Pharmacological tools to mobilise mesenchymal stromal cells into the blood promote bone formation after surgery.

Therapeutic approaches requiring the intravenous injection of autologous or allogeneic mesenchymal stromal cells (MSCs) are currently being evaluated for treatment of a range of diseases, including orthopaedic injuries. An alternative approach would be to mobilise endogenous MSCs into the blood, thereby reducing costs and obviating regulatory and technical hurdles associated with development of cell therapies. However, pharmacological tools for MSC mobilisation are currently lacking. Here we show that ß3 adrenergic agonists (ß3AR) in combination with a CXCR4 antagonist, AMD3100/Plerixafor, can mobilise MSCs into the blood in mice and rats. Mechanistically we show that reversal of the CXCL12 gradient across the bone marrow endothelium and local generation of endocannabinoids may both play a role in this process. Using a spine fusion model we provide evidence that this pharmacological strategy for MSC mobilisation enhances bone formation.

Pericytes, mesenchymal stem cells and their contributions to tissue repair.

Regenerative medicine using mesenchymal stem cells for the purposes of tissue repair has garnered considerable public attention due to the potential of returning tissues and organs to a normal, healthy state after injury or damage has occurred. To achieve this, progenitor cells such as pericytes and bone marrow-derived mesenchymal stem cells can be delivered exogenously, mobilised and recruited from within the body or transplanted in the form organs and tissues grown in the laboratory from stem cells. In this review, we summarise the recent evidence supporting the use of endogenously mobilised stem cell populations to enhance tissue repair along with the use of mesenchymal stem cells and pericytes in the development of engineered tissues. Finally, we conclude with an overview of currently available therapeutic options to manipulate endogenous stem cells to promote tissue repair.

A methodological approach to tracing cell lineage in human epithelial tissues.

Methods for lineage tracing of stem cell progeny in human tissues are currently not available. We describe a technique for detecting the expansion of a single cell's progeny that contain clonal mitochondrial DNA (mtDNA) mutations affecting the expression of mtDNA-encoded cytochrome c oxidase (COX). Because such mutations take up to 40 years to become phenotypically apparent, we believe these clonal patches originate in stem cells. Dual-color enzyme histochemistry was used to identify COX-deficient cells, and mutations were confirmed by microdissection of single cells with polymerase chain reaction sequencing of the entire mtDNA genome. These techniques have been applied to human intestine, liver, pancreas, and skin. Our results suggest that the stem cell niche is located at the base of colonic crypts and above the Paneth cell region in the small intestine, in accord with dynamic cell kinetic studies in animals. In the pancreas, exocrine tissue progenitors appeared to be located in or close to interlobular ducts, and, in the liver, we propose that stem cells are located in the periportal region. In the skin, the origin of a basal cell carcinoma appeared to be from the outer root sheath of the hair follicle. We propose that this is a general method for detecting clonal cell populations from which the location of the niche can be inferred, also affording the generation of cell fate maps, all in human tissues. In addition, the technique allows analysis of the origin of human tumors from specific tissue sites.

Tracking the cell hierarchy in the human intestine using biochemical signatures derived by mid-infrared microspectroscopy.

Markers of gastrointestinal (GI) stem cells remain elusive. We employed synchrotron Fourier-transform infrared (FTIR) microspectroscopy to derive mid-infrared (IR) spectra along the length of human GI crypts. Tissue sections (10-µm thick) were floated onto BaF2 windows and image maps were acquired of small intestine and large bowel crypts in transmission mode with an aperture of ≤10 µm×10 µm. Counting upwards in a step-size (≤10 µm) fashion from the crypt base, IR spectra were extracted from the image maps and each spectrum corresponding to a particular location was identified. Spectra were analyzed using principal component analysis plus linear discriminant analysis. Compared to putative crypt base columnar/Paneth cells, those assigned as label-retaining cells were chemically more similar to putative large bowel stem cells and, the small intestine transit-amplifying cells were closest to large bowel transit-amplifying cells; interestingly, the base of small intestine crypts was the most chemically-distinct. This study suggests that in the complex cell lineage of human GI crypts, chemical similarities as revealed by FTIR microspectroscopy between regions putatively assigned as stem cell, transit-amplifying and terminally-differentiated facilitates identification of cell function.

Locating the stem cell niche and tracing hepatocyte lineages in human liver.

UNLABELLED: We have used immunohistochemical and histochemical techniques to identify patches of hepatocytes deficient in the enzyme cytochrome c oxidase, a component of the electron transport chain and encoded by mitochondrial DNA (mtDNA). These patches invariably abutted the portal tracts and expanded laterally as they spread toward the hepatic veins. Here we investigate, using mtDNA mutations as a marker of clonal expansion, the clonality of these patches. Negative hepatocytes were laser-capture microdissected and mutations identified by polymerase chain reaction sequencing of the entire mtDNA genome. Patches of cytochrome c oxidase-deficient hepatocytes were clonal, suggesting an origin from a long-lived cell, presumably a stem cell. Immunohistochemical analysis of function and proliferation suggested that these mutations in cytochrome c oxidase-deficient hepatocytes were nonpathogenic. CONCLUSION: These data show, for the first time, that clonal proliferative units exist in the human liver, an origin from a periportal niche is most likely, and that the trajectory of the units is compatible with a migration of cells from the periportal regions to the hepatic veins.

Fourier transform infrared microspectroscopy identifies symmetric PO(2)(-) modifications as a marker of the putative stem cell region of human intestinal crypts.

Complex biomolecules absorb in the mid-infrared (lambda = 2-20 microm), giving vibrational spectra associated with structure and function. We used Fourier transform infrared (FTIR) microspectroscopy to "fingerprint" locations along the length of human small and large intestinal crypts. Paraffin-embedded slices of normal human gut were sectioned (10 microm thick) and mounted to facilitate infrared (IR) spectral analyses. IR spectra were collected using globar (15 microm x 15 microm aperture) FTIR microspectroscopy in reflection mode, synchrotron (

Cellular pathways to beta-cell replacement.

In the twenty-first century, diabetic patients are likely to be one of the major beneficiaries from the advancement of regenerative medicine through cellular therapies. Though the existence of a specific self-renewing stem cell within the pancreas is still far from clear, a surprising variety of cells within the pancreas can differentiate towards a beta-cell phenotype: ductular cells, periductular mesenchymal cells and beta-cells themselves can all give rise to new beta-cells. Extra-pancreatic adult somatic stem cells, in particular, those originating from bone marrow may also be capable of differentiating to beta-cells, though equally well the beneficial effects of bone marrow cells may reside in their contribution to the damaged islet vasculature. Forced expression of the beta-cell-specific transcription factor Pdx1 in hepatocytes also holds promise as a therapeutic strategy to increase insulin levels in diabetic individuals. Embryonic stem (ES) cells are clearly another possible source for generating beta-cells, but ES cells are beyond the scope of this review, which focuses on adult stem and progenitor cells capable of producing beta-cells. Despite considerable endeavour, we still have much to learn in the field of pancreatic regeneration prior to any clinically applicable therapy based upon adult stem cells.

Fibroblasts of recipient origin contribute to bronchiolitis obliterans in human lung transplants.

RATIONALE: The participation of circulating precursor cells in the development of experimental pulmonary fibrosing lesions in mice has been recently demonstrated. OBJECTIVES: This study analyzes whether circulating, bone marrow-derived, fibroblastic precursor cells contribute to the development of fibrosing lesions in human lungs, especially bronchiolitis obliterans. METHODS: The occurrence of in situ microchimerism in bronchiolitis obliterans lesions of human lung allografts (n = 12) as well as of autologous lung tissue from patients post-bone marrow transplantation (n = 2) was analyzed using laser-assisted microdissection after immunohistochemical labeling of leukocytes followed by short tandem repeat-polymerase chain reaction-based genotyping. Combined immunofluorescence and fluorescence in situ hybridization for sex chromosomes was performed for independent confirmation in cases with appropriate sex mismatch (n = 2). MEASUREMENTS AND MAIN RESULTS: The bronchiolitis obliterans lesions of all 12 lung transplant patients contained considerable numbers of recipient-derived fibroblasts (mean, 32%). The fibrosing pulmonary lesions of the two bone marrow-transplanted patients also displayed clear in situ microchimerism. The in situ detection methodology confirmed these results, although to a lower degree (6-16%). CONCLUSIONS: These data clearly demonstrate the involvement of circulating fibroblastic precursor cells in the development of human fibrosing lung lesions and provide evidence that these cells are most probably bone marrow derived. These results may open new venues regarding the prevention of fibrosis in lung transplants and potentially in other organs.

[Fibroblasts of recipient origin contribute to broncholitis obliterans in human lung transplants]. / Bronchiolitis obliterans nach Lungentransplantation enthält Empfängerfibroblasten.

RATIONALE: The participation of circulating precursor cells in the development of experimental pulmonary fibrosing lesions in mice has been recently demonstrated. OBJECTIVES: This study analyzes whether circulating, bone marrow-derived fibroblastic precursor cells contribute to the development of fibrosing lesions in human lungs, especially bronchiolitis obliterans. METHODS: The occurrence of in situ-microchimerism in bronchiolitis obliterans lesions of human lung allografts (n = 12) as well as of autologous lung tissue from patients post bone marrow-transplantation (n = 2) was analyzed using laser-assisted microdissection after immunohistochemical labeling of leukocytes followed by STR-PCR-based genotyping. Combined immunofluorescence and fluorescence in situ hybridization for sex chromsomes was performed for independent confirmation in cases with appropriate sex mismatch (n = 2). MEASUREMENTS AND MAIN RESULTS: The bronchiolitis obliterans lesions of all twelve lung transplant patients contained considerable numbers of recipient-derived fibroblasts (mean: 32 %). The fibrosing pulmonary lesions of the two bone marrow-transplanted patients displayed also clear in situ-microchimerism. The in situ detection methodology confirmed these results, although to a lower degree (6-16%). CONCLUSIONS: These data clearly demonstrate the involvement of circulating fibroblastic precursor cells in the development of human fibrosing lung lesions and provide evidence that these cells are most probably bone marrow-derived. These results may open new venues regarding the prevention of fibrosis in lung transplants and potentially other organs.