Relativistic effect behind the molybdenum vs. tungsten selectivity in enzymes

Abstract

Molybdenum and tungsten, being congeners of the 6^th group of d-block elements, are similar in many respects in terms of their properties. In fact, both participate in similar types of oxotransferase activity in their enzymes. Molybdenum is regarded as the heaviest essential trace metal in all forms of life; however, its next heavier congener, tungsten, as the heaviest metal, is found only in some prokaryotic organisms. Tungstoenzymes are generally selected by nature for carrying out low-potential redox activities under anaerobic conditions in prokaryotic organisms. This nature's molybdenum vs. tungsten selectivity for their biological functions under different working conditions (surrounding temperature and aerobic/anaerobic environment) is determined mainly by the relativistic effect, which is experienced to different extents by these two congeners. Understanding the mechanistic aspects of the relativistic effect-controlled enzymatic activities of tungstoenzymes is of immense biotechnological interest to develop eco-friendly and cost-effective methods for the commercial synthesis of acetaldehyde through the hydration of acetylene and commercial production of hydrogen (H₂, a green fuel) by producing tungsten-incorporated nitrogenase (W–N₂-ase) in CA6 (mutant strain) and to develop a biomimetic method to replace the hazardous Birch reduction in organic synthesis.