FMN riboswitch

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FMN riboswitch (RFN element)
RF00050-rscape.svg
Predicted secondary structure and sequence conservation of FMN
Identifiers
SymbolFMN
Alt. SymbolsRFN
Rfam RF00050
Other data
RNA type Cis-reg; riboswitch
Domain(s) Bacteria
GO GO:0010181
SO SO:0000035
PDB structures PDBe
Pictured is a FMN molecule bound in the binding sit of the FMN riboswitch. Adenine nucleotides A48, A85, and A99 (depicted with yellow carbons), as well as a positively charged magnesium ion (green) assist in binding. The planar isoalloxazine ring system of FMN (FMN depicted with green carbons) intercalates between A48 and A85. Uracil-like edges of the FMN ring system form specific Watson-Crick-like hydrogen bonds with the highly conserved A99 residue on the riboswitch. Lastly, the negatively charged phosphate group of FMN interacts with the positively charged magnesium ion, allowing this riboswitch to exhibit selectivity for the FMN. PDB code: 3F2Q FMNbinding.png
Pictured is a FMN molecule bound in the binding sit of the FMN riboswitch. Adenine nucleotides A48, A85, and A99 (depicted with yellow carbons), as well as a positively charged magnesium ion (green) assist in binding. The planar isoalloxazine ring system of FMN (FMN depicted with green carbons) intercalates between A48 and A85. Uracil-like edges of the FMN ring system form specific Watson–Crick-like hydrogen bonds with the highly conserved A99 residue on the riboswitch. Lastly, the negatively charged phosphate group of FMN interacts with the positively charged magnesium ion, allowing this riboswitch to exhibit selectivity for the FMN. PDB code: 3F2Q

The FMN riboswitch (also known as RFN element) is a highly conserved RNA element which is naturally occurring, and is found frequently in the 5'-untranslated regions of prokaryotic mRNAs that encode for flavin mononucleotide (FMN) biosynthesis and transport proteins. [1] [2] This element is a metabolite-dependent riboswitch that directly binds FMN in the absence of proteins, thus giving it the ability to regulate RNA expression by responding to changes in the concentration of FMN. [3] In Bacillus subtilis , previous studies have shown that this bacterium utilizes at least two FMN riboswitches, where one controls translation initiation, and the other controls premature transcription termination. [4] Regarding the second riboswitch in Bacilius subtilis , premature transcription termination occurs within the 5' untranslated region of the ribDEAHT operon, precluding access to the ribosome-binding site of ypaA mRNA. [3] [5] FMN riboswitches also have various magnesium and potassium ions dispersed throughout the nucleotide structure, some of which participate in binding of FMN. [6]

Contents

In the bacterium Fusobacterium nucleatum, FMN binding has been studied. The FMN riboswitch is able to selectively bind the FMN molecule due to several distinct nucleic acid residues, as well as some of the magnesium ions present in the overall riboswitch structure. FMN's planar isoalloxazine ring system intercalates between A48 and A85 residues on the riboswitch, thereby providing a continuous stacking alignment. Further, the uracil-like edge of the ring system forms specific Watson–Crick-like hydrogen bonds with a highly conserved A99 residue on the riboswitch. [6] An additional structural moiety of FMN, the ribityl group, uses one of its four oxygens for hydrogen bonding, whereas phosphate oxygens form additional hydrogen bonds with Watson–Crick edges of several conserved guanines. [7] The interaction between the phosphate of FMN and the RNA is also bridged by a magnesium ion, which directly coordinates the phosphate oxygen of FMN and a G33 residue, and forms several water-mediated contacts with neighboring nucleotides. [6]

A representation of the 3D structure of the FMN riboswitch. This derived from a crystal structure of the FMN riboswitch bound to FMN. PDB 3f4e EBI.png
A representation of the 3D structure of the FMN riboswitch. This derived from a crystal structure of the FMN riboswitch bound to FMN.

Function of FMN Riboswitch

The function of the FMN riboswitch is twofold; first, riboswitches contain an aptamer component, which allows this RNA molecule to bind to its target molecule, FMN, resulting in a series of conformational changes. These conformational changes occur between the bound and unbound states, and are contingent upon the presence or absence of FMN. Previous research has proposed that this riboswitch operates by forming an intrinsic terminator stem when FMN is present in sufficient amounts but folds into an alternative structure when FMN is absent. [4] Additional studies conducted on this riboswitch also suggest that these conformational changes in the structure of the FMN riboswitch are localized to specific nucleotide regions that form the binding pocket of this molecule. [8] These findings are congruent with binding events seen in other riboswitches and RNA molecules. [8] The second function of the FMN riboswitch is an expression platform, which either inhibits or activates expression of the genes associated with FMN.  

FMN Riboswitch's Role in Disease

While riboswitches are not present in mammalian eukaryotic cells, they are present in prokaryotic cells, thus making them possible targets for antibiotic drug development. Special interest is had with FMN riboswitches present in Fusobacterium nucleatum, as this bacterium plays a role in periodontal disease and other human infections, and is considered one of the most pathogenic bacteria of the genus. [6] The inherent plasticity of the FMN-binding pocket and the availability of large openings make the FMN riboswitch an attractive target for the structure-based design of analog FMN antimicrobial compounds. [6]

See also

Related Research Articles

<span class="mw-page-title-main">Riboswitch</span>

In molecular biology, a riboswitch is a regulatory segment of a messenger RNA molecule that binds a small molecule, resulting in a change in production of the proteins encoded by the mRNA. Thus, an mRNA that contains a riboswitch is directly involved in regulating its own activity, in response to the concentrations of its effector molecule. The discovery that modern organisms use RNA to bind small molecules, and discriminate against closely related analogs, expanded the known natural capabilities of RNA beyond its ability to code for proteins, catalyze reactions, or to bind other RNA or protein macromolecules.

<span class="mw-page-title-main">Cobalamin riboswitch</span>

Cobalamin riboswitch is a cis-regulatory element which is widely distributed in 5' untranslated regions of vitamin B12 (Cobalamin) related genes in bacteria.

<span class="mw-page-title-main">Glycine riboswitch</span> RNA element

The bacterial glycine riboswitch is an RNA element that can bind the amino acid glycine. Glycine riboswitches usually consist of two metabolite-binding aptamer domains with similar structures in tandem. The aptamers were originally thought to cooperatively bind glycine to regulate the expression of downstream genes. In Bacillus subtilis, this riboswitch is found upstream of the gcvT operon which controls glycine degradation. It is thought that when glycine is in excess it will bind to both aptamers to activate these genes and facilitate glycine degradation.

<span class="mw-page-title-main">YdaO/yuaA leader</span> RNA structure in bacteria

The YdaO/YuaA leader is a conserved RNA structure found upstream of the ydaO and yuaA genes in Bacillus subtilis and related genes in other bacteria. Its secondary structure and gene associations were predicted by bioinformatics.

<span class="mw-page-title-main">Lysine riboswitch</span>

The Lysine riboswitch is a metabolite binding RNA element found within certain messenger RNAs that serve as a precision sensor for the amino acid lysine. Allosteric rearrangement of mRNA structure is mediated by ligand binding, and this results in modulation of gene expression. Lysine riboswitch are most abundant in Bacillota and Gammaproteobacteria where they are found upstream of a number of genes involved in lysine biosynthesis, transport and catabolism. The lysine riboswitch has also been identified independently and called the L box.

<span class="mw-page-title-main">PreQ1 riboswitch</span>

The PreQ1-I riboswitch is a cis-acting element identified in bacteria which regulates expression of genes involved in biosynthesis of the nucleoside queuosine (Q) from GTP. PreQ1 (pre-queuosine1) is an intermediate in the queuosine pathway, and preQ1 riboswitch, as a type of riboswitch, is an RNA element that binds preQ1. The preQ1 riboswitch is distinguished by its unusually small aptamer, compared to other riboswitches. Its atomic-resolution three-dimensional structure has been determined, with the PDB ID 2L1V.

<span class="mw-page-title-main">Purine riboswitch</span>

A purine riboswitch is a sequence of ribonucleotides in certain messenger RNA (mRNA) that selectively binds to purine ligands via a natural aptamer domain. This binding causes a conformational change in the mRNA that can affect translation by revealing an expression platform for a downstream gene, or by forming a translation-terminating stem-loop. The ultimate effects of such translational regulation often take action to manage an abundance of the instigating purine, and might produce proteins that facilitate purine metabolism or purine membrane uptake.

<span class="mw-page-title-main">SAM riboswitch (S-box leader)</span>

The SAM riboswitch is found upstream of a number of genes which code for proteins involved in methionine or cysteine biosynthesis in Gram-positive bacteria. Two SAM riboswitches in Bacillus subtilis that were experimentally studied act at the level of transcription termination control. The predicted secondary structure consists of a complex stem-loop region followed by a single stem-loop terminator region. An alternative and mutually exclusive form involves bases in the 3' segment of helix 1 with those in the 5' region of helix 5 to form a structure termed the anti-terminator form. When SAM is unbound, the anti-terminator sequence sequesters the terminator sequence so the terminator is unable to form, allowing the polymerase to read-through the downstream gene. When S-Adenosyl methionine (SAM) is bound to the aptamer, the anti-terminator is sequestered by an anti-anti-terminator; the terminator forms and terminates the transcription. However, many SAM riboswitches are likely to regulate gene expression at the level of translation.

<span class="mw-page-title-main">T-box leader</span> RNA element

Usually found in gram-positive bacteria, the T box leader sequence is an RNA element that controls gene expression through the regulation of translation by binding directly to a specific tRNA and sensing its aminoacylation state. This interaction controls expression of downstream aminoacyl-tRNA synthetase genes, amino acid biosynthesis, and uptake-related genes in a negative feedback loop. The uncharged tRNA acts as the effector for transcription antitermination of genes in the T-box leader family. The anticodon of a specific tRNA base pairs to a specifier sequence within the T-box motif, and the NCCA acceptor tail of the tRNA base pairs to a conserved bulge in the T-box antiterminator hairpin.

<span class="mw-page-title-main">TPP riboswitch</span> RNA secondary structure

The TPP riboswitch, also known as the THI element and Thi-box riboswitch, is a highly conserved RNA secondary structure. It serves as a riboswitch that binds thiamine pyrophosphate (TPP) directly and modulates gene expression through a variety of mechanisms in archaea, bacteria and eukaryotes. TPP is the active form of thiamine (vitamin B1), an essential coenzyme synthesised by coupling of pyrimidine and thiazole moieties in bacteria. The THI element is an extension of a previously detected thiamin-regulatory element, the thi box, there is considerable variability in the predicted length and structures of the additional and facultative stem-loops represented in dark blue in the secondary structure diagram Analysis of operon structures has identified a large number of new candidate thiamin-regulated genes, mostly transporters, in various prokaryotic organisms. The x-ray crystal structure of the TPP riboswitch aptamer has been solved.

ykkC-yxkD leader Conserved RNA structure in bacteria

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.

<span class="mw-page-title-main">SMK box riboswitch</span>

The SMKbox riboswitch is an RNA element that regulates gene expression in bacteria. The SMK box riboswitch is found in the 5' UTR of the MetK gene in lactic acid bacteria. The structure of this element changes upon binding to S-adenosyl methionine (SAM) to a conformation that blocks the shine-dalgarno sequence and blocks translation of the gene.

<span class="mw-page-title-main">Riboflavin kinase</span> Class of enzymes

In enzymology, a riboflavin kinase is an enzyme that catalyzes the chemical reaction

The Magnesium responsive RNA element, not to be confused with the completely distinct M-box riboswitch, is a cis-regulatory element that regulates the expression of the magnesium transporter protein MgtA. It is located in the 5' UTR of this gene. The mechanism for the potential magnesium-sensing capacity of this RNA is still unclear, though a recent report suggests that the RNA element targets the mgtA transcript for degradation by RNase E when cells are grown in high Mg2+ environments.

<span class="mw-page-title-main">Mesoplasma florum riboswitch</span>

Riboswitches are cis-acting regulatory elements located within the 5’UTR of mRNA transcripts. These regulatory elements bind small molecules which results in a conformational change within the 5’UTR of the mRNA. The changes in the mRNA secondary structure subsequently result in changes in the expression of the adjacent open reading frame.

<span class="mw-page-title-main">SAM–SAH riboswitch</span> Bacterial RNA structure

The SAM–SAH riboswitch is a conserved RNA structure in certain bacteria that binds S-adenosylmethionine (SAM) and S-adenosylhomocysteine (SAH) and is therefore presumed to be a riboswitch. SAM–SAH riboswitches do not share any apparent structural resemblance to known riboswitches that bind SAM or SAH. The binding affinities for both compounds are similar, but binding for SAH is at least somewhat stronger. SAM–SAH riboswitches are exclusively found in Rhodobacterales, an order of alphaproteobacteria. They are always found in the apparent 5' untranslated regions of metK genes, which encode the enzyme that synthesizes SAM.

<span class="mw-page-title-main">Fluoride riboswitch</span> Fluoride-binding RNA structure

The fluoride riboswitch is a conserved RNA structure identified by bioinformatics in a wide variety of bacteria and archaea. These RNAs were later shown to function as riboswitches that sense fluoride ions. These "fluoride riboswitches" increase expression of downstream genes when fluoride levels are elevated, and the genes are proposed to help mitigate the toxic effects of very high levels of fluoride.

<span class="mw-page-title-main">Glutamine riboswitch</span> Glutamine-binding RNA structure

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.

<span class="mw-page-title-main">Tetrahydrofolate riboswitch</span> Class of homologous RNAs

Tetrahydrofolate riboswitches are a class of homologous RNAs in certain bacteria that bind tetrahydrofolate (THF). It is almost exclusively located in the probable 5' untranslated regions of protein-coding genes, and most of these genes are known to encode either folate transporters or enzymes involved in folate metabolism. For these reasons it was inferred that the RNAs function as riboswitches. THF riboswitches are found in a variety of Bacillota, specifically the orders Clostridiales and Lactobacillales, and more rarely in other lineages of bacteria. The THF riboswitch was one of many conserved RNA structures found in a project based on comparative genomics. The 3-d structure of the tetrahydrofolate riboswitch has been solved by separate groups using X-ray crystallography. These structures were deposited into the Protein Data Bank under accessions 3SD1 and 3SUX, with other entries containing variants.

<i>uup</i> RNA motif

The uup RNA motif is a conserved RNA structure that was discovered by bioinformatics. uup motif RNAs are found in Bacillota and Gammaproteobacteria.

References

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