Amylomaltase (EC 2.4.1.25, AMase) is a transferase, which can transfer α-1,4-linked glucosyl units from one glucan to another. Properties and applications of starch influenced by its structure, which changed by AMase. This study was to explore the relationship between molecular structure and physicochemical properties of starches using AMase. AMase from Thermus thermophilus (T. thermophilus) was overexpressed by E. coli BL21 (DE3) constructed in pET-20b(+). High purity of AMase was prepared after heating at 70oC for 30 min for starch and enzyme industry. For the academic research on the action mode of enzyme, AMase could be further purified by nickel affinity column chromatography with higher purity. 1% (w/w) of cassava starch was modified with AMase at different enzyme/substrate ratios (E/S) and reaction times to explore the structural changes and the retrogradation properties. The amylomaltase-treated starches (ATS) were produced with different molecular weight and chain length distribution, and their effects on the retrogradation property and frezze-thaw stability were studied. ATS showed an increase in weight-average molecular weight (Mw) at a short reaction time, and the action mode of AMase revealed two trends dependent on E/S. At high E/S (≥ 2 U/g), Mw increased initially and then decreased with time. At low E/S (≤ 1 U/g), Mw increased slightly with time. Amylose was hydrolyzed, its content and degree of polymerization (DP) were reduced, and the hydrolyzed segments were transferred to amylopectin, thereby extending the chain length by AMase reaction. Some DP 9–25 amylopectin chains were elongated to DP > 25, resulting in the increase in DP 26–75 at high E/S and in DP 35–55 at low E/S; the short chains (A or B1 chains) of amylopectin were extended to long chains (B2, B3, and B4 chains). The maximum absorption wavelength (λmax) of starch-iodine complex was shifted to shorter wavelength indicating that more iodine reacted with longer amylopectin chains due to the reduction of amylose and extending of amylopectin chains. More iodine molecules were complxed with amylopectin chains. AMase treatment resulted in a severe long-term retrogradation at high E/S along with long reaction time. After AMase treatment, the syneresis after freeze-thaw stability were reduced indicating the higher frozen stability. Low amylose content showed better stability; however, the reduction of molecular weight made the stability worse. The long-to-short chain ratio in amylopectin (L/S), a parameter of molecular structure, was positively correlated with long-term retrogradation. (E/S)2t was also proposed as a parameter to determine whether the domination of AMase action mode was disproportionation or hydrolysis, with a critical value of 49.2. The desired molecular weight of end products could be predicted and manipulated by E/S and reaction time. For industrial utility, the starch with higher molecular weight and better freeze-thaw stability were treated at 10 U/g for 10 min. Overall, A new insight into the structural characteristics and physicochemical properties of ATS was revealed through L/S, E/S, and reaction time, as well as an understanding of the action mode of AMase.