When compared with glycogen phosphorylase, it was found that starch phosphorylase (L-SP) from sweet potato roots has an insertion containing 78 amino acids (L78P) which might involve in the primer-independent (PI) activity of L-SP, since L-SP lost this PI activity totally if the L78P was removed by proteolysis (L-SP*). It was postulated that L-SP might bind with Glc-1-P at Lys residues on its L78P that might play the role of primer in starch synthesis. It was also demonstrated that L78P could control the direction of L-SP catalytic reactions by prtoein degradation. This study explored the structural features of L78P, and examined the possibility of the binding between L-SP and Glc-1-P. Besides, L78P was added to L-SP* for the rescue of its PI activity We found that L78P have four bands on native-PAGE which might be caused by its flexible conformation. From the circular dichroism (CD) spectroscopy analysis, L-SP was identified as random coil. When we added calf intestinal alkaline phosphatase to release the phosphate of Glc-1-P, L-SP and L78P could inhibit the reaction and decrease the phosphate leval. In addtion, Lys could compete with Glc-1-P in binding to L-SP; and the ability of L-SP to synthesize starch would be blocked by Lys. These results showed that L-SP can bind to Glc-1-P at the Lys residues of L78P. We also found that after adding L78P to L-SP*, the phosphate releasing leval increased and the starch synthesis began. In addition, it was found that proteasome (proteasome deletion mutant) could degrade L-SP and L78P; this observation indicated that L-SP activity might be regulated via ubiqutin-proteasome system.