The mitochondrial electron transport enzyme NADH:ubiquinone oxidoreductase (complex I), which is encoded by both mitochondrial DNA and nuclear DNA, is defective in multiple tissues in persons with Parkinson's disease (PD). The origin of this lesion and its role in the neurodegeneration of PD are unknown. To address these questions, we created an in vitro system in which the potential contributions of environmental toxins, complex I nuclear DNA mutations, and mitochondrial DNA mutations could be systematically analyzed. A clonal line of human neuroblastoma cells containing no mitochondrial DNA was repopulated with mitochondria derived from the platelets of PD or control subjects. After 5 to 6 weeks in culture, these cytoplasmic hybrid (cybrid) cell lines were assayed for electron transport chain activities, production of reactive oxygen species, and sensitivity to induction of apoptotic cell death by 1-methyl-4-phenyl pyridinium (MPP+). In PD cybrids we found a stable 20% decrement in complex I activity, increased oxygen radical production, and increased susceptibility to 1-methyl-4-phenyl pyridinium-induced programmed cell death. The complex I defect in PD appears to be genetic, arising from mitochondrial DNA, and may play an important role in the neurodegeneration of PD by fostering reactive oxygen species production and conferring increased neuronal susceptibility to mitochondrial toxins.
The development of renin-containing cells and nerve fibers was studied in Sprague-Dawley rat kidneys during the last third of gestation and the first 15 days of postnatal life. Kidney tissue sections were stained for nerve fibers or double stained employing an anti-rat renin polyclonal antibody and a monoclonal antibody (TUJ1) directed against a neuron-specific class III beta-tubulin isotype. Renin-containing cells and nerve fibers were detected at 17 days of gestation, in close spatial relationship along the main branches of the renal artery. During fetal life, renin-containing cells and nerve fibers were spatially associated along arcuate and interlobular arteries, renin-containing cells being also present throughout the entire length of afferent arterioles supplying juxtamedullary glomeruli. During postnatal life the distribution of renin-containing cells progressively shifted to a restricted juxtaglomerular position in afferent arterioles. Simultaneously, density and organization of nerve fibers increased with age along the arterial vascular tree. Our results suggest that innervation of renin-containing cells is present in fetal life and follows the centrifugal pattern of renin distribution and nephrovascular development.
Cultured neurons require specific trophic agents in order to survive. This dependence is thought to resemble the neuron-target interdependence that develops in vivo during synaptogenesis and neuronal cell death. The notion that neurons in general derive trophic support from their synaptic targets is based primarily on studies of peripheral neurons and motor neurons. To assess the general applicability of this nerve-target relationship, we tested the ability of vascular smooth muscle (VSM) to support dissociated neurons from the chick ciliary ganglion. The ciliary ganglion contains 2 distinct neuronal populations, one of which innervates striated muscle, the other VSM. Striated muscle cocultures are known to support all of the neurons in the ganglion for extended periods. Dissociated neurons were therefore cocultured in microwells containing VSM derived from the rat or chick aorta and from the choroid coat of the chick eye. Surviving neurons were counted after 1, 2, 5, and 7 d. Striated muscle is able to support full neuronal survival in the same assay. However, in no case was VSM capable of contributing to neuronal survival in vitro. The neurons in the VSM cocultures were able to form neurites and make contacts with their putative targets, as confirmed by scanning electron and light microscopy. The presence of viable and differentiated smooth muscle cells was demonstrated in the cultures by transmission electron microscopy and analysis of smooth muscle alpha-actin. The failure of VSM and even the choroid target tissue to support the survival of their innervating neurons suggests that novel mechanisms may operate to provide trophic support for neurons innervating VSM targets.
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