Cooperativity in catalysis by canonical family II pyrophosphatases.

Bacterial family II pyrophosphatases (PPases) are homodimeric enzymes, with the active site located between two catalytic domains. Some family II PPases additionally contain regulatory cystathionine ß-synthase (CBS) domains and exhibit positive kinetic cooperativity, which is lost upon CBS domain removal. We report here that CBS domain-deficient family II PPases of Bacillus subtilis and Streptococcus gordonii also exhibit positive kinetic cooperativity, manifested as an up to a five-fold difference in the Michaelis constants for two active sites. An Asn79Ser replacement in S. gordonii PPase preserved its dimeric structure but abolished cooperativity. The results of our study indicated that kinetic cooperativity is an inherent property of all family II PPase types, is not induced by CBS domains, and is sensitive to minor structural changes. These findings may have inferences for other CBS-proteins, which include important enzymes and membrane transporters associated with hereditary diseases.

Roles of nucleotide substructures in the regulation of cystathionine ß-synthase domain-containing pyrophosphatase.

BACKGROUND: Regulatory cystathionine ß-synthase (CBS) domains are ubiquitous in proteins, yet their mechanism of regulation remains largely obscure. Inorganic pyrophosphatase which contains regulatory CBS domains as internal inhibitors (CBS-PPase) is activated by ATP and inhibited by AMP and ADP; nucleotide binding to CBS domains and substrate binding to catalytic domains demonstrate positive co-operativity. METHODS: Here, we explore the ability of an AMP analogue (cAMP) and four compounds that mimic the constituent parts of the AMP molecule (adenine, adenosine, phosphate, and fructose-1-phosphate) to bind and alter the activity of CBS-PPase from the bacterium Desulfitobacterium hafniense. RESULTS: Adenine, adenosine and cAMP activated CBS-PPase several-fold whereas fructose-1-phosphate inhibited it. Adenine and adenosine binding to dimeric CBS-PPase exhibited high positive co-operativity and markedly increased substrate binding co-operativity. Phosphate bound to CBS-PPase competitively with respect to a fluorescent AMP analogue. CONCLUSIONS: Protein interactions with the adenine moiety of AMP induce partial release of the internal inhibition and determine nucleotide-binding co-operativity, whereas interactions with the phosphate group potentiate the internal inhibition and decrease active-site co-operativity. The ribose moiety appears to enhance the activation effect of adenine and suppress its contribution to both types of co-operativity. GENERAL SIGNIFICANCE: Our findings demonstrate for the first time that regulation of a CBS-protein (inhibition or activation) is determined by a balance of its interactions with different chemical groups of the nucleotide and can be reversed by their modification. Differential regulation by nucleotides is not uncommon among CBS-proteins, and our findings may thus have a wider significance.