Riboswitch: Difference between revisions

Revision as of 12:52, 17 August 2016

Function

Normally, a variety of proteins and protein cofactors control gene expression in an organism by binding to different sites on messenger RNA (mRNA). Riboswitches are genetic regulatory elements that are built directly into the RNA. They are a type of noncoding RNA that regulate gene expression in the absence of proteins by switching from one structural conformation (shape) to another in response to ligand binding. Most contain a single binding site that recognizes a specific ligand. The ability of a riboswitch to discriminate against molecules that are similar or closely related to its ligand is essential to prevent metabolic misregulation^[1].

The various classes of riboswitches discovered so far are differentiated by their respective ligands. Every class of riboswitch is characterized by an aptamer (binding site) domain, which provides the site for ligand binding, and an expression platform that undergoes conformational change. The sequences and structures of aptamer domains are highly conserved, and therefore exhibit little variation among riboswitches belonging to the same class.

For details on guanine riboswitch see

Structural highlights

Atomic-resolution structures of riboswitch binding sites show that they make numerous hydrogen bonds with their ligands, forming contacts that stabilize RNA interactions to further increase affinity. Some binding sites form pockets that entirely engulf the ligand, and in these instances an induced-fit mechanism of binding must occur. The riboswitch-adenine complex shows the stacking interactions of the zippered-up junctional bubble which is formed by the adenine^[2].

3D structures of riboswitch3D structures of riboswitch

Updated on 17-August-2016

Adenine riboswitch
- 1y26, 4tzx, 4tzy, 4xnr – AR + adenine – Vibrio vulnificus
- 3ivn – BsAR (mutant) – Bacillus subtilis
- 3la5 - BsAR (mutant) + azacytosine
Guanine riboswitch
- 1y27 – BsGR residues 185-252 + guanine
- 2g9c, 3fo4, 3fo6, 3ges, 3gog, 3rkf - BsGR (mutant) + guanine derivative
- 3got - BsGR (mutant) + adenine derivative
- 2xo1 - BsGR aptamer domain + adenine derivative
- 3g4m, 3ger - BsGR + guanine derivative
- 2xnz - BsGR aptamer domain + guanine derivative
- 2xo0 - BsGR aptamer domain + triazine derivative
- 2ees, 2eet, 2eeu, 2eev, 2eew - BsGR (mutant) + hypoxanthine
- 3gao - BsGR + xanthine
- 2xnw – BsGR + Mn
- 4fe5, 4fej, 4fel, 4fen, 4feo, 4fep – GR + hypoxanthine – synthetic
Thiamine pyrophosphate riboswitch
- 2gdi – TPPR + TPP – synthetic
- 2hoj, 2hok, 2hol – EcTPPR + TPP + metal ion – Escherichia coli
- 2hom – EcTPPR + TMP
- 2hoo, 2hop – EcTPPR + TPP analog
- 4nya, 4nyb, 4nyc – EcTPPR + pyrimidine derivative
- 4nyd – EcTPPR + hypoxanthine
- 4nyg – EcTPPR + thyamine
- 3d2g, 3d2v, 3d2x - TPPR + TPP analog – Arabidopsis thaliana
S-adenosylmethionine riboswitch
- 2gis, 4aob, 4b5r – TtSAMR + SAM – Thermoanaerobacter tengcongensis
- 3iqr, 2ydh, 2ygh - TtSAMR (mutant) + SAM
- 3iqp - TtSAMR
- 2qwy, 3e5c, 3e5e, 3e5f, 3iqn - SAMR + SAM – synthetic
- 4kqy – BsSAMR + SAM
- 4oqu - SAMR + SAM - synthetic
S-adenosylhomocysteine riboswitch
- 3npn, 3npq – SAHR + SAH – Ralstonia solanacearum
Lysine riboswitch
- 3d0u – TmKR ligand-binding domain + Lysine – Thermotoga maritima
- 4erj – TmKR + aminocaproic acid
- 4erl – TmKR + Lys + Gly
FMN riboswitch
- 3f2q, 3f2t, 3f2w, 3f2x, 3f2y, 3f30, 3f4e – FnFMNR + FMN – Fusobacterium nucleatum
- 2yie - FnFMNR aptamer domain + FMN
- 3f4g, 3f4h – FnFMNR + flavin derivative
- 2yif - FnFMNR + GTP
Pre-queosine riboswitch
- 3fu2, 3k1v – BsQ1R + queosine
- 3gca – TtQ0R + queosine
- 3q50, 3q51 – TtQ1R aptamer domain + queosine
- 4jf2 – Q1R + GTP + deaza-aminomethyl guanine – Lactobacillus rhamnosus
C-di-GMP riboswitch
- 3irw, 3mxh – VcGMPR + C-di-GMP + GTP + U1 small nuclear ribonucleoprotein – Vibrio cholerae
- 3iwn – VcGMPR + C-di-GMP + U1 small nuclear ribonucleoprotein
- 3mum, 3mur, 3mut - VcGMPR (mutant) + C-di-GMP + U1 small nuclear ribonucleoprotein
- 3muv - VcGMPR (mutant) + C-di-AMP + U1 small nuclear ribonucleoprotein
- 3q3z - GMPR + C-di-GMP – Clostridium acetobutylicum
- 4qk8, 4qka – GMPR + GTP – Thermoanaerobacter pseudethanolicus
- 4qk9 – GMPR + guanosine derivative – Thermovirga lienii
Glycine riboswitch
- 3owi, 3oww, 3owz – VcGlyR + glycine
- 3ox0, 3oxe, 3oxj, 3oxm – VcGlyR + GDP + cytidine cyclic phosphate
- 3oxb, 3oxd – VcGlyR (mutant) + GDP + cytidine cyclic phosphate
- 3p49 – FnGlyR + U1 small nuclear ribonucleoprotein + glycine
M-Box riboswitch
- 3pdr – BsMBR + Mn
T-Box riboswitch
- 4lck – sTBR + tRNA-Gly + ribosomal protein YBXF – synthetic
- 4mgn – sTBR + tRNA-Gly
Tetrahydrofolate riboswitch
- 3suh, 3sux – EsTHFR + THF derivative – Eubacterium siraeum
- 3suy - EsTHFR + cytidine cyclic phosphate
- 3sd1, 4lvv, 4lvx, 4lvw, 4lvy, 4lvz, 4lw0 – THFR + purine derivative – synthetic
- 3sd3 – THFR (mutant) + pteridine derivative – synthetic
Fluoride riboswitch
- 3vrs – TpR + Mn + K + F – Thermotoga petrophila
- 4en5 – TpR + Mg + Tl + F
- 4enc – TpR + Mg + K + F
- 4ena – TpR + Mg + Cs + GTP + F
- 4enb – TpR + Mg + Ir + K + GTP + F
Cobalamine riboswitch
- 4frg, 4frn, 4gma, 4gxy – CoR + aptamer domain – Marine metagenome
yybp-ykoy riboswitch
- 4y1i – LlYYR + Mn – Lactobacillus lactis
- 4y1j – LlYYR (mutant) + Mn
- 4y1m – EcYYR

ReferencesReferences

↑ Breaker, Ronald R. (28 March, 2008). Complex Riboswitches. Science, 319(5871), 1795-1797. doi:10.1126/science.1152621
↑ Serganov A, Yuan YR, Pikovskaya O, Polonskaia A, Malinina L, Phan AT, Hobartner C, Micura R, Breaker RR, Patel DJ. Structural basis for discriminative regulation of gene expression by adenine- and guanine-sensing mRNAs. Chem Biol. 2004 Dec;11(12):1729-41. PMID:15610857 doi:S1074-5521(04)00343-6

Proteopedia Page Contributors and Editors (what is this?)Proteopedia Page Contributors and Editors (what is this?)

Michal Harel, Alexander Berchansky, Joel L. Sussman, Karsten Theis

[scimag-1] Breaker, Ronald R. (28 March, 2008). Complex Riboswitches. Science, 319(5871), 1795-1797. doi:10.1126/science.1152621

[2] Serganov A, Yuan YR, Pikovskaya O, Polonskaia A, Malinina L, Phan AT, Hobartner C, Micura R, Breaker RR, Patel DJ. Structural basis for discriminative regulation of gene expression by adenine- and guanine-sensing mRNAs. Chem Biol. 2004 Dec;11(12):1729-41. PMID:15610857 doi:S1074-5521(04)00343-6

[1]

[2]

@@ Line 1: / Line 1: @@
-<StructureSection load='1y26' size='350' side='right' scene='' caption='Adenine riboswitch complex with adenine and Mg+2 ions, [[1y26]]'>
+<StructureSection load='1y26' size='350' side='right' scene='47/479252/Cv/1' caption='Adenine riboswitch complex with adenine and Mg+2 ions, [[1y26]]'>
 == Function ==
 Normally, a variety of proteins and protein cofactors control gene expression in an organism by binding to different sites on messenger RNA (mRNA). '''Riboswitches''' are genetic regulatory elements that are built directly into the RNA. They are a type of noncoding RNA that regulate gene expression in the absence of proteins by switching from one structural conformation (shape) to another in response to ligand binding.  Most contain a single binding site that recognizes a specific ligand. The ability of a riboswitch to discriminate against molecules that are similar or closely related to its ligand is essential to prevent metabolic misregulation<ref name=scimag>Breaker, Ronald R. (28 March, 2008). Complex Riboswitches. ''Science'', 319(5871), 1795-1797. doi:[http://dx.doi.org/10.1126/science.1152621 10.1126/science.1152621]</ref>.