On the key role played by altered protein conformation in Parkinson’s disease

Agnati, Luigi F.; Baldelli, Enrica; Andreoli, Nicola; Woods, Amina S.; Vellani, Vittorio; Marcellino, Daniel; Guidolin, Diego; Fuxé, Kjell

doi:10.1007/s00702-008-0072-1

Cited by 7 publications

(6 citation statements)

References 82 publications

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“…In vitro, CDNF protein was unable to promote the survival of embryonic motor neurons or dorsal root ganglion (DRG) neurons, or early postnatal sympathetic cervical ganglion (SCG) neurons differently from GDNF that supports the survival of different neuronal populations including motoneurons and enteric, sensory, parasympathetic, and sympathetic neurons. Similar to the results obtained with CDNF were also reported for the MANF protein, although MANF showed a small survival promoting effect on DRG neurons [38].…”

Section: Neurotrophinsupporting

confidence: 80%

Neurotrophic factors and Parkinson's disease

Bhardwaj¹,

Deshmukh²

2017

Clinical-Investigation

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Section: Neurotrophinsupporting

confidence: 80%

Neurotrophic factors and Parkinson's disease

Bhardwaj¹,

Deshmukh²

2017

Clinical-Investigation

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“…This protein conformational alteration appears to be correlated with reduced electron transfer rates, suggesting that excessive oxidative damage of complex I subunits leads to a misassembled complex I, hence to a pathologic Protein Mosaic [80][81][82]. This proposal is in agreement with the view that the formation of abnormal Protein Mosaics can cause distortion of cellular structures, toxic functions, and/or formation of improper membrane ion channels [81].…”

Section: Bb Mitochondria and Parkinson's Disease (Pd)supporting

confidence: 55%

“…It should also be mentioned that these neurons are autonomous pacemaker neurons, and that this pacemaking activity depends on Ca 2+ channels (L-type Cav1.3). This task is also likely to create a metabolic stress and an additional burden upon mitochondria [81,82,84].…”

Section: Bb Mitochondria and Parkinson's Disease (Pd)mentioning

confidence: 99%

A New Hypothesis of Pathogenesis Based on the Divorce between Mitochondria and their Host Cells: Possible Relevance for Alzheimers Disease

Lf¹,

Guidolin

Baluška³

et al. 2010

CAR

Self Cite

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On the basis of not only the endosymbiotic theory of eukaryotic cell organization and evolution but also of observations of transcellular communication via Tunneling NanoTubes (TNTs), the hypothesis is put forward that when mitochondria, which were once independently living prokaryote-like organisms, are subjected to detrimental genetic, toxic, or environmental conditions, including age-related endogenous factors, they can regress towards their original independent state. At that point, they can become potentially pathogenic intruders within their eukaryotic host cell. Because of the protoplasmic disequilibrium caused by an altered, or mutated, mitochondral population, certain host cells with a minimal capacity for self-renewal, such as dopaminergic neurons, risk a loss of function and degenerate. It is also proposed that altered mitochondria, as well as their mutated mtDNA, can migrate, via TNTs, into adjacent cells. In this way, neurodegenerative states are propagated between cells (glia and/or neurons) of the Central Nervous System (CNS) and that this leads to conditions such as Alzheimer's and Parkinson's disease. This proposal finds indirect support from observations on rotenone-poisoned glioblastoma cells which have been co-cultured with non-poisoned cells. Immunocytochemical techniques revealed that mitochondria, moving along the TNTs, migrated from the poisoned cells towards the healthy cells. It has also been demonstrated by means of immunocytochemistry that, in glioblastoma cell cultures, Amyloid Precursor Protein (APP) is present in TNTs, hence it may migrate from one cell to neighbouring cells. This datum may be of high relevance for a better understanding of Alzheimer's Disease (AD) since molecular, cellular, and animal model studies have revealed that the formation of amyloid beta (Abeta) and other derivatives of the APP are key pathogenic factors in AD, causing mitochondrial dysfunction, free radical generation, oxidative damage, and inflammation. Furthermore, the present data demonstrate the presence of alpha-synuclein (alpha-syn) within TNTs, hence a similar pathogenic mechanism to the one surmised for AD, but centred on alpha-syn rather than on Abeta, may play a role in Parkinson's Disease (PD). As a matter of fact, alpha-syn can enter mitochondria and interact with complex I causing respiratory deficiency and increased oxygen free radical production. In agreement with this view, it has been demonstrated that, in comparison with normal subjects, PD patients show a significant accumulation of alpha-syn at Substantia Nigra and Striatal level, predominantly associated with the inner mitochondrial membrane,. These observations suggest that potentially neuropathogenic proteins, such as Abeta and alpha-syn, can not only diffuse via the extracellular space but also move from cell to cell also via TNTs where they can cause mitochondrial damage and cell degeneration. A mathematical model (see Appendix) is proposed to simulate the pathogenic consequences of the migration of altered mitochondria and/or of ...

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“…In fact, an important role for alpha-synuclein in the aging of the enteric and autonomic circuitry of the GI tract might be anticipated because, in contrast to most neural systems where alpha-synuclein expression is restricted to presynaptic terminals (Andringa et al, 2003; Bennett, 2005; Halliday and McCann, 2008; Jakes et al, 1994), alpha-synuclein in the GI tract is expressed--in addition to presynaptic terminals--in the cytoplasm of neuronal somata and the axoplasm of neurites (Andringa et al, 2003; Bloch et al, 2006; Braak et al, , 2006, 2007; Hawkes et al, 2007; Miwa et al, 2006; Phillips and Powley, 2007; Phillips et al, 2008; Wakabayashi et al, 2007). Furthermore, alpha-synuclein has a tendency to fibrillize with itself and other native proteins, including tau (a protein frequently found to accumulate in aging and degenerating axons), it has a propensity to form insoluble intracellular aggregates, and it is prominently involved in synucleinopathies that frequently occur in old age (Agnati et al, 2008; Bennett, 2005; Frasier and Wolozin, 2004; Galpern and Lang, 2006; Goedert, 1999; Halliday and McCann, 2008; Lee, 2008; Mattson and Magnus, 2006), all of which make it a strong candidate to be involved in the formation of age-related inclusions in the gut’s nervous system. Finally, limited observations already indicate that at least some markedly swollen axons in the wall of the GI tract are immunopositive for alpha-synuclein (Phillips and Powley, 2007; Phillips et al, 2008), affirming the need for a more thorough examination of the expression of alpha-synuclein in the heteroplastic autonomic axons in the aging GI tract.…”

Section: Introductionmentioning

confidence: 99%

Alpha-synuclein immunopositive aggregates in the myenteric plexus of the aging Fischer 344 rat

Phillips

Walter

Ringer

et al. 2009

Experimental Neurology

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Dystrophic axons and terminals are common in the myenteric plexus and smooth muscle of the gastrointestinal (GI) tract of aged rats. In young adult rats, alpha-synuclein in its normal state is abundant throughout the myenteric plexus, making this protein--which is prone to fibrillization--a candidate marker for axonopathies in the aged rat. To determine if aggregation of alpha-synuclein is involved in the formation of age-related enteric neuropathies, we sampled the stomach, small intestine and large intestine of adult, middle-aged, and aged virgin male Fischer 344 rats stained for alpha-synuclein in both its normal and pathological states. Alpha-synuclein-positive dystrophic axons and terminals were present throughout the GI tract of middle-aged and aged rats, with immunohistochemical double-labeling demonstrating co-localization within nitric oxide synthase-, calretinin-, calbindin-, or tyrosine hydroxylase-positive markedly swollen neurites. However, other dystrophic neurites positive for each of these four markers were not co-reactive for alpha-synuclein. Similarly, a subpopulation of alpha-synuclein inclusions contained deposits immunostained with an anti-tau phospho-specific Ser262 antibody, but not all of these hyperphosphorylated tau-positive aggregates were co-localized with alpha-synuclein. The presence of heteroplastic and potentially degenerating neural elements and protein aggregates both positive and negative for alpha-synuclein suggests a complex chronological relationship between the onset of degenerative changes and the accumulation of misfolded proteins. Additionally, proteins other than alpha-synuclein appear to be involved in age-related axonopathies. Finally, this study establishes the utility of the aging Fischer 344 rat for the study of synucleopathies and tauopathies in the GI tract.

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On the key role played by altered protein conformation in Parkinson’s disease

Cited by 7 publications

References 82 publications

Neurotrophic factors and Parkinson's disease

Neurotrophic factors and Parkinson's disease

A New Hypothesis of Pathogenesis Based on the Divorce between Mitochondria and their Host Cells: Possible Relevance for Alzheimers Disease

Alpha-synuclein immunopositive aggregates in the myenteric plexus of the aging Fischer 344 rat

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