β-Sheet-rich α-synuclein (αS) aggregates characterize Parkinson's disease (PD). αS was long believed to be a natively unfolded monomer, but recent work suggests it also occurs in α-helix-rich tetramers. Crosslinking traps principally tetrameric αS in intact normal neurons, but not after cell lysis, suggesting a dynamic equilibrium. Here we show that freshly biopsied normal human brain contains abundant αS tetramers. The PD-causing mutation A53T decreases tetramers in mouse brain. Neurons derived from an A53T patient have decreased tetramers. Neurons expressing E46K do also, and adding 1-2 E46K-like mutations into the canonical αS repeat motifs (KTKEGV) further reduces tetramers, decreases αS solubility and induces neurotoxicity and round inclusions. The other three fPD missense mutations likewise decrease tetramer:monomer ratios. The destabilization of physiological tetramers by PD-causing missense mutations and the neurotoxicity and inclusions induced by markedly decreasing tetramers suggest that decreased α-helical tetramers and increased unfolded monomers initiate pathogenesis. Tetramer-stabilizing compounds should prevent this.
Background: ␣Syn is central to Parkinsonism, but its native state is unsettled. Results: A new, facile method for cross-linking ␣Syn in living cells, including neurons, reveals a major 60-kDa form consistent with a tetramer. Cell lysis destabilizes it, yielding mostly monomers. Conclusion: ␣Syn exists principally as a metastable tetramer in vivo. Significance: Models of native ␣Syn as an unfolded monomer should be reconsidered.
Background: Mitochondrial dysfunction and aggregation of ␣-synuclein both contribute to Parkinson disease. Results: Prefibrillar ␣-synuclein oligomers reduce the Ca 2ϩ retention time of isolated mitochondria respiring with complex I but not II substrates. Conclusion: Oligomeric ␣-synuclein promotes mitochondrial dysfunction in a Ca
A switch in the conformational properties of α-synuclein (αS) is hypothesized to be a key step in the pathogenic mechanism of Parkinson’s disease (PD). Whereas the beta-sheet-rich state of αS has long been associated with its pathological aggregation in PD, a partially alpha-helical state was found to be related to physiological lipid binding; this suggests a potential role of the alpha-helical state in controlling synaptic vesicle cycling and resistance to β-sheet rich aggregation. N-terminal acetylation is the predominant post-translational modification of mammalian αS. Using circular dichroism, isothermal titration calorimetry, and fluorescence spectroscopy, we have analyzed the effects of N-terminal acetylation on the propensity of recombinant human αS to form the two conformational states in interaction with lipid membranes. Small unilamellar vesicles of negatively charged lipids served as model membranes. Consistent with previous NMR studies using phosphatidylserine, we found that membrane-induced α-helical folding was enhanced by N-terminal acetylation and that greater exothermic heat could be measured upon vesicle binding of the modified protein. Interestingly, the folding and lipid binding enhancements with phosphatidylserine in vitro were weak when compared to that of αS with GM1, a lipid enriched in presynaptic membranes. The resultant increase in helical folding propensity of N-acetylated αS enhanced its resistance to aggregation. Our findings demonstrate the significance of the extreme N-terminus for folding nucleation, for relative GM1 specificity of αS-membrane interaction, and for a protective function of N-terminal-acetylation against αS aggregation mediated by GM1.
Although clinically distinct, schizophrenia and Alzheimer's disease are common and devastating disorders that profoundly impair cognitive function. For Alzheimer's disease, key mechanistic insights have emerged from genetic studies that identified causative mutations in amyloid precursor protein (APP) and presenilin. Several genes have been associated with schizophrenia and other major psychoses, and understanding their normal functions will help elucidate the underlying causes of these disorders. One such gene is disrupted-in-schizophrenia 1 (DISC1). DISC1 and APP have been implicated separately in cortical development, with each having roles in both neuronal migration and neurite outgrowth. Here, we report a previously unrecognized biochemical and functional interaction between DISC1 and APP. Using in utero electroporation in the living rat brain, we show that DISC1 acts downstream of APP and Disabled-1 to regulate cortical precursor cell migration. Specifically, overexpression of DISC1 rescues the migration defect caused by a loss of APP expression. Moreover, knockdown of APP in cultured embryonic neurons results in altered subcellular localization of DISC1. Using transfected cells and normal brain tissue, we show that APP and DISC1 coimmunoprecipitate and that the intracellular domain of APP interacts with the N-terminal domain of DISC1. Based on these findings, we hypothesize that the APP cytoplasmic region transiently interacts with DISC1 to help regulate the translocation of DISC1 to the centrosome, where it plays a key role in controlling neuronal migration during cortical development.
Despite two decades of research, the structure-function relationships of endogenous, physiological forms of α-synuclein (αSyn) are not well understood. Most in vitro studies of this Parkinson's disease-related protein have focused on recombinant αSyn that is unfolded and monomeric, assuming that this represents its state in the normal human brain. Recently, we have provided evidence that αSyn exists in considerable part in neurons, erythrocytes and other cells as a metastable multimer that principally sizes as a tetramer. In contrast to recombinant αSyn, physiological tetramers purified from human erythrocytes have substantial α-helical content and resist pathological aggregation into β-sheet rich fibers. Here, we report the first method to fully purify soluble αSyn from the most relevant source, human brain. We describe protocols that purify αSyn to homogeneity from non-diseased human cortex using ammonium sulfate precipitation, gel filtration, and ion exchange, hydrophobic interaction and affinity chromatographies. Crosslinking of the starting material and the partially purified chromatographic fractions revealed abundant αSyn multimers, including apparent tetramers, but these were destabilized in large part to monomers during the final purification step. The method also fully purified the homologue β-synuclein, with a similar outcome. Circular dichroism spectroscopy showed that purified, brain-derived αSyn can display more helical content than the recombinant protein, but this result varied. Collectively, our data suggest that purifying αSyn to homogeneity destabilizes native, α-helix-rich multimers that exist in intact and partially purified brain samples. This finding suggests the existence of a stabilizing co-factor (e.g., a small lipid) present inside neurons that is lost during final purification.
Misfolding and pathogenic aggregation of α-synuclein (αSyn) is a hallmark of familial and sporadic Parkinson's disease, but the physiological state of the protein in cells remains unsettled. We have further examined our hypothesis that endogenous αSyn can occur in normal cells as a metastable, helically folded tetramer, not solely as the unfolded monomer long thought to be its native form. At this meeting, we reviewed our recent approaches for trapping αSyn in intact cells via in vivo crosslinking, a 5-step purification of αSyn from normal human brain, and the generation of new monoclonal antibodies to αSyn that enable general and oligomer-selective ELISAs. Crosslinking in intact living cells confirmed that αSyn occurs in the cytosol of neurons and non-neural cells in substantial part as metastable tetramers and related oligomers, plus varying amounts of free monomers. The non-pathogenic homolog, β-synuclein, forms closely similar oligomeric assemblies, suggesting that the oligomers we observe for αSyn are also physiological. In contrast to other normal oligomeric proteins (e.g., DJ-1), αSyn tetramers dissociate rapidly to monomers upon conventional cell lysis but are retained partially as tetramers if cells are lysed at high protein concentrations (‘molecular crowding'). Thus, αSyn exists natively as helical tetramers that are in dynamic equilibrium with unfolded monomers. The tetramers appear relatively resistant to aggregation, in contrast to monomers, which may give rise to fibrillar inclusions.
Skeletal muscle growth and its regeneration following injury rely on myogenic progenitor cells, a heterogeneous population that includes the satellite cells and other interstitial progenitors. The present study demonstrates that surface expression of β4 integrin marks a population of vessel-associated interstitial muscle progenitor cells. Muscle β4 integrin–positive cells do not express myogenic markers upon isolation. However, they are capable of undergoing myogenic specification in vitro and in vivo: β4 integrin cells differentiate into multinucleated myotubes in culture dishes and contribute to muscle regeneration upon delivery into diseased mice. Subfractionation of β4 integrin–expressing cells based on CD31 expression does not further enrich for myogenic precursors. These findings support the expression of β4 integrin in interstitial, vessel-associated cells with myogenic activity within adult skeletal muscle.
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