Low-barrier hydrogen bond

Description

Standard hydrogen bonds are longer (e.g. 2.8 Å for an O···O h-bond), and the hydrogen ion clearly belongs to one of the heteroatoms. When pKa of the heteroatoms is closely matched, a LBHB becomes possible at a shorter distance (~2.55 Å). When the distance further decreases (

Proteins

Low barrier hydrogen bonds occur in the water-excluding environments of proteins. Multiple residues act together in a charge-relay system to control the pKa values of the residues involved. LBHBs also occur on the surfaces of proteins, but are unstable due to their proximity to bulk water, and the conflicting requirements of strong salt-bridges in protein-protein interfaces.

Enzyme catalysis

Low-barrier hydrogen bonds have been proposed to be relevant to enzyme catalysis in two types of circumstance. Firstly, a low-barrier hydrogen bond in a charge relay network within an active site could activate a catalytic residue (e.g. between acid and base within a catalytic triad). Secondly, an LBHB could form during catalysis to stabilise a transition state (e.g. with substrate transition state in an oxyanion hole). Both of these mechanisms are contentious, with theoretical and experimental evidence split on whether they occur. Since the 2000s, the general consensus has been that LBHBs are not used by enzymes to aid catalysis. However, in 2012, a low-barrier hydrogen bond has been proposed to be involved in phosphate-arsenate discrimination for a phosphate transport protein. This finding might indicate the possibility of low-barrier hydrogen bonds playing a catalytic role in ion size selection for some very rare cases.

References

References

1. (2000-09-26). "Towards an unified hydrogen-bond theory". Journal of Molecular Structure.
2. (2007). "Encircled Proton". [[J. Am. Chem. Soc.]].
3. (October 1998). "On the electronic nature of low-barrier hydrogen bonds in enzymatic reactions". Proc. Natl. Acad. Sci. U.S.A..
4. (2014-02-06). "Proton transfer reactions and hydrogen-bond networks in protein environments". Journal of the Royal Society Interface.
5. (2 October 1998). "The Low Barrier Hydrogen Bond in Enzymatic Catalysis". Journal of Biological Chemistry.
6. (7 November 1997). "A Low-Barrier Hydrogen Bond in the Catalytic Triad of Serine Proteases? Theory Versus Experiment". Science.
7. (1 April 2004). "The low barrier hydrogen bond (LBHB) proposal revisited: The case of the Asp ··· His pair in serine proteases". Proteins: Structure, Function, and Bioinformatics.
8. (August 2006). "Electrostatic Basis for Enzyme Catalysis". Chemical Reviews.
9. (2012-11-01). "The molecular basis of phosphate discrimination in arsenate-rich environments". Nature.