The liver has an enormous capacity to regenerate, as demonstrated by the 2/3 partial hepatectomy model in rodents. In addition, the liver has a stem cell compartment acting as a backup regenerative system. Activation of the stem cell compartment takes place when hepatocytes are functionally compromised, are unable to divide, or both. In stem cell-aided liver regeneration, progeny of the stem cells multiply in an amplification compartment composed of hepatic oval cells. Several studies have shown that bone marrow cells can differentiate into hepatocytes, and we have also shown that bone marrow (BM) cells are able to produce hepatic oval cells. The foremost questions are: what molecular mechanisms are involved in oval cell physiology, and can these pathways be manipulated to enhance their therapeutic value in treating liver disorders? The experiments described within this proposal are designed to address the above stated questions. We will pursue the following specific aims:
Specific Aim 1 : We hypothesize that activation of the JAK2 and MAPK signal transduction pathways by G-CSF interaction with G-CSF receptor on the cell membrane enhances both proliferation and migration of liver oval cells.
Specific aim 2 : We hypothesize that activation of the MEK and PI3K signal transduction pathways following SDF-1 binding to CXCR4 receptor on the cell membrane enhances both proliferation and migration of liver oval cells.
Specific aim 3 : We hypothesize that modulation of the oval cell phenotype by G-CSF and SDF-1 will positively affect engraftment and expansion of compensatory oval cells into rat liver afflicted with a genetic disorder, resulting in a measurable enhancement of liver function. It is anticipated that the proposed studies will yield new and significant data about the mechanisms of governing the bone marrow contribution to liver regeneration and signals involved in oval cell activation, proliferation and differentiation.
The liver has an enormous capacity to regenerate, as demonstrated by the 2/3 partial hepatectomy model in rodents. In addition, the liver has a stem cell compartment acting as a backup regenerative system. Activation of the stem cell compartment takes place when hepatocytes are functionally compromised, are unable to divide, or both. In stem cell-aided liver regeneration, progeny of the stem cells multiply in an amplification compartment composed of hepatic oval cells. Several studies have shown that bone marrow cells can differentiate into hepatocytes, and we have also shown that bone marrow (BM) cells are able to produce hepatic oval cells. The foremost questions are: what molecular mechanisms are involved in oval cell physiology, and can these pathways be manipulated to enhance their therapeutic value in treating liver disorders? The experiments described within this proposal are designed to address the above stated questions. We will pursue the following specific aims:
Specific Aim 1 : We hypothesize that activation of the JAK2 and MAPK signal transduction pathways by G-CSF interaction with G-CSF receptor on the cell membrane enhances both proliferation and migration of liver oval cells.
Specific Aim 2 : We hypothesize that activation of the MEK and PI3K signal transduction pathways following SDF-1 binding to CXCR4 receptor on the cell membrane enhances both proliferation and migration of liver oval cells.
Specific Aim 3 : We hypothesize that modulation of the oval cell phenotype by G-CSF and SDF-1 will positively affect engraftment and expansion of compensatory oval cells into rat liver afflicted with a genetic disorder, resulting in a measurable enhancement of liver function. It is anticipated that the proposed studies will yield new and significant data about the mechanisms of governing the bone marrow contribution to liver regeneration and signals involved in oval cell activation, proliferation and differentiation.
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