Angiotensin II Regulation of Proliferation, Differentiation, and Engraftment of Hematopoietic Stem Cells.

Emerging evidence indicates that differentiation and mobilization of hematopoietic cell are critical in the development and establishment of hypertension and hypertension-linked vascular pathophysiology. This, coupled with the intimate involvement of the hyperactive renin-angiotensin system in hypertension, led us to investigate the hypothesis that chronic angiotensin II (Ang II) infusion affects hematopoietic stem cell (HSC) regulation at the level of the bone marrow. Ang II infusion resulted in increases in hematopoietic stem/progenitor cells (83%) and long-term HSC (207%) in the bone marrow. Interestingly, increases of HSCs and long-term HSCs were more pronounced in the spleen (228% and 1117%, respectively). Furthermore, we observed higher expression of C-C chemokine receptor type 2 in these HSCs, indicating there was increased myeloid differentiation in Ang II-infused mice. This was associated with accumulation of C-C chemokine receptor type 2(+) proinflammatory monocytes in the spleen. In contrast, decreased engraftment efficiency of GFP(+) HSC was observed after Ang II infusion. Time-lapse in vivo imaging and in vitro Ang II pretreatment demonstrated that Ang II induces untimely proliferation and differentiation of the donor HSC resulting in diminished HSC engraftment and bone marrow reconstitution. We conclude that (1) chronic Ang II infusion regulates HSC proliferation, mediated by angiotensin receptor type 1a, (2) Ang II accelerates HSC to myeloid differentiation resulting in accumulation of C-C chemokine receptor type 2(+) HSCs and inflammatory monocytes in the spleen, and (3) Ang II impairs homing and reconstitution potentials of the donor HSCs. These observations highlight the important regulatory roles of Ang II on HSC proliferation, differentiation, and engraftment.

Involvement of bone marrow cells and neuroinflammation in hypertension.

RATIONALE: Microglial activation in autonomic brain regions is a hallmark of neuroinflammation in neurogenic hypertension. Despite evidence that an impaired sympathetic nerve activity supplying the bone marrow (BM) increases inflammatory cells and decreases angiogenic cells, little is known about the reciprocal impact of BM-derived inflammatory cells on neuroinflammation in hypertension. OBJECTIVE: To test the hypothesis that proinflammatory BM cells from hypertensive animals contribute to neuroinflammation and hypertension via a brain-BM interaction. METHODS AND RESULTS: After BM ablation in spontaneously hypertensive rats, and reconstitution with normotensive Wistar Kyoto rat BM, the resultant chimeric spontaneously hypertensive rats displayed significant reduction in mean arterial pressure associated with attenuation of both central and peripheral inflammation. In contrast, an elevated mean arterial pressure along with increased central and peripheral inflammation was observed in chimeric Wistar-Kyoto rats reconstituted with spontaneously hypertensive rat BM. Oral treatment with minocycline, an inhibitor of microglial activation, attenuated hypertension in both the spontaneously hypertensive rats and the chronic angiotensin II-infused rats. This was accompanied by decreased sympathetic drive and inflammation. Furthermore, in chronic angiotensin II-infused rats, minocycline prevented extravasation of BM-derived cells to the hypothalamic paraventricular nucleus, presumably via a mechanism of decreased C-C chemokine ligand 2 levels in the cerebrospinal fluid. CONCLUSIONS: The BM contributes to hypertension by increasing peripheral inflammatory cells and their extravasation into the brain. Minocycline is an effective therapy to modify neurogenic components of hypertension. These observations support the hypothesis that BM-derived cells are involved in neuroinflammation, and targeting them may be an innovative strategy for neurogenic resistant hypertension therapy.

Comparison of the transduction efficiency of tyrosine-mutant adeno-associated virus serotype vectors in kidney.

Gene therapy has a distinct potential to treat kidney diseases. However, the efficient transduction of a significant number of renal cells by viral vectors has been difficult to accomplish. Previous studies indicate that adeno-associated virus (AAV) can transduce renal cells with variable and suboptimal efficiency. Because new and innovative mutants of AAV are now available, we compared their efficacy in transducing rat kidneys. We compared five types of AAV mutants (AAV2 mut-triple, AAV2 sextuple, AAV8 mut447, AAV8 mut733 and AAV9 mut446) carrying a green fluorescence protein (GFP) reporter gene. A pressure microinjection technique was used to inject either 1.5 × 10(11) vector genome (vg) AAV mutants or three dose of AAV2 sextuple into the renal cortex of rats. The microinjection approach has not been used in AAV-mediated renal gene transfer thus far. Slow and sustained microinjection enables continuous administration of the viral vector to the kidney cortex and limits any damage to the kidney, because the tip of a glass micropipette is very small. Three weeks after injection, the kidneys were collected and evaluated for GFP expression. Among the various mutated AAV serotypes studied, only AAV2 sextuple showed robust GFP expression in renal tissue. The AAV2 sextuple serotype appears to be an efficient gene transfer vector to preferentially target renal tubular epithelial cells. A combination of the AAV2 sextuple and the microinjection technique holds the key to the future of therapeutic treatments for kidney diseases.