Abstract
Membrane integral pyrophosphatases (mPPases) are responsible for the hydrolysis of pyrophosphate. This enzymatic mechanism is coupled to the pumping of H+ or Na+ across membranes in a process that can be K+ dependent or independent. Understanding the movements and dynamics throughout the mPPase catalytic cycle is important, as this knowledge is essential for improving or impeding protein function. mPPases have been shown to play a crucial role in plant maturation and abiotic stress tolerance, and so have the potential to be engineered to improve plant survival, with implications for global food security. mPPases are also selectively toxic drug targets, which could be pharmacologically modulated to reduce the virulence of common human pathogens. The last few years have seen the publication of many new insights into the function and structure of mPPases. In particular, there is a new body of evidence that the catalytic cycle is more complex than originally proposed. There are structural and functional data supporting a mechanism involving half-of-the-sites reactivity, inter-subunit communication, and exit channel motions. A more advanced and in-depth understanding of mPPases has begun to be uncovered, leaving the field of research with multiple interesting avenues for further exploration and investigation.
Highlights
Pyrophosphatases (PPases) are enzymes responsible for the reversible hydrolysis of the phosphoanhydride bond in pyrophosphate (PPi) to two inorganic phosphate molecules (Kajander et al, 2013)
PPases are subcategorized into three separate protein families; Family I, Family II, and membrane-integral pyrophosphatases
A single subunit of both Family I and membrane-integral pyrophosphatases (mPPases) consists of a single domain, while Family II PPases have two domains per subunit. mPPases are the only family that is embedded in the membrane: they have 15-17 transmembrane helices (TMH) per 70-81 kDa subunit (Kellosalo et al, 2012; Lin et al, 2012)
Summary
Pyrophosphatases (PPases) are enzymes responsible for the reversible hydrolysis of the phosphoanhydride bond in pyrophosphate (PPi) to two inorganic phosphate molecules (Kajander et al, 2013). I and II PPases are only responsible for removing excess waste PPi from the cytoplasm, while mPPases are primary ion pumps: they couple hydrolysis to movement of H+ and/or Na+ across a membrane (Kajander et al, 2013) and generate a membrane potential, which contributes to a number of cellular functions, such as acidocalcisome and vacuole regulation and energization (Shah et al, 2016). MPPases promote energy efficiency and survival in numerous human pathogens, making them clinically relevant as potential drug targets (Luoto et al, 2011; Shah et al, 2016) This evolutionarily ancient family evolved through a gene triplication; they consist of three structurally-conserved splayed 4-helix bundles made up of TMH 3-6, 9-12, and 13-16 (Au et al, 2006; Kajander et al, 2013) arranged with ∼3-fold symmetry perpendicular to the membrane plane.
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