In order to improve the self-sufficiency of food and renewable energy and make effective use of paddy fields in the future, it is important to make great strides in the multi-use of rice, such as for bioethanol and feed. We have shown that the accumulation and composition of stem non-structural carbohydrates (NSCs) can be genetically modified without affecting the function of the leaf blade or ears (endosperm). In this study, we crossed the existing high-starch feed rice cultivars "Leaf Star" or "Tachisuzuka" with a mutant line of "Nipponbare", which does not accumulate much starch in the stems due to a functional deficiency in OsAGPL1 gene, and then grew their BC1F3 generations in paddy fields to investigate the relationship between the genotype and the stem sugar and starch contents at harvest. The results showed that stem starch content in AGPL1-deficient individuals, regardless of the parental cultivar, was almost zero, and soluble sugars were increased twice as much as in normal and heterozygous individuals, confirming the heritability of the high stem-sugar trait. In addition, the crude fat content was also increased in the stems of AGPL1-deficient individuals.