Fluoride riboswitch explained

crcB RNA motif
Symbol:crcB RNA
Rfam:RF01734
Rna Type:Cis-reg
riboswitch
Tax Domain:Prokaryota

The fluoride riboswitch (formerly called the crcB RNA motif) is a conserved RNA structure identified by bioinformatics in a wide variety of bacteria and archaea.[1] These RNAs were later shown to function as riboswitches that sense fluoride ions.[2] 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.

Many genes are presumed to be regulated by these fluoride riboswitches. Two of the most common encode proteins that are proposed to function by removing fluoride from the cell. These proteins are CrcB proteins and a fluoride-specific subtype of chloride channels referred to as EriCF or ClCF. ClCF proteins have been shown to function as fluoride-specific fluoride/proton antiporters.

The three-dimensional structure of a fluoride riboswitch has been solved at atomic resolution by X-ray crystallography.[3]

Fluoride riboswitches are found in many organisms within the domains bacteria and archaea, indicating that many of these organisms sometimes encounter elevated levels of fluoride. Of particular interest is Streptococcus mutans, a major cause of dental caries. It has been shown that sodium fluoride has inhibited the growth rate of S. mutans using glucose as an energy and carbon source.[4] However, it is also noteworthy that many organisms that do not encounter fluoride in the human mouth carry fluoride riboswitches or resistance genes.

Discovery of the fluoride riboswitch

The identity of fluoride as the riboswitch ligand was accidentally discovered when a compound contaminated with fluoride caused significant conformational changes to the non-coding crcB RNA motif during an in-line probing experiment. In-line probing was used to illuminate the secondary structure of the crcB RNA motif and structural changes associated with possible binding to specific metabolites or ions.[5] The results of the probing showed the addition of increasing fluoride ion concentrations suppressed certain regions of spontaneous RNA cleavage and heightening other regions. These nucleotide regions in the crcB RNA motif play important roles in the aptamer binding region for fluoride.[2]

Upon binding fluoride ions, the fluoride riboswitch showed regulation of downstream gene transcription. These downstream genes transcribe fluoride sensitive enzymes such as enolase, pyrophosphatase, the presumed fluoride exporter CrcB and a superfamily of CLC membrane proteins called EricF proteins.[6] The CLCF proteins have been shown to function as fluoride transporters against fluoride toxicity.[6] The ericF gene is a mutant version of the chloride channel gene that is less common in bacteria than chloride-specific homologs, but is nonetheless found in the genome of Streptococcus mutans.[7] The EricF protein in particular carries specific amino acids in their channels that targets fluoride anions whereas the regular Eric protein favored chloride over fluoride ions.

Fluoride riboswitch structure

The discovery of the fluoride riboswitch was surprising as both fluoride ions and the crcB RNA phosphate groups are negatively charged and should not be able to bind to one another.[2] Previous research came across this question in elucidating the cofactor thiamine pyrophosphate (TPP) riboswitch. The TPP riboswitch structure showed the assistance of two hydrated Mg2+ ions that help stabilize the connection between the phosphates of TPP and guanine bases of the RNA.[8] [9] This guiding research help characterize the fluoride riboswitch's own interactions with fluoride and its structure. Through in-line probing and mutational studies the fluoride riboswitch of the organism Thermotoga petrophila is recognized to have two helical stems adjoined by a helical loop with the capacity to become a pseudoknot.[10] The bound fluoride ligand is found to be located within the center of the riboswitch fold, enclosed by three Mg2+ ions. The Mg2+ ions are octahedrally coordinated with five outer backbone phosphates and water molecules making a metabolite specific pocket for coordinating the fluoride ligand to bind. The placement of the Mg2+ ions positions the fluoride ion into the negatively charged crcB RNA scaffold.[10]

Biological significance

In the Earth's crust, fluoride is the 13th most abundant element.[2] It is commonly used in oral healthcare products and water.[2] The fluoride acts as a hardening agent with the enamel base on teeth, remineralizing and protecting them from harsh acids and bacteria in the oral cavity.[11] Additionally, its significance lies in the effect of the toxicity of fluoride at high concentrations to bacteria, especially those that cause dental caries. It has long been known that many species encapsulate a sensor system for toxic metals such as cadmium and silver.[2] However, a sensor system against fluoride remained unknown. The fluoride riboswitch elucidates the bacterial defense mechanism in counteracting against the toxicity of high concentrations of fluoride by regulating downstream genes of the riboswitch upon binding the fluoride ligand.[2] Further elucidating the mechanism of how bacteria protect themselves from fluoride toxicity can help modify the mechanism to make smaller concentrations of fluoride even more lethal to bacteria. Additionally, the fluoride riboswitch and the downstream regulated genes can be potential targets for drug development in the future. Overall, these advancements will help towards making fluoride and future drugs strong protectors against oral health disease.

Notes and References

  1. Weinberg Z, Wang JX, Bogue J . Comparative genomics reveals 104 candidate structured RNAs from bacteria, archaea and their metagenomes . Genome Biol . 11 . 3 . R31 . March 2010 . 20230605 . 10.1186/gb-2010-11-3-r31 . 2864571. etal . free .
  2. Baker JL, Sudarsan N, Weinberg Z . Widespread genetic switches and toxicity resistance proteins for fluoride . Science . 335 . 6065 . 233–235 . January 2012 . 22194412 . 10.1126/science.1215063 . 4140402. etal.
  3. Ren A, Rajashankar KR, Patel DJ . Fluoride ion encapsulation by Mg2+ ions and phosphates in a fluoride riboswitch . Nature . 486 . 7401 . 85–89 . June 2012 . 22678284 . 10.1038/nature11152 . 3744881.
  4. Yost. K G. VanDemark, P J. Growth inhibition of Streptococcus mutans and Leuconostoc mesenteroides by sodium fluoride and ionic tin. Applied and Environmental Microbiology. May 1978. 35. 5. 920–924. 10.1128/aem.35.5.920-924.1978. 655708. 242953.
  5. Book: Regulski, EE. Breaker RR. In-Line Probing Analysis of Riboswitches . Post-Transcriptional Gene Regulation. 2008. 419. 53–67. 10.1007/978-1-59745-033-1_4. 18369975. Methods in Molecular Biology. 978-1-58829-783-9. registration. https://archive.org/details/posttranscriptio00wilu/page/53.
  6. Stockbridge. RB. Lim HH . Otten R . Williams C . Shane T . Weinberg Z . Miller C . Fluoride resistance and transport by riboswitch-controlled CLC antiporters. Proc Natl Acad Sci U S A. 18 September 2012. 109. 38. 15289–15294. 22949689. 10.1073/pnas.1210896109 . 3458365. free.
  7. Breaker. R.R.. New Insight on the Response of Bacteria to Fluoride. Caries Research. 10 February 2012. 46. 1. 78–81. 10.1159/000336397. 22327376. 3331882.
  8. Serganov. A. Polonskaia A . Phan AT . Breaker RR . Patel DJ . Structural basis for gene regulation by a thiamine pyrophosphate-sensing riboswitch. Nature. 29 June 2006. 441. 7097. 1167–1171. 16728979. 10.1038/nature04740. 4689313.
  9. Thore. S. Leibundgut M . Ban N . Structure of the eukaryotic thiamine pyrophosphate riboswitch with its regulatory ligand. Science. 26 May 2006. 312. 5777. 1208–1211. 16675665. 10.1126/science.1128451. 32389251. free.
  10. Ren. A. Rajashankar KR . Patel DJ . Fluoride ion encapsulation by Mg2+ ions and phosphates in a fluoride riboswitch. Nature. 13 May 2012. 486. 7401. 85–89. 22678284. 10.1038/nature11152. 3744881.
  11. Wolfgang. Arnold. Andreas Dorow . Stephanie Langenhorst . Zeno Gintner . Jolan Banoczy . Peter Gaengler . Effect of fluoride toothpastes on enamel demineralization. BMC Oral Health. 15 June 2006. 6. 8. 8. 10.1186/1472-6831-6-8. 16776820 . 1543617 . free .