Cleavage of alpha-synuclein by calpain: potential role in degradation of fibrillized and nitrated species of alpha-synuclein.

Alpha-synuclein (alpha-syn) is a major protein component of the neuropathological hallmarks of Parkinson's disease and related neurodegenerative disorders termed synucleinopathies. Neither the mechanism of alpha-syn fibrillization nor the degradative process for alpha-syn has been elucidated. Previously, we showed that wild-type, mutated, and fibrillar alpha-syn proteins are substrates of calpain I in vitro. In this study, we demonstrate that calpain-mediated cleavage near and within the middle region of soluble alpha-syn with/without tyrosine nitration and oxidation generates fragments that are unable to self-fibrillize. More importantly, these fragments prevent full-length alpha-syn from fibrillizing. Calpain-mediated cleavage of alpha-syn fibrils composed of wild-type or nitrated alpha-syn generate C-terminally truncated fragments that retain their fibrillar structure and induce soluble full-length alpha-syn to co-assemble. Therefore, calpain-cleaved soluble alpha-syn inhibits fibrillization, whereas calpain-cleaved fibrillar alpha-syn promotes further co-assembly. These results provide insight into possible disease mechanisms underlying synucleinopathies since the formation of alpha-syn fibrils could be causally linked to the onset/progression of these disorders.

The E46K mutation in alpha-synuclein increases amyloid fibril formation.

The identification of a novel mutation (E46K) in one of the KTKEGV-type repeats in the amino-terminal region of alpha-synuclein suggests that this region and, more specifically, Glu residues in the repeats may be important in regulating the ability of alpha-synuclein to polymerize into amyloid fibrils. It was demonstrated that the E46K mutation increased the propensity of alpha-synuclein to fibrillize, but this effect was less than that of the A53T mutation. The substitution of Glu(46) for an Ala also increased the assembly of alpha-synuclein, but the polymers formed can have different ultrastructures, further indicating that this amino acid position has a significant effect on the assembly process. The effect of residue Glu(83) in the sixth repeat of alpha-synuclein, which lies closest to the amino acid stretch critical for filament assembly, was also studied. Mutation of Glu(83) to a Lys or Ala increased polymerization but perturbed some of the properties of mature amyloid. These results demonstrated that some of the Glu residues within the repeats can have significant effects on modulating the assembly of alpha-synuclein to form amyloid fibrils. The greater effect of the A53T mutation, even when compared with what may be predicted to be a more dramatic mutation such as E46K, underscores the importance of protein microenvironment in affecting protein structure. Moreover, the relative effects of the A53T and E46K mutations are consistent with the age of onset of disease. These findings support the notion that aberrant alpha-synuclein polymerization resulting in the formation of pathological inclusions can lead to disease.

Functional consequences of alpha-synuclein tyrosine nitration: diminished binding to lipid vesicles and increased fibril formation.

Previous studies have shown the presence of nitrated alpha-synuclein (alpha-syn) in human Lewy bodies and other alpha-syn inclusions. Herein, the effects of tyrosine nitration on alpha-syn fibril formation, lipid binding, chaperone-like function, and proteolytic degradation were systematically examined by employing chromatographically isolated nitrated monomeric, dimeric, and oligomeric alpha-syn. Nitrated alpha-syn monomers and dimers but not oligomers accelerated the rate of fibril formation of unmodified alpha-syn when present at low concentrations. Immunoelectron microscopy revealed that nitrated monomers and dimers are incorporated into the fibrils. However, the purified nitrated alpha-syn monomer by itself was unable to form fibrils. Nitration of the tyrosine residue at position 39 was largely responsible for decreased binding of nitrated monomeric alpha-syn to synthetic vesicles, which correlated with an impairment of the nitrated protein to adopt alpha-helical conformation in the presence of liposomes. The chaperone-like activity of alpha-syn was not inhibited by nitration or oxidation. Furthermore, the 20 S proteasome and calpain I degraded nitrated monomeric alpha-syn, although at a slower rate compared with control alpha-syn. Collectively, these data suggest that post-translational modification of alpha-syn by nitration can promote the formation of intracytoplasmic inclusions that constitute the hallmark of Parkinson disease and other synucleinopathies.

Differential preservation of AMPA receptor subunits in the hippocampi of Alzheimer's disease patients according to Braak stage.

The Alzheimer's disease (AD) brain, characterized pathologically by the presence of senile plaques and neurofibrillary tangles, contains regions that are differentially prone toward development of AD pathology. Within these "vulnerable" regions, specific cell populations appear to be selectively affected; the pyramidal cells of the hippocampal subiculum subfield constitute such a vulnerable region. This study investigated whether the AMPA receptor subunit content (GluR1, GluR2, GluR2/3) within "vulnerable" vs. "resistant" sectors of the hippocampus is quantitatively altered with increasing AD neuropathology, as determined by Braak staging. We hypothesize that the glutamate-mediated vulnerability is highly influenced by the repertoire of glutamate receptors expressed on hippocampal neurons. Our results indicate that AMPA receptor subunit proteins are relatively spared across all Braak stages in resistant subfields (CA2/CA3/Dentate Gyrus). However, within vulnerable sectors, i.e., subiculum, GluR2, and GluR2/3 protein levels decreased 63.77% and 60.60%, respectively, in association with Braak stages I-II and stages III-IV, respectively. In Braak stages V-VI, GluR2 and GluR2/3 protein levels were similar to those of Braak stages I-II. In contrast to GluR2 and GluR2/3, GluR1 protein levels were unchanged within vulnerable sectors throughout all stages of the disease. In interpreting these data, it may be relevant to consider that the GluR2 subunit impedes the flow of Ca(+2) through the AMPA receptor ion channel. Thus, we hypothesize that in resistant sectors, the presence of the GluR2 subunit may provide a neuroprotective role by limiting the flow of extracellular Ca(+2), whereas in vulnerable regions, the reduction of GluR2 may contribute to the vulnerability via a mechanism involving an increase in intracellular Ca(+2) and destabilization of intracellular Ca(+2) homeostasis.

Biochemical and molecular studies of NMDA receptor subunits NR1/2A/2B in hippocampal subregions throughout progression of Alzheimer's disease pathology.

Alzheimer's disease (AD) is characterized by loss of specific cell populations within selective subregions of the hippocampus. Excitotoxicity, mediated via ionotropic glutamate receptors, may play a crucial role in this selective neuronal vulnerability. We investigated whether alterations in NMDA receptor subunits occurred during AD progression. Employing biochemical and in situ hybridization techniques in subjects with a broad range of AD pathology, protein levels, and mRNA expression of NR1/2A/2B subunits were assayed. With increasing AD neuropathology, protein levels and mRNA expression for NR1/2B subunits were significantly reduced, while the NR2A subunit mRNA expression and protein levels were unchanged. Cellular analysis of neuronal mRNA expression revealed a significant increase in the NR2A subunit in subjects with moderate neurofibrillary tangle neuropathology. This investigation supports the hypothesis that alterations occur in the expression of specific NMDA receptor subunits with increasing AD pathologic severity, which is hypothesized to contribute to the vulnerability of these neurons.

Plasticity of glutamate and GABAA receptors in the hippocampus of patients with Alzheimer's disease.

AIM: In Alzheimer's disease (AD) it is well known that specific regions of the brain are particularly vulnerable to the pathologic insults of the disease. In particular, the hippocampus is affected very early in the disease and by end stage AD is ravaged by neurofibrillary tangles and senile plaques (i.e., the pathologic hallmarks of AD). Throughout the past several years our laboratory has sought to determine the molecular mechanisms underlying the selective vulnerability of neurons in AD. METHODS: To this end, we employed immunohistochemical, biochemical, and in situ hybrization methods to examine glutamate and gamma-aminobutyric acid (GABAA) receptor subtypes in the hippocampus of patients displaying the full spectrum of AD pathology. RESULTS: Despite the fact that the hippocampus is characterized by a marked loss of neurons in the late stages of the disease, our data demonstrate a rather remarkable preservation among some glutamate and GABAA receptor subtypes. CONCLUSIONS: Collectively, our data support the view that the relatively constant levels of selected receptor subtypes represent a compensatory up-regulation of these receptors subunits in surviving neurons. The demonstration that glutamate and GABA receptor subunits are comparably unaffected implies that even in the terminal stages of the discase the brain is "attempting" to maintain a balance in excitatory and inhibitory tone. Our data also support the concept that receptor subunits are differentially affected in AD with some subunits displaying no change while others display alterations in protein and mRNA levels within selected regions of the hippocampus. Although many of these changes are modest, they do suggest that the subunit composition of these receptors may be altered and hence affect the pharmacokinetic and physiological properties of the receptor. The latter findings stress the importance of understanding the subunit composition of individual glutamate/GABA receptors in the diseased brain prior to the development of drugs targeted towards those receptors.

Distinct cleavage patterns of normal and pathologic forms of alpha-synuclein by calpain I in vitro.

Parkinson's disease (PD) is characterized by fibrillary neuronal inclusions called Lewy bodies (LBs) consisting largely of alpha-synuclein (alpha-syn), the protein mutated in some patients with familial PD. The mechanisms of alpha-syn fibrillization and LB formation are unknown, but may involve aberrant degradation or turnover. We examined the ability of calpain I to cleave alpha-syn in vitro. Calpain I cleaved wild-type alpha-syn predominantly after amino acid 57 and within the non-amyloid component (NAC) region. In contrast, calpain I cleaved fibrillized alpha-syn primarily in the region of amino acid 120 to generate fragments like those that increase susceptibility to dopamine toxicity and oxidative stress. Further, while calpain I cleaved wild-type alpha-syn after amino acid 57, this did not occur in mutant A53T alpha-syn. This paucity of proteolysis could increase the stability of A53T alpha-syn, suggesting that calpain I might protect cells from forming LBs by specific cleavages of soluble wild-type alpha-syn. However, once alpha-syn has polymerized into fibrils, calpain I may contribute to toxicity of these forms of alpha-syn by cleaving at aberrant sites within the C-terminal region. Elucidating the role of calpain I in the proteolytic processing of alpha-syn in normal and diseased brains may clarify mechanisms of neurodegenerative alpha-synucleinopathies.