Identification of a neuroregulated phosphoprotein in skeletal muscle as the regulatory subunit of cyclic AMP-dependent protein kinase II.

When soluble proteins in cytosolic fractions of rat soleus muscles are 32P-phosphorylated in vitro by an ATP:protein phosphotransferase reaction, the major substrate is a 56-kilodalton (56K) protein. As we have also reported previously, the onset and development of increased 32P-phosphorylation of this 56K protein, which are observed after the soleus is denervated, temporally correlate with the denervation period and length of the distal nerve stump [Held et al, 1983]. Conclusive evidence which identifies this neuroregulated muscle protein as the regulatory subunit of cyclic AMP-dependent protein kinase type II (R-II) is presented in this paper. The 56K soleus protein and purified bovine heart R-II were 32P-phosphorylated and subjected to limited proteolysis with bovine pancreas trypsin. After resolution of the generated 32P-phosphopeptides by SDS slab PAGE and visualization by autoradiography, no tryptic products were observed from the 56K soleus protein which were not also produced by proteolysis of the purified R-II. These tryptic phosphopeptides included 39, 16.5, and 12K fragments which retained the autophosphorylation site of R-II. After denervation, the 32P-phosphorylation of the 56K soleus protein and of the 39K tryptic peptide product were comparably increased. The identification of the neuroregulated 56K soleus protein as R-II was also confirmed by Western blotting with a specific anti-R-II sera. Taken together, our results demonstrate that the previously observed neuroregulation of the 32P-phosphorylation of the 56K soleus protein is identifiable with some alteration which affects the intramolecular 32P-autophosphorylation of R-II.