Abstract Disclosure: H. Kojima: None. M. Katagi: None. J. Okano: None. T. Nakagawa: None. Diabetes is based on chronic inflammation and cannot be cured using only drugs that lower blood glucose levels. A culprit was lurking there that was hindering healing. We discovered abnormal hematopoietic stem cells that caused persistent chronic inflammation in the bone marrow of diabetic model animals. The real culprit is born after several days of hyperglycemia, never dies, and each time glycemic control deteriorates, it moves its progeny in large numbers throughout the body, fusing with unique cells in various organs and producing TNF-α from the organ cells. We have named these worst stem cells, which resemble cancer stem cells, "diabetes stem cells," and attempted to induce complete remission in diabetic model animals by eliminating them with drugs. In this study, we used streptozotocin (STZ)-induced insulin-deficient diabetes model mice. "Diabetes stem cells" were included in the CD106-positive short-term hematopoietic stem cell fraction, in which progenitor cells that play an important role in the regeneration of the thymus and peripheral tissues, and were characterized by abnormal expression of proinsulin and TNF-α. Furthermore, like cancer cells, the expression of histone deacetylases (HDACs) increased, and once the cells were born, they would not disappear. Therefore, we aimed to eliminate diabetes by administering an HDAC inhibitor and subcutaneously injecting insulin pellets to temporarily correct blood glucose levels. We treated diabetic mice with HDAC inhibitor for 8 weeks, along with several weeks of insulin therapy. Insulin aims to prevent the formation of new abnormal cells in the bone marrow and to prevent the inhibition of pancreatic islet wasting due to the forced insulin secretion caused by hyperglycemia. The combination therapy allowed the beta cells to regenerate and produce enough insulin to normalize blood glucose levels and maintain them even after treatment was discontinued. It also solved the mystery of how the abnormal cell population evades attacks from the T cells. In STZ diabetes, the supply of normal CD106-positive progenitor cells from the bone marrow for thymic regeneration was completely blocked, resulting in marked thymic atrophy. As a result, the thymus, which had lost its progenitor cells, was unable to establish an immune surveillance system to eliminate mutated cells throughout the body. In other words, the combination therapy completely broke the vicious cycle caused by atrophies in both the islet and the thymus. Moreover, when the thymus was surgically removed along with the adventitia to prevent regeneration, diabetes remission was completely inhibited, supporting the importance of thymic normalization. Diabetes is a hematopoietic stem cell disease accompanied by thymic dysfunction, and the removal of "diabetes stem cells" paves the way for the cure of diabetes. Presentation: 6/2/2024
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