The chemokine stromal-derived factor-1 (SDF-1, also known as CXCL12) and its receptor CXCR4 have been implicated in homing of stem cells to the bone marrow and the homing of bone marrow-derived cells to sites of injury. Bone marrow cells infiltrate brain and give rise to long-term resident cells following injury. Therefore, SDF-1 and CXCR4 expression patterns in 40 mice were examined relative to the homing of bone marrow-derived cells to sites of ischemic injury using a stroke model. Mice received bone marrow transplants from green fluorescent protein (GFP) transgenic donors and later underwent a temporary middle cerebral artery suture occlusion (MCAo). SDF-1 was associated with blood vessels and cellular profiles by 24 hours through at least 30 days post-MCAo. SDF-1 expression was principally localized to the ischemic penumbra. The majority of SDF-1 expression was associated with reactive astrocytes; much of this was perivascular. GFP+ cells were associated with SDF-1-positive vessels and were also found in the neuropil of regions with increased SDF-1 immunoreactivity. Most vessel-associated GFP+ cells resemble pericytes or perivascular microglia and the majority of the GFP+ cells in the parenchyma displayed characteristics of activated microglial cells. These findings suggest SDF-1 is important in the homing of bone marrow-derived cells, especially monocytes, to areas of ischemic injury.
Background and Purpose-After an ischemic event, bone marrow-derived cells may be involved in reparative processes.There is increasing evidence that bone marrow-derived stem cells may be a source of endothelial cells and organ-specific cells. Our objectives were to determine whether bone marrow-derived cells were a source of endothelial cells and neurons after cerebral ischemia. Methods-We transplanted bone marrow from male C57 BL/6-TgN (ACTbEGFP)1Osb mice, which express green fluorescent protein (GFP), into female C57 BL/6J mice. The recipient mice then underwent suture occlusion of the middle cerebral artery (MCA), and bone marrow-derived cells were tracked by GFP epifluorescence and Y chromosome probe. Results-Within 3 days and at 7 and 14 days after MCA occlusion, bone marrow-derived cells incorporated into the vasculature in the ischemic zone and expressed an endothelial cell phenotype. Few bone marrow-derived cells incorporated into the vasculature 24 hours after MCA occlusion. Some bone marrow-derived cells also expressed the neuronal marker NeuN at 7 and 14 days after ischemia. Conclusions-Postnatal vasculogenesis occurs in the brain in the setting of a cerebral infarction. Bone marrow-derived cells are a source of endothelial cells and NeuN-expressing cells after cerebral infarction. This plasticity may be exploited in the future to enhance recovery after stroke.
Once hypoxic-ischemic (HI) injury ensues in the human neonate at birth, the resulting brain damage lasts throughout the individual's lifetime, as no ameliorative treatments are currently available. We have recently shown that intracerebral transplantation of multipotent adult progenitor cells (MAPCs) results in behavioral improvement and reduction in ischemic cell loss in neonatal rat HI-injury model. In an attempt to advance this cellular therapy to the clinic, we explored the more practical and less invasive intravenous administration of MAPCs. Seven-day-old Sprague-Dawley rats were initially subjected to unilateral HI injury, then 7 days later received intracerebral or intravenous injections of allogeneic rat MAPCs. On post-transplantation days 7 and 14, the animals that received MAPCs via the intracerebral or intravenous route exhibited improved motor and neurologic scores compared with those that received vehicle infusion alone. Immunohistochemical evaluations at day 14 after transplantation revealed that both intracerebrally and intravenously transplanted MAPCs were detected in the ischemic hippocampal area. The degree of hippocampal cell preservation was almost the same in the two treatment groups and greater than that in the vehicle group. These results show that intravenous delivery of MAPCs is a feasible and efficacious cell therapy with potential for clinical use.
This study was undertaken to determine if patients who lack muscle phosphorylase (i.e., McArdle's disease), and therefore the ability to produce lactic acid during exercise, demonstrate a normal hyperventilatory response during progressive incremental exercise. As expected these patients did not increase their blood lactate above resting levels, whereas the blood lactate levels of normal subjects increased 8- to 10-fold during maximal exercise. The venous pH of the normal subjects decreased markedly during exercise that resulted in hyperventilation. The patients demonstrated a distinct increase in ventilation with respect to O2 consumption similar to that seen in normal individuals during submaximal exercise. However their hyperventilation resulted in an increase in pH because there was no underlying metabolic acidosis. End-tidal partial pressures of O2 and CO2 also reflected a distinct hyperventilation in both groups at approximately 70-85% maximal O2 consumption. These data show that hyperventilation occurs during intense exercise, even when there is no increase in plasma [H+]. Since arterial CO2 levels were decreasing and O2 levels were increasing during the hyperventilation, it is possible that nonhumoral stimuli originating in the active muscles or in the brain elicit the hyperventilation observed during intense exercise.
Neurofibromatosis 2 (NF2) patients with constitutional splice site NF2 mutations have greater variability in disease severity than NF2 patients with other types of mutations; the cause of this variability is unknown. We evaluated genotype-phenotype correlations, with particular focus on the location of splice site mutations, using mutation and clinical information on 831 patients from 528 NF2 families with identified constitutional NF2 mutations. The clinical characteristics examined were age at onset of symptoms of NF2 and number of intracranial meningiomas, which are the primary indices of the severity of NF2. Two regression models were used to analyse genotype-phenotype correlations. People with splice site mutations in exons 1-5 had more severe disease than those with splice site mutations in exons 11-15. This result is compatible with studies showing that exons 2 and 3 are required for selfassociation of the amino terminal of the NF2 protein in vitro, and that deletions of exons 2 and 3 in transgenic and knockout mouse models of NF2 cause a high prevalence of Schwann cell derived tumours.
Children born with hypoxic-ischemic (HI) brain injury account for a significant number of live births wherein no clinical treatment is available. Limited clinical trials of stem cell therapy have been initiated in a number of neurological disorders, but the preclinical evidence of a cell-based therapy for neonatal HI injury remains in its infancy. One major postulated mechanism underlying therapeutic benefits of stem cell therapy involves stimulation of endogenous neurogenesis via transplantation of exogenous stem cells. To this end, transplantation has targeted neurogenic sites, such as the hippocampus, for brain protection and repair. The hippocampus has been shown to secrete growth factors, especially during the postnatal period, suggesting that this brain region presents as highly conducive microenvironment for cell survival. Based on its neurogenic and neurotrophic factor-secreting features, the hippocampus stands as an appealing target for stem cell therapy. Here, we investigated the efficacy of intrahippocampal transplantation of multipotent progenitor cells (MPCs), which are pluripotent progenitor cells with the ability to differentiate into a neuronal lineage. Seven-day-old Sprague-Dawley rats were initially subjected to unilateral HI injury, which involved permanent ligation of the right common carotid artery and subsequent exposure to hypoxic environment. At day 7 after HI injury, animals received stereotaxic hippocampal injections of vehicle or cryopreserved MPCs (thawed just prior to transplantation) derived either from Sprague-Dawley rats (syngeneic) or Fisher rats (allogeneic). All animals were treated with daily immunosuppression throughout the survival period. Behavioral tests were conducted on posttransplantation days 7 and 14 using the elevated body swing test and the rotarod to reveal general and coordinated motor functions. MPC transplanted animals exhibited reduced motor asymmetry and longer time spent on the rotarod than those that received the vehicle infusion. Both syngeneic and allogeneic MPC transplanted injured animals did not significantly differ in their behavioral improvements at both test periods. Immunohistochemical evaluations of graft survival after behavioral testing at day 14 posttransplantation revealed that syngeneic and allogeneic transplanted MPCs survived in the hippocampal region. These results demonstrate for the first time that transplantation of MPCs ameliorated motor deficits associated with HI injury. In view of comparable behavioral recovery produced by syngeneic and allogeneic MPC grafts, allogeneic transplantation poses as a feasible and efficacious cell replacement strategy with direct clinical application. An equally major finding is the observation lending support to the hippocampus as an excellent target brain region for stem cell therapy in treating HI injury.
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