The SAM-II riboswitch is a RNA element found predominantly in alpha-proteobacteria that binds S-adenosyl methionine (SAM). Its structure and sequence appear to be unrelated to the SAM riboswitch found in Gram-positive bacteria. This SAM riboswitch is located upstream of the metA and metC genes in Agrobacterium tumefaciens, and other methionine and SAM biosynthesis genes in other alpha-proteobacteria. Like the other SAM riboswitch, it probably functions to turn off expression of these genes in response to elevated SAM levels. A significant variant of SAM-II riboswitches was found in Pelagibacter ubique and related marine bacteria and called SAM-V. Also, like many structured RNAs, SAM-II riboswitches can tolerate long loops between their stems.
The ykkC/yxkD leader is a conserved RNA structure found upstream of the ykkC and yxkD genes in Bacillus subtilis and related genes in other bacteria. The function of this family is unclear for many years although it has been suggested that it may function to switch on efflux pumps and detoxification systems in response to harmful environmental molecules. The Thermoanaerobacter tengcongensis sequence AE013027 overlaps with that of purine riboswitch suggesting that the two riboswitches may work in conjunction to regulate the upstream gene which codes for TTE0584 (Q8RC62), a member of the permease family.
The sucA RNA motif is a conserved RNA structure found in bacteria of the order Burkholderiales. RNAs within this motif are always found in the presumed 5' UTR of sucA genes. sucA encodes a subunit of an enzyme that participates in the citric acid cycle by synthesizing succinyl-CoA from 2-oxoglutarate. A part of the conserved structure overlaps predicted Shine-Dalgarno sequences of the downstream sucA genes. Because of the RNA motif's consistent gene association and a possible mechanism for sequestering the ribosome binding site, it was proposed that the sucA RNA motif corresponds to a cis-regulatory element. Its relatively complex secondary structure could indicate that it is a riboswitch. However, the function of this RNA motif remains unknown.
The asd RNA motif is a conserved RNA structure found is certain lactic acid bacteria. The asd motif was detected by bioinformatics and an individual asd RNA in Streptococcus pyogenes was detected by microarray and northern hybridization experiments as a 170-nucleotide molecule called "SR914400". The transcription start site determined for SR914400 corresponds to the 5′-end of the molecule shown in the consensus diagram.
The Bacteroidales-1 RNA motif is a conserved RNA structure identified by bioinformatics. It has been identified only in bacteria within the order (biology) Bacteroidales. Its presumed length is marked by a promoter on one end that conforms to an alternate consensus sequence that is common in the phylum Bacteroidetes, and its 3′ end is indicated by predicted transcription terminators. It is often located downstream of a gene that encodes the L20 ribosomal subunit, although it is unclear whether there is a functional reason underlying this apparent association.
The glutamine riboswitch is a conserved RNA structure that was predicted by bioinformatics. It is present in a variety of lineages of cyanobacteria, as well as some phages that infect cyanobacteria. It is also found in DNA extracted from uncultivated bacteria living in the ocean that are presumably species of cyanobacteria.
The leu/phe-leader RNA motif is a conserved RNA structure identified by bioinformatics. These RNAs function as peptide leaders. They contain a short open reading frame (ORF) that contains many codons for leucine or phenylalanine. Normally, expression of the downstream genes is suppressed. However, when cellular concentrations of the relevant amino acid is low, ribosome stalling leads to an alternate structure that enables downstream gene expression.
The Lnt RNA motif refers to a conserved RNA structure found in certain bacteria. Specifically, Lnt RNAs are known only in species within the phylum Chlorobi, and are located in the possible 5' untranslated regions of genes that are annotated as encoding apolipoprotein N-acyltransferase enzymes. There is some doubt as to whether the indicated motif is transcribed as RNA, or whether its reverse complement is transcribed. If the reverse complement is transcribed it would potentially in 5' UTRs of genes encoding bacteriochlorophyll A, and would be close to the start codon of those genes.
The Moco-II RNA motif is a conserved RNA structure identified by bioinformatics. However, only 8 examples of the RNA motif are known. The RNAs are potentially in the 5' untranslated regions of genes related to molybdenum cofactor (Moco), specifically a gene that encodes a molybdenum-binding domain and a nitrate reductase, which uses Moco as a cofactor. Thus the RNA might be involved in the regulation of genes based on Moco levels. Reliable predictions of Moco-II RNAs are restricted to deltaproteobacteria, but a Moco-II RNA might be present in a betaproteobacterial species. The Moco RNA motif is another RNA that is associated with Moco, and its complex secondary structure and genetic experiments have led to proposals that it is a riboswitch. However, the simpler structure of the Moco-II RNA motif is less typical of riboswitches. Moco-II RNAs are typically followed by a predicted rho-independent transcription terminator.
The mraW RNA motif is a conserved, structured RNA found in certain bacteria. Specifically, it is predicted in many, though not all, species of actinobacteria, and especially within the genus Mycobacterium. Structurally, the motif consists of a hairpin with a highly conserved terminal loop sequence. mraW RNAs are consistently in the presumed 5' untranslated regions of mraW genes. These mraW genes likely form operons with immediately downstream ftsI genes, and multiple types of mur genes. These genes are associated with peptidoglycan synthesis, and it was hypothesized that the mraW RNA motif might regulate these genes.
PhotoRC RNA motifs refer to conserved RNA structures that are associated with genes acting in the photosynthetic reaction centre of photosynthetic bacteria. Two such RNA classes were identified and called the PhotoRC-I and PhotoRC-II motifs. PhotoRC-I RNAs were detected in the genomes of some cyanobacteria. Although no PhotoRC-II RNA has been detected in cyanobacteria, one is found in the genome of a purified phage that infects cyanobacteria. Both PhotoRC-I and PhotoRC-II RNAs are present in sequences derived from DNA that was extracted from uncultivated marine bacteria.
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.
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.
The Pseudomon-Rho RNA motif refers to a conserved RNA structure that was discovered using bioinformatics. The RNAs that conform to this motif are found in species within the genus Pseudomonas, as well as the related Azotobacter vinelandii. They are consistently located in what could be the 5' untranslated regions of genes that encode the Rho factor protein, and this arrangement in bacteria suggested that Pseudomon-Rho RNAs might be cis-regulatory elements that regulate concentrations of the Rho protein.
The Rhizobiales-2 RNA motif is a set of RNAs found in certain bacteria that are presumed to be homologous because they conserve a common primary and secondary structure. The motif was discovered using bioinformatics, and is found only within bacteria that belong to the order Hyphomicrobiales, in turn a kind of alphaproteobacteria. Because Rhizobiales-2 RNAs are not consistently located in proximity to genes of a consistent class or function, these RNAs are presumed to function as non-coding RNAs.
The rne-II RNA motif is a conserved RNA structure identified using bioinformatics. It is detected only in species classified within the family Pseudomonadaceae, a group of gammaproteobacteria. rne-II RNAs are consistently located in the presumed 5' untranslated regions of genes that encode Ribonuclease E. The RNase E 5' UTR element is a previously identified RNA structure that is also found in the 5' UTRs of RNase E genes. However, the latter motif is found only in enterobacteria, and the two motifs have apparently unrelated structure. In view of their differences, it was hypothesized that rne-II RNAs fulfill the same functional role as RNase E 5' UTR elements, which is to regulate the levels of RNase E proteins by acting as a substrate for RNase E. Thus, when concentrations of RNase E are high, they will degrade their own messenger RNA.
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.
The sucC RNA motif is a conserved RNA structure discovered using bioinformatics. sucC RNAs are found in the genus Pseudomonas, and are consistently found in possible 5' untranslated regions of sucC genes. These genes encode Succinyl coenzyme A synthetase, and are hypothesised to be regulated by the sucC RNAs. sucC genes participate in the citric acid cycle, and another gene involved in the citric acid cycle, sucA, is also predicted to be regulated by a conserved RNA structure.
The traJ-II RNA motif is a conserved RNA structure discovered in bacteria by using bioinformatics. traJ-II RNAs appear to be in the 5' untranslated regions of protein-coding genes called traJ, which functions in the process of bacterial conjugation. A previously identified motif known as TraJ 5' UTR is also found upstream of traJ genes functions as the target of FinP antisense RNAs, so it is possible that traJ-II RNAs play a similar role as targets of an antisense RNA. However, some sequence features within the traJ-II RNA motif suggest that the biological RNA might be transcribed from the reverse-complement strand. Thus is it unclear whether traJ-II function as cis-regulatory elements. traJ-II RNAs are found in a variety of proteobacteria.
The Zeta-pan RNA motif is a conserved RNA structure that was discovered by bioinformatics. Zeta-pan motif RNAs are found in Zetaproteobacteria.
