Starch phosphorylase (L-SP) and D-enzyme are two important enzymes in starch metabolism. Several groups showed that L-SP is involved in starch biosynthesis (Tickle et al., 2009). L-SP can be phosphorylated, and the phosphorylated L-SP may form protein complexes with SBEI and SBEIIb which then affect the biosynthesis of starch (Tetlow et al., 2004b). On the other hand, it is believed that D-enzyme is mainly participated in starch degradation (Zeeman et al., 2010). Besides, it was found that D-enzyme (malQ) and 1, 4-alpha-D-glucan phosphorylase (malP) are encoded by the genes of the same operon in E. coli (Goda et al., 1997), suggesting that D-enzyme and SP may work together. During the purification process of L-SP, Chang (1999) found a high-molecular weight band (HX) showing L-SP activity. Subsequently, Lin also found that D-enzyme showed an extra form of catalytic activity having high molecular weight during its purification. The interaction of D-enzyme and L-SP was confirmed by co-immunoprecipitation (Lin, unpublished observation). In this study, GST pull-down assay and Far Western were utilized to confirm the protein-protein interaction between L-SP and D-enzyme. It was found that HX may be composed of four L-SP and four D-enzyme subunits, and the molecular weight of HX was estimated as 686 kDa by gel filtration and native/SDS 2D-PAGE. In addition, we checked the effect of phosphorylation/dephosphorylation on the formation of HX, and found that post-translational phosphorylation may promote the interaction of L-SP and D-enzyme. Moreover, high molecular weight form (HX) of D-enzyme demonstrated an enhanced catalytic activity, and showed wider range for various substrates. Therefore, in the protein complex (HX), D-enzyme might play the role in producing the malto-oligosaccharides which were then acted by L-SP via phosphorolysis. Furthermore, the protein level of L-SP increased when sweet potato roots accumulating starch, but decreased when sweet potato roots sprouted. This result showed that L-SP might be closely related to starch biosynthesis. However, the enzyme activity and protein expression of D-enzyme increased when sweet potato roots was about to sprout, indicating that D-enzyme might be mainly involved in starch degradation. Interestingly, the protein level of HX increased at two physiological stages: firstly, when the starch synthesis was active; and secondly, after sweet potato roots were germinated. These results suggested that the formation of HX might go through post-translational modification, which may then facilitate the starch metabolism by recycling the available glucans.