Summary The intestinal microbiota influence neurodevelopment, modulate behavior, and contribute to neurological disorders. However, a functional link between gut bacteria and neurodegenerative diseases remains unexplored. Synucleinopathies are characterized by aggregation of the protein α-synuclein (αSyn), often resulting in motor dysfunction as exemplified by Parkinson's disease (PD). Using mice that overexpress αSyn, we report herein that gut microbiota are required for motor deficits, microglia activation, and αSyn pathology. Antibiotic treatment ameliorates, while microbial re-colonization promotes, pathophysiology in adult animals, suggesting postnatal signaling between the gut and the brain modulates disease. Indeed, oral administration of specific microbial metabolites to germ-free mice promotes neuroinflammation and motor symptoms. Remarkably, colonization of αSyn-overexpressing mice with microbiota from PD patients enhances physical impairments compared to microbiota transplants from healthy human donors. These findings reveal that gut bacteria regulate movement disorders in mice, and suggest that alterations in the human microbiome represent a risk factor for PD.
Loss-of-function mutations in parkin are the major cause of early-onset familial Parkinson's disease. To investigate the pathogenic mechanism by which loss of parkin function causes Parkinson's disease, we generated a mouse model bearing a germline disruption in parkin. Parkin؊/؊ mice are viable and exhibit grossly normal brain morphology. Quantitative in vivo microdialysis revealed an increase in extracellular dopamine concentration in the striatum of parkin؊/؊ mice. Intracellular recordings of medium-sized striatal spiny neurons showed that greater currents are required to induce synaptic responses, suggesting a reduction in synaptic excitability in the absence of parkin. Furthermore, parkin؊/؊ mice exhibit deficits in behavioral paradigms sensitive to dysfunction of the nigrostriatal pathway. The number of dopaminergic neurons in the substantia nigra of parkin؊/؊ mice, however, is normal up to the age of 24 months, in contrast to the substantial loss of nigral neurons characteristic of Parkinson's disease. Steady-state levels of CDCrel-1, synphilin-1, and ␣-synuclein, which were identified previously as substrates of the E3 ubiquitin ligase activity of parkin, are unaltered in parkin؊/؊ brains. Together these findings provide the first evidence for a novel role of parkin in dopamine regulation and nigrostriatal function, and a non-essential role of parkin in the survival of nigral neurons in mice. Parkinson's disease (PD)1 is an age-related movement disorder characterized by bradykinesia, rigidity, resting tremor, and postural instability. The neuropathologic hallmarks of PD are the loss of dopaminergic neurons in the substantia nigra (SN) and the presence of intraneuronal cytoplasmic inclusions known as Lewy bodies. The clinical manifestations of PD are due to progressive degeneration of dopaminergic neurons in the pars compacta of the SN that give rise to the nigrostriatal pathway, causing dopamine (DA) depletion in the striatum, where it is required for normal motor function. Little is known about the mechanisms of PD pathogenesis and nigral degeneration, although DA neurons have been shown to be susceptible to oxidative stress (1), mitochondrial defects (2), and environmental toxins (3).The recent identification of genes linked to familial forms of PD (FPD) makes it possible to investigate the pathogenic mechanism by employing genetic approaches (4 -6). Over fifty recessively inherited mutations, including deletion, frameshift, nonsense, and missense mutations, have been identified in parkin in large numbers of families, making parkin the major gene responsible for early-onset FPD (7-10). Although the first report linked parkin mutations to autosomal recessive juvenile parkinsonism (AR-JP) with atypical clinical features (5), many more cases identified subsequently were considered typical early-onset FPD with symptoms often indistinguishable from sporadic PD (9, 11). Autopsies of limited numbers of patients showed selective loss of dopaminergic neurons in the SN either in the absence (12-15) or in the ...
Huntington's disease (HD) is caused by an abnormal expansion of CAG repeats in the gene encoding huntingtin. The development of therapies for HD requires preclinical testing of drugs in animal models that reproduce the dysfunction and regionally specific pathology observed in HD. We have developed a new knock-in mouse model of HD with a chimeric mouse/human exon 1 containing 140 CAG repeats inserted in the murine huntingtin gene. These mice displayed an increased locomotor activity and rearing at 1 month of age, followed by hypoactivity at 4 months and gait anomalies at 1 year. Behavioral symptoms preceded neuropathological anomalies, which became intense and widespread only at 4 months of age. These consisted of nuclear staining for huntingtin and huntingtin-containing nuclear and neuropil aggregates that first appeared in the striatum, nucleus accumbens, and olfactory tubercle. Interestingly, regions with early pathology all receive dense dopaminergic inputs, supporting accumulating evidence for a role of dopamine in HD pathology. Nuclear staining and aggregates predominated in striatum and layer II/III and deep layer V of the cerebral cortex, whereas neuropil aggregates were found in the globus pallidus and layer IV/superficial layer V of the cerebral cortex. The olfactory system displayed early and marked aggregate accumulation, which may be relevant to the early deficit in odor discrimination observed in patients with HD. Because of their early behavioral anomalies and regionally specific pathology, these mice provide a powerful tool with which to evaluate the effectiveness of new therapies and to study the mechanisms involved in the neuropathology of HD.
The central dogma of mammalian brain sexual differentiation has contended that sex steroids of gonadal origin organize the neural circuits of the developing brain. Recent evidence has begun to challenge this idea and has suggested that, independent of the masculinizing effects of gonadal secretions, XY and XX brain cells have different patterns of gene expression that influence their differentiation and function. We have previously shown that specific differences in gene expression exist between male and female developing brains and that these differences precede the influences of gonadal hormones. Here we demonstrate that the Y chromosome-linked, male-determining gene Sry is specifically expressed in the substantia nigra of the adult male rodent in tyrosine hydroxylase-expressing neurons. Furthermore, using antisense oligodeoxynucleotides, we show that Sry downregulation in the substantia nigra causes a statistically significant decrease in tyrosine hydroxylase expression with no overall effect on neuronal numbers and that this decrease leads to motor deficits in male rats. Our studies suggest that Sry directly affects the biochemical properties of the dopaminergic neurons of the nigrostriatal system and the specific motor behaviors they control. These results demonstrate a direct male-specific effect on the brain by a gene encoded only in the male genome, without any mediation by gonadal hormones.
Tissue restoration is the process whereby multiple damaged cell types are replaced to restore the histoarchitecture and function to the tissue. Several theories have been proposed to explain the phenomenon of tissue restoration in amphibians and in animals belonging to higher orders. These theories include dedifferentiation of damaged tissues, transdifferentiation of lineage-committed progenitor cells, and activation of reserve precursor cells. Studies by Young et al. and others demonstrated that connective tissue compartments throughout postnatal individuals contain reserve precursor cells. Subsequent repetitive single cell-cloning and cell-sorting studies revealed that these reserve precursor cells consisted of multiple populations of cells, including tissue-specific progenitor cells, germ-layer lineage stem cells, and pluripotent stem cells. Tissue-specific progenitor cells display various capacities for differentiation, ranging from unipotency (forming a single cell type) to multipotency (forming multiple cell types). However, all progenitor cells demonstrate a finite life span of 50 to 70 population doublings before programmed cell senescence and cell death occurs. Germ-layer lineage stem cells can form a wider range of cell types than a progenitor cell. An individual germ-layer lineage stem cell can form all cells types within its respective germ-layer lineage (i.e., ectoderm, mesoderm, or endoderm). Pluripotent stem cells can form a wider range of cell types than a single germ-layer lineage stem cell. A single pluripotent stem cell can form cells belonging to all three germ layer lineages. Both germ-layer lineage stem cells and pluripotent stem cells exhibit extended capabilities for self-renewal, far surpassing the limited life span of progenitor cells (50-70 population doublings). The authors propose that the activation of quiescent tissue-specific progenitor cells, germ-layer lineage stem cells, and/or pluripotent stem cells may be a potential explanation, along with dedifferentiation and transdifferentiation, for the process of tissue restoration. Several model systems are currently being investigated to determine the possibilities of using these adult quiescent reserve precursor cells for tissue engineering.
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