regions of operons formed of psaA and psaB genes. For this reason, it was hypothesized that psaA RNAs function as cis-regulatory elements of these genes. The psaAB genes encode proteins that form subunits in the photosystem I structure used for photosynthesis. psaA RNAs have been detected only in cyanobacteria, which is consistent with their association with photosynthesis.

RadC RNA motif

The radC RNA motif is a conserved RNA structure identified by bioinformatics. The radC RNA motif is found in certain bacteria where it is consistent located in the presumed 5' untranslated regions of genes whose encoded proteins bind DNA are interact with other proteins that bind DNA. These proteins include integrases, methyltransferases that might methylate DNA, proteins that inhibit restriction enzymes and radC genes. Although radC genes were thought to encode DNA repair proteins, this conclusion was based on mutation data that was later shown to affect a different gene. However, it is still possible that radC genes play some DNA-related role. No radC RNAs have been detected in any purified phage whose sequence was available as of 2010, although integrases are often used by phages.

SAM-Chlorobi RNA motif

The SAM-Chlorobi RNA motif is a conserved RNA structure that was identified by bioinformatics. The RNAs are found only in bacteria classified as within the phylum Chlorobi. These RNAs are always in the 5' untranslated regions of operons that contain metK and ahcY genes. metK genes encode methionine adenosyltransferase, which synthesizes S-adenosyl methionine (SAM), and ahcY genes encode S-adenosylhomocysteine hydrolase, which degrade the related metabolite S-Adenosyl-L-homocysteine (SAH). In fact all predicted metK and ahcY genes within Chlorobi bacteria as of 2010 are preceded by predicted SAM-Chlorobi RNAs. Predicted promoter sequences are consistently found upstream of SAM-Chlorobi RNAs, and these promoter sequences imply that SAM-Chlorobi RNAs are indeed transcribed as RNAs. The promoter sequences are commonly associated with strong transcription in the phyla Chlorobi and Bacteroidetes, but are not used by most lineages of bacteria. The placement of SAM-Chlorobi RNAs suggests that they are involved in the regulation of the metK/ahcY operon through an unknown mechanism.

Termite-flg RNA motif

The Termite-flg RNA motif is a conserved RNA structure identified by bioinformatics. Genomic sequences corresponding to Termite-flg RNAs have been identified only in uncultivated bacteria present in the termite hindgut. As of 2010 it has not been identified in the DNA of any cultivated species, and is thus an example of RNAs present in environmental samples.

Termite-leu RNA motif

The Termite-leu RNA motif is a conserved RNA structure discovered by bioinformatics. It is found only in DNA sequences extracted from uncultivated bacteria living in termite hindguts, and has not yet been detected in any known cultivated organism. In many cases, Termite-leu RNAs are found in the likely 5′ untranslated regions of multive genes related to the synthesis of the amino acid leucine. However, in several cases it is not found in this type of location. Therefore, it was considered ambiguous as to whether Termite-leu RNAs constitute cis-regulatory elements.

TwoAYGGAY RNA motif

The TwoAYGGAY RNA motif is a conserved RNA structure identified by bioinformatics. Its name refers to the conserved AYGGAY nucleotide sequence found in the motif's two terminal loops. The RNAs are found in sequences derived from DNA extracted from uncultivated bacteria present in the human gut, as well as some bacteria in the classes Clostridia and Gammaproteobacteria.

Whalefall-1 RNA motif

The Whalefall-1 RNA motif refers to a conserved RNA structure that was discovered using bioinformatics. Structurally, the motif consists of two stem-loops, the second of which is often terminated by a CUUG tetraloop, which is an energetically favorable RNA sequence. Whalefall-1 RNAs are found only in DNA extracted from uncultivated bacteria found on whale fall, i.e., a whale carcass. As of 2010, Whalefall-1 RNAs have not been detected in any known, cultivated species of bacteria, and are thus one of several RNAs present in environmental samples.

Pedo-repair RNA motif

The Pedo-repair RNA motif is a conserved RNA structure identified by using bioinformatics. It has been detected in only one species of bacteria: Pedobacter sp. BAL39, within the phylum Bacteroidetes. The motif might be in the 5′ untranslated regions of operons containing genes predicted to be involved in DNA repair or related to restriction enzymes.

Non-coding RNAs have been discovered using both experimental and bioinformatic approaches. Bioinformatic approaches can be divided into three main categories. The first involves homology search, although these techniques are by definition unable to find new classes of ncRNAs. The second category includes algorithms designed to discover specific types of ncRNAs that have similar properties. Finally, some discovery methods are based on very general properties of RNA, and are thus able to discover entirely new kinds of ncRNAs.

References

  1. 1 2 Weinberg Z, Wang JX, Bogue J, et al. (March 2010). "Comparative genomics reveals 104 candidate structured RNAs from bacteria, archaea and their metagenomes". Genome Biol. 11 (3): R31. doi:10.1186/gb-2010-11-3-r31. PMC   2864571 . PMID   20230605.