Inhibition of Methyltransferase Setd7 Allows the In Vitro Expansion of Myogenic Stem Cells with Improved Therapeutic Potential.

The development of cell therapy for repairing damaged or diseased skeletal muscle has been hindered by the inability to significantly expand immature, transplantable myogenic stem cells (MuSCs) in culture. To overcome this limitation, a deeper understanding of the mechanisms regulating the transition between activated, proliferating MuSCs and differentiation-primed, poorly engrafting progenitors is needed. Here, we show that methyltransferase Setd7 facilitates such transition by regulating the nuclear accumulation of ß-catenin in proliferating MuSCs. Genetic or pharmacological inhibition of Setd7 promotes in vitro expansion of MuSCs and increases the yield of primary myogenic cell cultures. Upon transplantation, both mouse and human MuSCs expanded with a Setd7 small-molecule inhibitor are better able to repopulate the satellite cell niche, and treated mouse MuSCs show enhanced therapeutic potential in preclinical models of muscular dystrophy. Thus, Setd7 inhibition may help bypass a key obstacle in the translation of cell therapy for muscle disease.

Submyeloablative conditioning with busulfan permits bone marrow-derived cell accumulation in a murine model of Alzheimer's disease.

Previous work has suggested that bone marrow (BM)-derived cells (BMDCs) accumulate within the CNS and could potentially associate with ß-amyloid plaques in Alzheimer's disease (AD). To explore the accumulation of BMDCs in murine AD, we transplanted green fluorescent protein (GFP)-labeled BM cells into triple transgenic (3×Tg) and wild-type (wt) mice using non-irradiative myelosuppresive conditioning with busulfan (BU). We find that BU (80mg/kg) is sufficient to obtain adequate chimerism (>85%) in wt mice. In order to obtain appreciable non-irradiative chimerism in the 3×Tg mice (>80%), anti-asialo ganglio-N-tetraosylceramide (α-ASGM-1) antibody was also used to reduce natural killer cell function and thereby abrogate the hybrid resistance of the 3×Tg mouse strain. Using BU conditioning and α-ASGM-1 together, we observed sustained BM chimerism and BMDC accumulation within the CNS of the 3×Tg and wt mice. In cortex and hippocampus, BMDC accumulation was perivascular in distribution and similar between 3×Tg and wt mice, with no clear association between BMDCs and AD plaques. We conclude that non-irradiative BM chimerism can be achieved with BU in 3×Tg mice, but requires α-ASGM-1 (or similar appropriate NK-cell depletion). Use of this chimerism protocol permits BMDCs accumulation in the CNS of mixed strain recipient mice although BMDCs appear to be largely perivascular within cortex and hippocampus.

Myelosuppressive conditioning using busulfan enables bone marrow cell accumulation in the spinal cord of a mouse model of amyotrophic lateral sclerosis.

Myeloablative preconditioning using irradiation is the most commonly used technique to generate rodents having chimeric bone marrow, employed for the study of bone marrow-derived cell accumulation in the healthy and diseased central nervous system. However, irradiation has been shown to alter the blood-brain barrier, potentially creating confounding artefacts. To better study the potential of bone marrow-derived cells to function as treatment vehicles for neurodegenerative diseases alternative preconditioning regimens must be developed. We treated transgenic mice that over-express human mutant superoxide dismutase 1, a model of amyotrophic lateral sclerosis, with busulfan to determine whether this commonly used chemotherapeutic leads to stable chimerism and promotes the entry of bone marrow-derived cells into spinal cord. Intraperitoneal treatment with busulfan at 60 mg/kg or 80 mg/kg followed by intravenous injection of green fluorescent protein-expressing bone marrow resulted in sustained levels of chimerism (~80%). Bone marrow-derived cells accumulated in the lumbar spinal cord of diseased mice at advanced stages of pathology at both doses, with limited numbers of bone marrow derived cells observed in the spinal cords of similarly treated, age-matched controls; the majority of bone marrow-derived cells in spinal cord immunolabelled for macrophage antigens. Comparatively, significantly greater numbers of bone marrow-derived cells were observed in lumbar spinal cord following irradiative myeloablation. These results demonstrate bone marrow-derived cell accumulation in diseased spinal cord is possible without irradiative preconditioning.

Bone marrow-derived cells in the central nervous system of a mouse model of amyotrophic lateral sclerosis are associated with blood vessels and express CX(3)CR1.

Amyotrophic lateral sclerosis (ALS) is associated with increased numbers of microglia within the CNS. However, it is unclear to what extent bone marrow (BM)-derived cells contribute to this microgliosis. We have studied the adoptive transfer of green fluorescent protein (GFP)-labeled whole BM cells and BM from mice that express GFP only in CX(3)CR1+ cells (CX(3)CR1(+/GFP)) into the CNS of a murine model of ALS having over-expression of mutant superoxide dismutase (mSOD), and wt littermates. We find that most GFP+ and CX(3)CR1(+/GFP) cells are found adjacent to the microvasculature within the CNS, both in mSOD and wt mice. GFP+ and CX(3)CR1(+/GFP) cells within the CNS have a variety of morphologies, including cells with an elongated appearance, weak Iba-1 immunoreactivity, and often mannose receptor immunoreactivity, indicating that these cells are perivascular microglia. Typically, less than 10% of BM-derived cells had a stellate-shape and expressed strong Iba-1 immunoreactivity, as expected for parenchymal microglia, indicating that BM-derived cells uncommonly generate parenchymal microglia. Adoptive transfer of BM-derived cells from CX(3)CR1(+/GFP) mice revealed that many elongated cells are GFP+, demonstrating that some perivascular cells are derived from BM cells of the CX(3)CR1+ lineage. The significantly greater numbers of BM cells in mSOD than in control mice indicate that the presence of these BM cells in the spinal cord is regulated by conditioning stimuli that may include irradiation and inflammatory factors within the CNS.

Origin and distribution of bone marrow-derived cells in the central nervous system in a mouse model of amyotrophic lateral sclerosis.

Amyotrophic lateral sclerosis (ALS) is associated with increased numbers of microglia within the central nervous system (CNS). However, it is unknown whether the microgliosis results from proliferation of CNS resident microglia, or recruitment of bone marrow (BM)-derived microglial precursors. Here we assess the distribution and number of BM-derived cells in spinal cord using transplantation of green fluorescent protein (GFP)-labeled BM cells into myelo-ablated mice over-expressing human mutant superoxide dismutase 1 (mSOD), a murine model of ALS. Transplantation of GFP+ BM did not affect the rate of disease progression in mSOD mice. Mean numbers of microglia and GFP+ cells in spinal cords of control mice were not significantly different from those in asymptomatic mSOD mice and showed no change with animal age. The number of GFP+ cells and microglia (F4/80+ and CD11b+ cells) within the spinal cord of mSOD mice increased compared to age-matched controls at a time when mSOD mice exhibited disease symptoms, continuing up to disease end-stage. Although we observed an increase in the number of GFP+ cells in spinal cords of mSOD mice with disease symptoms, mean numbers of GFP+ F4/80+ cells comprised less than 20% of all F4/80+ cells and did not increase with disease progression. Furthermore, the relative rates of proliferation in CD45+GFP- and CD45+GFP+ cells were comparable. Thus, we demonstrate that the microgliosis present in spinal cord tissue of mSOD mice is primarily due to an expansion of resident microglia and not to the recruitment of microglial precursors from the circulation.