Mutants of phosphorylase a altered in recognition by protein phosphatase-1.

To develop our knowledge of specificity determinants for protein phosphatase-1, mutants of phosphorylase b have been converted to phosphorylase a and examined for their efficacy as substrates for protein phosphatase-1. Mutants focused on the N-terminal primary sequence surrounding the phosphoserine (R16A, R16E, and I13G) and at a site that interacts with the phosphoserine in phosphorylase a, (R69K and R69E). The success achieved studying protein kinase substrate specificity with peptide substrates has not extended to protein phosphatases. Protein phosphatases are believed to recognize higher order structure in substrates in addition to the primary sequence surrounding the phosphoserine or threonine. Peptide studies with protein phosphatase-1 have revealed a preference for basic residues N-terminal to the phosphoserine. Arginine 16 in phosphorylase a may be a positive determinant. In this work, protein phosphatase-1 preferred the positive charge on arginine 16. R16A exhibited a similar K(m) but reduced V(max), and R16E had an increased K(m) and a decreased V(max) when compared to phosphorylase. I13G had a similar K(m) but an increased V(max). The R69 mutants were also dephosphorylated preferentially over phosphorylase a. The K(m) for R69K was unchanged but had a higher V(max). R69E exhibited the most changes, with a 4-fold increase in K(m) and a 10-fold increase in V(max). These results suggest that proper presentation of the phosphoserine can greatly affect the rate of dephosphorylation.

The amino-terminal tail of glycogen phosphorylase is a switch for controlling phosphorylase conformation, activation, and response to ligands.

Glycogen phosphorylase is a muscle enzyme which metabolizes glycogen, producing glucose-1-phosphate, which can be used for the production of ATP. Phosphorylase activity is regulated by phosphorylation/dephosphorylation, and by the allosteric binding of numerous effectors. In this work, we have studied 10 site-directed mutants of glycogen phosphorylase (GP) in its amino-terminal regulatory region to characterize any changes that the mutations may have made on its structure or function. All of the GP mutants had normal levels of activity in the presence of the allosteric activator AMP. Some of the mutants were observed to have altered AMP-binding characteristics, however. R16A and R16E were activated at very low AMP concentration and crystallized at low temperature, like the phosphorylated form of GP, phosphorylase a, and unlike the dephospho-form, phosphorylase b. This indicates that even without phosphorylation, the structures of these mutants are more like phosphorylase a than phosphorylase b. These mutants were also very poorly phosphorylated in the presence of the inhibitor glucose, while phosphorylase b was phosphorylated normally with this inhibitor present. In contrast to R16A and R16E, four other mutants behaved like phosphorylase b after phosphorylation. R69E was only partially activated by phosphorylation, and I13G, R43E, and R43E/R69E were completely inactive after phosphorylation. We propose a model for the many functions of the amino terminus to explain the many varied effects of these mutations.