Magnesium responsive RNA element

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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. [1] 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. [2]

Contents

Background

The term riboswitches refer to a collective group of cis-regulatory elements which are mostly located in the untranslated regions of messenger RNAs. The purpose of these molecules is that they have the ability to regulate gene expression through the association with different metabolites, and as such, do not require assistance from various protein factors. [3] These specific types of RNA can have individualized structures and functions, but for the most part, have certain features and functions which remain conserved.

Structure

Magnesium responsive RNA element
MGsensor SS.png
Identifiers
SymbolMg sensor
Rfam RF01056
Other data
RNA typeCis-regulatory element
Domain(s) Enterobacteriales
GO 0032026
PDB structures PDBe

The fundamental structure of a riboswitch consists of two structural elements which remain highly conserved in most of these types of RNAs. These two elements are the aptamer and the expression platform. The main role of the aptamer is to sense the presence of a specific ligand whereas the expression platform is more important in controlling gene expression in a variety of ways. [3] More specifically, in a bacterial riboswitch, it is noted that the expression platform is usually located downstream of the aptamer. As a result, this allows for the expression platform to be able to assess the degree of binding occurring between the ligand and the RNA so that it may function in a way that confers proper gene regulation and expression. [3] However, this property of expression platforms to manipulate their own tertiary structure to ensure proper gene expression is what allows for the alteration of these conserved regions which is not seen in the aptamer portion of the riboswitch. The aptamer region tends to maintain both its sequences and structures due to the fact that there are only four monomers which RNAs utilize in order to form the binding pocket which will serve as a binding site for a specific metabolite. [3] This differs from the expression platform because the structure, and possibly sequence, contained within this region of the riboswitch has the ability to engage in alternative folding structures that may contribute to the efficiency in which genes are expressed. [3] Thus, this warrants the observation that the expression platform tends to be less conserved evolutionary than the aptamer region.

Function

The evolutionary divergence of the expression platform from this conserved pathway has numerous implications in the various functions displayed by different riboswitches. Such functions can include transcription termination, translation initiation, eukaryotic splicing mechanisms, transcription interference, self-cleaving, and many more. [3] Of these functions, the most common function that simple riboswitches participate in is regulation of transcription termination. [3] In order to modulate this process, a bacterial riboswitch will aid in the development of a strong stem-like structure which is followed by a series of uridine residues. The purpose of this structure and sequence is to facilitate the appearance of an intrinsic transcription terminator. During transcription, this intrinsic terminator will be encountered by RNA polymerase and cause this transcriptional protein to briefly stall before releasing the DNA template and novel RNA product. [3] Nonetheless, though there are various types of riboswitches with various structures and functions, the remainder of this article is going to discuss the magnesium responsive RNA element and its respective structure and function.

Magnesium responsive RNA element

A specific type of bacterial riboswitch which plays a major role in maintaining magnesium homeostasis is known as the magnesium responsive RNA element. This riboswith is located in the 5' untranslated region of the gene mgtA which consists of 264 nucleotides. [4]

Structure

Much like other general riboswitches, the modulation of gene expression through ligand binding still stands. However, what makes this cis-regulatory element unique is the fact that it shares a distinct relationship with RNA through its positively-charged magnesium ion that serves as the ligand. [5] The structural function of this divalent ion involves the stabilization of complex RNA folds seen in the tertiary structure of an RNA molecule. Without the presence of the magnesium ion, the folding of RNA molecules which is utilized to form a proper ligand binding pocket would not be possible since the charge-charge repulsion due to the negatively-charged phosphate-rich RNA backbone would prevent this site from forming. [5]

Function

Moreover, recent studies have depicted the magnesium responsive RNA element as having two very distinct functions. The first function that has been characterized for this molecule is its ability to serve as a magnesium sensor. What this means is that in times when the concentration of magnesium is low in cells, this riboswitch will alter its conformation in such a way that it favors transcription elongation. [5] On the other hand, when the concentration of magnesium is high in cells, the riboswitch will again undergo a conformational change. However, this time the change in conformation will result in the transcriptional inactivation of downstream genes. [5] These changes in conformation result in the formation of a pseudoknot due to the mechanism in which the RNA element interacts with the magnesium ions. [6] The implication for this form of magnesium concentration-dependent regulation is for the purpose of maintaining a steady-state level of magnesium within the cells which is consistent with the theory of mass action. [7] It is important to note though that the actual mechanism by which the magnesium responsive RNA element has the ability to perform transcriptional regulation is still not clearly understood. However, a recent report suggests that there is the possibility for the magnesium responsive RNA element to have the capacity to target the mgtA transcript for degradation by the RNase E. [8] This would only apply under conditions where the cells are grown under high magnesium ion conditions. [8] The other function that has been recently suggested for this specific type of riboswitch is its involvement in the process of mRNA degradation. It has been noted that there again appears to be a magnesium concentration-dependent response. [5] In this case though, this response causes the 5'-UTR region of mgtA to be targeted for degradation. [5]

Also, it is important to note that although the magnesium responsive RNA element appears similar to the M-box riboswitch based on structure and function, they are not the same. The way in which both the M-box riboswitch may appear similar to that of the magnesium responsive RNA element is in the structures of their respective aptamers. [5] The M-box riboswitch has been found to contain a metalloregulatory RNA similar in structure and function to that of the magnesium responsive RNA element. [5] Similarly, this riboswitch also has the ability to become involved in transcriptional and translational regulation. [9] For instance, the version of the M-box riboswitch which is found in the microorganism B. subtilis has the ability to shut off the expression of downstream genes in a magnesium-concentration dependent manner. [5] However, what sets the magnesium responsive RNA element apart from this type of riboswitch is the fact that they display different distribution patterns in relation to the genes that they transcriptionally regulate. [5] As opposed to the mgtA riboswitch class which regulates genes downstream of itself, the M-box riboswitch class is instead located upstream of the genes that it regulates which includes genes that encode magnesium transporters and other various proteins such as a Mycobacterium cell surface protein and cell division proteins. [5]

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">Antisense RNA</span>

Antisense RNA (asRNA), also referred to as antisense transcript, natural antisense transcript (NAT) or antisense oligonucleotide, is a single stranded RNA that is complementary to a protein coding messenger RNA (mRNA) with which it hybridizes, and thereby blocks its translation into protein. asRNAs have been found in both prokaryotes and eukaryotes, and can be classified into short and long non-coding RNAs (ncRNAs). The primary function of asRNA is regulating gene expression. asRNAs may also be produced synthetically and have found wide spread use as research tools for gene knockdown. They may also have therapeutic applications.

<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">FMN riboswitch</span> Highly conserved RNA element

The FMN riboswitch 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. 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. 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. 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. FMN riboswitches also have various magnesium and potassium ions dispersed throughout the nucleotide structure, some of which participate in binding of FMN.

<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">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.

ykkC-yxkD leader

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">YkoK leader</span>

The Ykok leader or M-box is a Mg2+-sensing RNA structure that controls the expression of Magnesium ion transport proteins in bacteria. It is a distinct structure to the Magnesium responsive RNA element.

yybP-ykoY leader

The yybP-ykoY leader RNA element was originally discovered in E. coli during a large scale screen and was named SraF. This family was later found to exist upstream of related families of protein genes in many bacteria, including the yybP and ykoY genes in B. subtilis. The specific functions of these proteins are unknown, but this structured RNA element may be involved in their genetic regulation as a riboswitch. The yybP-ykoY element was later proposed to be manganese-responsive after another associated family of genes, YebN/MntP, was shown to encode Mn2+ efflux pumps in several bacteria. Genetic data and a crystal structure confirmed that yybp-ykoY is a manganese riboswitch that directly binds Mn2+

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

In molecular biology, a riboregulator is a ribonucleic acid (RNA) that responds to a signal nucleic acid molecule by Watson-Crick base pairing. A riboregulator may respond to a signal molecule in any number of manners including, translation of the RNA into a protein, activation of a ribozyme, release of silencing RNA (siRNA), conformational change, and/or binding other nucleic acids. Riboregulators contain two canonical domains, a sensor domain and an effector domain. These domains are also found on riboswitches, but unlike riboswitches, the sensor domain only binds complementary RNA or DNA strands as opposed to small molecules. Because binding is based on base-pairing, a riboregulator can be tailored to differentiate and respond to individual genetic sequences and combinations thereof.

<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">Downstream-peptide motif</span>

The Downstream-peptide motif refers to a conserved RNA structure identified by bioinformatics in the cyanobacterial genera Synechococcus and Prochlorococcus and one phage that infects such bacteria. It was also detected in marine samples of DNA from uncultivated bacteria, which are presumably other species of cyanobacteria.

<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">Pfl RNA motif</span>

The pfl RNA motif refers to a conserved RNA structure present in some bacteria and originally discovered using bioinformatics. pfl RNAs are consistently present in genomic locations that likely correspond to the 5' untranslated regions of protein-coding genes. This arrangement in bacteria is commonly associated with cis-regulatory elements. Moreover, they are in presumed 5' UTRs of multiple non-homologous genes, suggesting that they function only in these locations. Additional evidence of cis-regulatory function came from the observation that predicted rho-independent transcription terminators overlap pfl RNAs. This overlap suggests that the alternate secondary structures of pfl RNA and the transcription terminator stem-loops compete with each other, and this is a common mechanism for cis gene control in bacteria.

<span class="mw-page-title-main">YjdF RNA motif</span> Conserved RNA structure

The yjdF RNA motif is a conserved RNA structure identified using bioinformatics. Most yjdF RNAs are located in bacteria classified within the phylum Bacillota. A yjdF RNA is found in the presumed 5' untranslated region of the yjdF gene in Bacillus subtilis, and almost all yjdF RNAs are found in the 5' UTRs of homologs of this gene. The function of the yjdF gene is unknown, but the protein that it is predicted to encode is classified by the Pfam Database as DUF2992.

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

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.

<span class="mw-page-title-main">Cyclic di-GMP-II riboswitch</span>

Cyclic di-GMP-II riboswitches form a class of riboswitches that specifically bind cyclic di-GMP, a second messenger used in multiple bacterial processes such as virulence, motility and biofilm formation. Cyclic di-GMP II riboswitches are structurally unrelated to cyclic di-GMP-I riboswitches, though they have the same function.

SAM-V riboswitch is the fifth known riboswitch to bind S-adenosyl methionine (SAM). It was first discovered in the marine bacterium Candidatus Pelagibacter ubique and can also be found in marine metagenomes. SAM-V features a similar consensus sequence and secondary structure as the binding site of SAM-II riboswitch, but bioinformatics scans cluster the two aptamers independently. These similar binding pockets suggest that the two riboswitches have undergone convergent evolution.

References

  1. Groisman EA, Cromie MJ, Shi Y, Latifi T (2006). "A Mg2+-responding RNA that controls the expression of a Mg2+ transporter". Cold Spring Harb Symp Quant Biol. 71: 251–258. doi: 10.1101/sqb.2006.71.005 . PMID   17381304.
  2. Spinelli SV, Pontel LB, García Véscovi E, Soncini FC (2008). "Regulation of magnesium homeostasis in Salmonella: Mg(2+) targets the mgtA transcript for degradation by RNase E." FEMS Microbiol Lett. 280 (2): 226–234. doi: 10.1111/j.1574-6968.2008.01065.x . PMID   18248433.
  3. 1 2 3 4 5 6 7 8 Breaker, Ronald R. (2012-02-01). "Riboswitches and the RNA world". Cold Spring Harbor Perspectives in Biology. 4 (2): a003566. doi:10.1101/cshperspect.a003566. ISSN   1943-0264. PMC   3281570 . PMID   21106649.
  4. Groisman, Cromie, Shi, Latifi, EA, MJ, Y, T (2006). "A Mg2+-responding RNA that controls the expression of a Mg2+ transporter". Cold Spring Harbor Symposia on Quantitative Biology. 71: 251–258. doi: 10.1101/sqb.2006.71.005 . PMID   17381304.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  5. 1 2 3 4 5 6 7 8 9 10 11 Ramesh, Arati; Winkler, Wade C. (2010-01-01). "Magnesium-sensing riboswitches in bacteria". RNA Biology. 7 (1): 77–83. doi: 10.4161/rna.7.1.10490 . ISSN   1547-6286. PMID   20023416. S2CID   35406547.
  6. Sarkar, Raju; Jaiswar, Akhilesh; Henelley, Scott P; Onuchic, José N; Sanbonmatsu, Karissa Y; Roy, Susmita (2021-06-24). "Chelated Magnesium Logic Gate Regulates Riboswitch Pseudoknot Formation". The Journal of Physical Chemistry B. 125 (24): 6479–6490. doi:10.1021/acs.jpcb.1c02467. ISSN   1520-6106. PMC   8988897 . PMID   34106719.
  7. McLean, Franklin C. (1938-10-01). "Application of the Law of Chemical Equilibrium (Law of Mass Action) to Biological Problems". Physiological Reviews. 18 (4): 495–523. doi:10.1152/physrev.1938.18.4.495. ISSN   0031-9333.
  8. 1 2 Spinelli, Silvana V.; Pontel, Lucas B.; García Véscovi, Eleonora; Soncini, Fernando C. (2008-03-01). "Regulation of magnesium homeostasis in Salmonella: Mg2+ targets the mgtA transcript for degradation by RNase E". FEMS Microbiology Letters. 280 (2): 226–234. doi: 10.1111/j.1574-6968.2008.01065.x . ISSN   0378-1097. PMID   18248433.
  9. Nudler, Evgeny; Mironov, Alexander S (2004-01-01). "The riboswitch control of bacterial metabolism". Trends in Biochemical Sciences. 29 (1): 11–17. doi:10.1016/j.tibs.2003.11.004. ISSN   0968-0004. PMID   14729327.
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