The CD4 molecule has an important role in the human immune system and in the pathogenesis of HIV. A key factor in HIV pathogenesis is the use of the CD4 molecule as the primary receptor for cellular infection. In addition to CD4+ T helper cells, there are numerous other cells of the immune system that express CD4 that are susceptible to infection by HIV. One of the primary targets and an important and poorly understood reservoir for HIV in an infected individual are monocytes/macrophages. Other than allowing HIV infection of these cells, the role of the CD4 receptor in the function and development of monocyte/macrophages is not known. We have recently determined that ligation of CD4 on monocytes/macrophages modulates gene and cytokine protein expression as well as T cell responses. We are interested in examining this and other roles and functions of the CD4 molecule on the monocyte/ macrophage cell subset. Our central hypothesis in this proposal is that CD4 has a role in monocyte/ macrophage differentiation and function by modulating the expression of factors that control cellular development and other immune responses. This, in turn, has important implications in HIV infection and the understanding of the monocyte/ macrophage reservoir of infected cells in disease progression. This proposal will focus on addressing these issues and will focus on the following three Specific Aims: 1. To determine the mechanisms regulating CD4 expression during monocyte/macrophage development. 2. To determine the function(s) and consequence(s) of CD4 expression during monocyte/macrophage lineage differentiation and development. 3. To determine the role(s) of the CD4 molecule on mature monocyte/ macrophage function. To achieve this, we will utilize a novel embryonic stem cell-based system that we can genetically manipulate and examine monocyte/ macrophage differentiation and function from a cell type that is among the earliest in human hematopoietic development. In summary, it is anticipated that these studies will shed light on the potential roles and importance of CD4 in monocyte/macrophage development and/or function. Further, it is anticipated that the proposed studies will allow a more comprehensive understanding of the consequences of HIV infection in this cell type.
The experimental approach described in this proposal is designed to address the central hypothesis that the CD4 molecule has a broader function in the immune response, and by extension in HIV pathogenesis, than its capacity on CD4+ T helper cells. These studies will increase our knowledge of how the CD4 molecule influences monocyte/ macrophage development and immune function and how HIV may impact this process;thus, increasing our understanding of the mechanisms of HIV infection and pathogenesis. Further, the use of embryonic stem cells in these studies, due to their high plasticity, self-renewal ability, and ability to be genetically manipulated, may allow the development of immune replacement therapeutic strategies to be developed for HIV and other similar diseases.
| Zhen, Anjie; Carrillo, Mayra A; Kitchen, Scott G (2017) Chimeric antigen receptor engineered stem cells: a novel HIV therapy. Immunotherapy 9:401-410 |
| Zhen, Anjie; Rezek, Valerie; Youn, Cindy et al. (2017) Targeting type I interferon-mediated activation restores immune function in chronic HIV infection. J Clin Invest 127:260-268 |
| Zhen, Anjie; Rezek, Valerie; Youn, Cindy et al. (2016) Stem-cell Based Engineered Immunity Against HIV Infection in the Humanized Mouse Model. J Vis Exp : |
| Zhen, Anjie; Kamata, Masakazu; Rezek, Valerie et al. (2015) HIV-specific Immunity Derived From Chimeric Antigen Receptor-engineered Stem Cells. Mol Ther 23:1358-1367 |
| De Azambuja, Katherine; Barman, Provabati; Toyama, Joy et al. (2014) Validation of an HPV16-mediated carcinogenesis mouse model. In Vivo 28:761-7 |
| Zhen, Anjie; Krutzik, Stephan R; Levin, Bernard R et al. (2014) CD4 ligation on human blood monocytes triggers macrophage differentiation and enhances HIV infection. J Virol 88:9934-46 |
| Zhen, Anjie; Kitchen, Scott (2013) Stem-cell-based gene therapy for HIV infection. Viruses 6:1-12 |
| Kitchen, Scott G; Levin, Bernard R; Bristol, Gregory et al. (2012) In vivo suppression of HIV by antigen specific T cells derived from engineered hematopoietic stem cells. PLoS Pathog 8:e1002649 |
| Kitchen, Scott G; Shimizu, Saki; An, Dong Sung (2011) Stem cell-based anti-HIV gene therapy. Virology 411:260-72 |
| Kitchen, Scott G; Zack, Jerome A (2011) Stem cell-based approaches to treating HIV infection. Curr Opin HIV AIDS 6:68-73 |
