Human immune system (HIS) mice, generated by transplanting human hematopoietic stem cells to immunodeficient mice, are a powerful tool to study human immune functions in vivo. However, how to generate HIS mice containing functional adaptive immunity remains challenges. It is well known that cytokines play a critical role in directing immune cell development and functions. The defect in adaptive immunity in current HIS mice may be due to the limited cross-reactivity between mouse cytokines and human receptors. Another potential cause of T cell impairment in HIS mice is that human T cells are educated by mouse major histocompatibility complex (MHC) in the thymus of HIS mice, which may result in their T cell receptors not being able to recognize human antigen-presenting cells that express human leukocyte antigen (HLA). We hypothesized that by providing HIS mice with a combination of human cytokines that are important for T and B cell development and human HLA molecules, we may be able to generate HIS mice with improved adaptive immunity. In the first part of this study, we established protocols to successfully isolate CD34+ hematopoietic stem cells from the umbilical cord blood. Transplantation of these hematopoietic stem cells into irradiated young adult or neonatal immunodeficient NOD.Cg‑Prkdcscid Il2rgtm1Wjl （NSG）mice led to significant amounts of human CD45+ leukocyte cells in the blood and the percentage of these human cells increased with time. Mature human CD4+ T cells and CD8+ T cells were also found in the spleen, liver, bone marrow and thymus. However, these HIS mice became ill and died within two months after transplantation. The cause of death was likely due to radiation which resulted in extremely low levels of red blood cells and platelets in these mice. Because radiation pretreatment will shorten mice lifespan, which is unfavorable for long term experiment observation. Therefore, we adopted a protocol which used neonatal mice without radiation pretreatment for generating HIS mice. This HIS neonatal mice were successfully generated and we took it as our modal for investigate human adaptive immune system in the later experiment. To improve the adaptive immunity in HIS mice, we used adeno-associated viral (AAV) vectors to deliver human cytokines (GM-CSF, IL-7, BLyS, and IL-4) and both class I and class II HLA molecules. In vitro and in vivo assays demonstrated that these AAV vectors were able to express their corresponding cytokines and HLA proteins. Since expression of HLA within the thymus is essential for human T cells to be properly educated, the AAV/HLA vectors were directly injected into the thymus. AAV vectors that express cytokines were intraperitoneally injected which allows cytokine expression systemically. We compared the percentage of human CD45+ cells and the total human immunoglobulin levels in the blood of the HIS mice with and without transduction of AAV vectors expressing cytokines and HLAs. So far, three experiments have been performed with inconsistent results. In two experiment, AAV-cytokine and HLA transduced HIS mice showed much higher percentage of human CD45+ cells as compared with HIS mice without AAV transduction. Analysis of serum immunoglobulin levels also showed high titers of human IgG levels in one experiment, while no human immunoglobulins can be detected in HIS mice without AAV transduction. Unfortunately, these results can not be reproduced in another experiment. We are currently clarifying the possible causes of these inconsistent results and will continue to work on generating HIS mice with an improved adaptive immunity.