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Journal ArticleDOI

Monogenic Parkinson's disease and parkinsonism: Clinical phenotypes and frequencies of known mutations.

Andreas Puschmann1
Lund University1
01 Apr 2013-Parkinsonism & Related Disorders (Elsevier)-Vol. 19, Iss: 4, pp 407-415
TL;DR: Clinical features of diseases caused by mutations in SNCA cause cognitive or psychiatric symptoms, parkinsonism, dysautonomia and myoclonus with widespread alpha-synuclein pathology in the central and peripheral nervous system.
About: This article is published in Parkinsonism & Related Disorders.The article was published on 2013-04-01 and is currently open access. It has received 211 citations till now. The article focuses on the topics: Parkinsonism & Parkin.

Summary (4 min read)

Jump to: [Introduction][Dominant PD genes][SNCA][LRRK2][VPS35][EIF4G1][Other dominant and x-linked disorders that may present with parkinsonism][Monogenic disorders with various manifestations that may include parkinsonism][Recessive PD genes][PINK1][DJ1][Aspects common to parkin, PINK1, DJ1][Detailed information about clinical characteristics of carriers of certain mutations in parkin,][Recessive disorders that may include parkinsonism] and [Conclusions]

Introduction

  • The first mutation causing Parkinson's disease (PD) was discovered in the SNCA gene in 1997 [1] .
  • Since then, intensive research efforts have established a total of seven genes containing causal mutations for parkinsonism clinically resembling PD, with autosomal dominant or recessive modes of inheritance.
  • For mutations in at least 19 additional genes, a disease-causing role was postulated (Table 1 ), but subsequent studies either could not confirm that mutations in these genes are associated with parkinsonism or PD, or showed that they in most or all cases cause a clinical phenotype that is clearly distinguishable from PD.
  • This article reviews the present knowledge on these monogenic disorders, with an emphasis on their clinical phenotype and their frequency.

Dominant PD genes

  • Today, there is good evidence that mutations in four dominant PD genes may cause parkinsonism.
  • The first two, SNCA and LRRK2, have been studied in detail, whereas EIF4G1 and VPS35 have only been identified recently.

SNCA

  • Three pathogenic point mutations as well as genomic duplications and triplications are known in the gene encoding alpha-synuclein (SNCA).
  • The family originates from the Basque region in Northern Spain.
  • The severity of the clinical symptoms and the response to levodopa were variable [14] , and studies of mutation carriers without PD symptoms revealed sleep abnormalities [16] and cardiac sympathetic denervation [17] .
  • The A30P and E46K mutations have not been reported from any other family worldwide.
  • The clinical phenotype of PD patients with SNCA mutations (including multiplications) has certain characteristics.

LRRK2

  • In 2004, two groups simultaneously reported the discovery of mutations in the leucine-rich repeat kinase 2 (LRRK2, dardarin) gene in PD [26, 27] .
  • Nevertheless, the large number of PD patients with the LRRK2 G2019S mutation allowed for a clear description of the clinical phenotype attributed to a single mutation in a PD gene, and for statistical analyses [45] .
  • Based on data from 1,045 patients with this mutation, motor symptoms and non-motor symptoms of LRRK2 PD were more benign than those of a control group of patients, for example the risk for dementia was lower [45] .
  • These findings remain uncertain [46] and need to be interpreted in light of the fact that that study's control group consisted of PD patients collected in a brain bank, which may not reflect the average idiopathic PD population.

VPS35

  • The mutation was present in one family each from the United States and Tunisia, and in one family and one sporadic patient of Yemenite Jewish origin [53] .
  • An incomplete neuropathological examination of only parts of the cortex and basal ganglia (but not the brainstem) did not reveal any alphasynuclein immunoreactivity in these areas [54] .
  • Penetrance was incomplete with the oldest reported unaffected carrier at 86 years [53] .

EIF4G1

  • Five mutations in this gene, encoding eukaryotic translation initiation factor 4-gamma 1, were described in PD patients in 2011 [63] .
  • Co-segregation of a mutation with disease could only be demonstrated for the p.R1205H mutation, found initially in a French family and subsequently in patients from the USA, Canada, Ireland, Italy, and Tunisia [63] .
  • The clinical phenotype was that of mild PD with a late age of onset (50-80, mean 64 years) and preserved cognition, but this is based on the few patients described.
  • Concomitant Alzheimer pathology was present in a family with dementia and parkinsonism who had both G686C and R1197W mutations [66] .

Other dominant and x-linked disorders that may present with parkinsonism

  • Trinucleotide expansions in ATXN2 (ataxin-2) or ATXN3 (ataxin-3) usually cause spinocerebellar ataxia that may include parkinsonian features.
  • Men with premutations may develop the fragile X tremor/ataxia syndrome , typically characterized by adult-onset tremor, ataxia, neuropathy, autonomic dysfunction, cognitive decline, behavioral changes with apathy, disinhibition or irritability, and depression.
  • Some of the individuals with pathogenic MAPT mutations present with parkinsonism; signs of frontotemporal dementia may occur years later [73] .
  • The phenotype may resemble PD but there are frequently signs of dystonia as well, such as dystonic tremor [81] .
  • Two patients have been reported who had adult onset PD and TH mutations, but the association remains uncertain, although a pathophysiological connection appears reasonable [82] .

Monogenic disorders with various manifestations that may include parkinsonism

  • Mutations in mitochondrial DNA polymerase gamma (POLG, POLG1) have been reported from patients with parkinsonism, with loss of dopaminergic cells evidenced in DATscans and at least partial response to dopaminergic medication [85, 86] .
  • All these patients also had pronounced additional neurological signs such as progressive external ophthalmoplegia, ataxia, sensory neuropathy or sensorineural hearing loss, or muscle weakness with elevated creatine kinase and mitochondrial myopathy in muscle biopsy, and/or hypogonadism [85] [86] [87] [88] .
  • Most patients with hereditary leukoencephalopathy with spheroids, a disorder caused by mutations in the CSF1R gene, develop parkinsonism during the course of their disease, but parkinsonism is neither the initial nor the only symptom [89] [90] [91] .

Recessive PD genes

  • Recessive inheritance is suggested in families where several members of one generation are affected, especially siblings, but not their parents or their children.
  • Some of these have been published from several groups and have become wellestablished.
  • Others have only been found in one or a few patients, and their significance is difficult to ascertain.

PINK1

  • Homozygous mutations in phosphatase and tensin homolog-induced putative kinase1 (PINK1, PARK6) are associated with early-onset PD [105] .
  • Over 40 point mutations and rarely, large deletions, have been detected [101] .
  • The clinical phenotype seems to be similar to that of parkin mutations, but there are some indications that psychiatric symptoms may occur more commonly among patients with PINK1 mutations [101, 106] .
  • Mutations in PINK1 are rarer than parkin mutations.

DJ1

  • Mutations in oncogene DJ1 (parkinson protein 7, PARK7) are well-established but very rare causes for recessive PD [107] .
  • Only a few patients homozygous for DJ1 mutations have been described.

Aspects common to parkin, PINK1, DJ1

  • Mutations in these three genes are associated with a similar clinical phenotype, which is distinct from the average patient with idiopathic PD.
  • Accompanying non-motor symptoms, if present, remain mild in most cases.
  • Apart from the tendency to develop dyskinesias and dystonia common to all patients with early-onset PD irrespective of genetic background [112] , no specific features reliably distinguish these forms.
  • An important criterion for the pathogenicity of a mutation is that of co-segregation within families, meaning that mutation carriers develop disease whereas their relatives without mutations remain unaffected.
  • Stringent large-scale studies exploring the association of reported mutations with disease have not been performed, and the pathogenicity of a considerable number of mutations in these three genes remains unconfirmed.

Detailed information about clinical characteristics of carriers of certain mutations in parkin,

  • PINK1 and DJ1 is also limited: Although a large number of different mutations are known, each one is comparatively rare.
  • Grouping together patients with different mutations in the same gene may overcome this problem but has limitations when different biological effects of the various mutations are assumed.
  • It has been suggested that certain mutations cause early-onset PD when they are present on both alleles, but cause late-onset PD in heterozygote carriers [115] .
  • The overall frequency of mutations in these three genes is lower than previously estimated; a systematic review of publications covering more than 5,800 EOPD patients reported proportions of 8.6% with mutations in parkin, 3.7% in PINK1 and 0.4% in DJ1 [103] .

Recessive disorders that may include parkinsonism

  • Mutations in ATPase type 13A2 (ATP13A2; PARK9) were found to cause the rare Kufor-Rakeb syndrome in a Chilean family.
  • ATP13A2 mutations appear to be exceedingly rare.
  • Both are severe neuro-pediatric disorders that bear no resemblance to PD.
  • Three years later, mutations in this gene were reported from patients who also developed what was called adult-onset levodopa-responsive dystonia-parkinsonism [125, 126] .

Conclusions

  • The genetic causes of a considerable number of monogenic disorders with parkinsonism are known today.
  • In most populations, the known pathogenic mutations are exceptionally rare, and can only explain a very minor part [8, 24, 44, 103, 132] of the estimated 10% of PD patients with one or more affected first-degree relatives [133] .
  • In general, the probability to find a pathogenic mutation in a given patient with parkinsonism remains low [44, 103, 132] , but varies widely, depending on factors including the patient's age at onset, family history, origin, and clinical phenotype.
  • Table 4 shows which genetic tests may be useful.
  • Clinical genetic analysis should only be performed when adequate genetic counseling before, during and after testing can be provided.

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Journal ArticleDOI
iPSC modeling of young-onset Parkinson's disease reveals a molecular signature of disease and novel therapeutic candidates.

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Laperle Alexander1, Samuel Sances1, Yucer Nur1, Victoria Dardov1, Veronica J. Garcia1, Ritchie Ho1, A. N. Fulton1, Matthew Jones1, K. M. Roxas1, Pablo Avalos1, D. West1, Maria G. Banuelos1, Zhan Shu2, Ramachandran Murali1, N. T. Maidment2, J. E. Van Eyk1, M. Tagliati1, Clive N. Svendsen1 
Cedars-Sinai Medical Center1, Semel Institute for Neuroscience and Human Behavior2
27 Jan 2020-Nature Medicine
TL;DR: iPSC-derived midbrain dopaminergic neurons from patients with young-onset Parkinson’s disease exhibit molecular abnormalities, including elevated α-synuclein and lysosomal dysfunction, which can be normalized with phorbol ester treatment.
Abstract: Young-onset Parkinson's disease (YOPD), defined by onset at <50 years, accounts for approximately 10% of all Parkinson's disease cases and, while some cases are associated with known genetic mutations, most are not. Here induced pluripotent stem cells were generated from control individuals and from patients with YOPD with no known mutations. Following differentiation into cultures containing dopamine neurons, induced pluripotent stem cells from patients with YOPD showed increased accumulation of soluble α-synuclein protein and phosphorylated protein kinase Cα, as well as reduced abundance of lysosomal membrane proteins such as LAMP1. Testing activators of lysosomal function showed that specific phorbol esters, such as PEP005, reduced α-synuclein and phosphorylated protein kinase Cα levels while increasing LAMP1 abundance. Interestingly, the reduction in α-synuclein occurred through proteasomal degradation. PEP005 delivery to mouse striatum also decreased α-synuclein production in vivo. Induced pluripotent stem cell-derived dopaminergic cultures reveal a signature in patients with YOPD who have no known Parkinson's disease-related mutations, suggesting that there might be other genetic contributions to this disorder. This signature was normalized by specific phorbol esters, making them promising therapeutic candidates.

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Clinical and demographic factors and outcome of amyotrophic lateral sclerosis in relation to population ancestral origin.

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Benoît Marin, Giancarlo Logroscino1, Farid Boumediene2, Farid Boumediene3, Anaïs Labrunie2, Philippe Couratier3, Philippe Couratier2, Marie Claude Babron2, Marie Claude Babron4, Anne-Louise Leutenegger4, Anne-Louise Leutenegger2, Pierre-Marie Preux3, Pierre-Marie Preux2, Ettore Beghi5 
University of Bari1, French Institute of Health and Medical Research2, Centre national de la recherche scientifique3, Paris Diderot University4, Mario Negri Institute for Pharmacological Research5
01 Mar 2016-European Journal of Epidemiology
TL;DR: A systematic review and meta-analysis of the literature concerning differences in phenotype and outcome of ALS that relate to PAO sets the scene for a collaborative study involving a wide international consortium to investigate the link between ancestry, environment, and ALS phenotype.
Abstract: To review how the phenotype and outcome of amyotrophic lateral sclerosis (ALS) change with variations in population ancestral origin (PAO). Knowledge of how PAO modifies ALS phenotype may provide important insight into the risk factors and pathogenic mechanisms of the disease. We performed a systematic review and meta-analysis of the literature concerning differences in phenotype and outcome of ALS that relate to PAO. A review of 3111 records identified 78 population-based studies. The 40 that were included covered 40 geographical areas in 10 subcontinents. Around 12,700 ALS cases were considered. The results highlight the phenotypic heterogeneity of ALS at time of onset [age, sex ratio (SR), bulbar onset], age at diagnosis, occurrence of comorbidities in the first year after diagnosis, and outcome (survival). Subcontinent is a major explanatory factor for the variability of the ALS phenotype in population-based studies. Some markers of ALS phenotype were homogeneously distributed in western countries (SR, mean age at onset/diagnosis) but their distributions in other subcontinents were remarkably different. Other markers presented variations in European subcontinents (familial ALS, bulbar onset) and in other continents. As a consequence, ALS outcome strongly varied, with a median survival time from onset ranging from 24 months (Northern Europe) to 48 months (Central Asia). This review sets the scene for a collaborative study involving a wide international consortium to investigate, using a standard methodology, the link between ancestry, environment, and ALS phenotype.

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Limelight on alpha-synuclein: pathological and mechanistic implications in neurodegeneration.

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Pauline Wales1, Raquel Pinho1, Diana F. Lázaro1, Tiago F. Outeiro1
University of Göttingen1
01 Jan 2013-Journal of Parkinson's disease
TL;DR: Detailed understanding of the biology/pathobiology of ASYN may enable the development of novel avenues for diagnosis and/or therapeutic intervention in synucleinopathies.
Abstract: The pathogenesis of many neurodegenerative disorders arises in association with the misfolding and accumulation of a wide variety of proteins. Much emphasis has been placed on understanding the nature of these protein accumulations, including their composition, the process by which they are formed and the physiological impact they impose at cellular and, ultimately, organismal levels. Alpha-synuclein (ASYN) is the major component of protein inclusions known as Lewy bodies and Lewy neurites, which are the typical pathological hallmarks in disorders referred to as synucleinopathies. In addition, mutations or multiplications in the gene encoding for ASYN have also been shown to cause familial cases of PD, the most common synucleinopathy. Although the precise function of ASYN remains unclear, it appears to be involved in a vast array of cellular processes. Here, we review, in depth, a spectrum of cellular and molecular mechanisms that have been implicated in synucleinopathies. Importantly, detailed understanding of the biology/pathobiology of ASYN may enable the development of novel avenues for diagnosis and/or therapeutic intervention in synucleinopathies.

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TL;DR: The structure-activity relationships (SAR) within a novel series of highly selective USP30 inhibitors are disclosed and it is shown that MF-094 increases protein ubiquitination and accelerates mitophagy.

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TL;DR: In this article, the α-synuclein was identified as the major component of Lewy bodies, the pathological hallmark of Parkinson's disease, and of glial cell cytoplasmic inclusions.
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Mike Hutton1, Corinne Lendon2, Patrizia Rizzu3, Matt Baker1, Susanne Froelich4, Susanne Froelich3, Henry Houlden1, Stuart Pickering-Brown, Sumitra Chakraverty2, Adrian M. Isaacs1, Andrew Grover1, J. Hackett1, Jennifer Adamson1, Sarah Lincoln1, Dennis W. Dickson1, Peter Davies5, Ronald C. Petersen1, M. Stevens3, E. De Graaff1, E. Wauters3, J. Van Baren1, M. Hillebrand3, Marijke Joosse3, J. M. Kwon2, Petra Nowotny2, Lien Kuei Che2, Joanne Norton2, John C. Morris2, L. A. Reed6, John Q. Trojanowski6, Hans Basun4, Lars Lannfelt4, M. Neystat7, Stanley Fahn7, Frances Dark, Tony Tannenberg8, Peter R. Dodd9, Nicholas K. Hayward10, John B.J. Kwok11, Peter R. Schofield11, Athena Andreadis, Julie S. Snowden, David Craufurd, David Neary12, F. Owen13, Ben A. Oostra3, John Hardy1, Alison Goate2, J. C. van Swieten1, David M. A. Mann, Timothy Lynch7, Peter Heutink3 
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18 Jun 1998-Nature
TL;DR: In this paper, the authors sequenced tau in FTDP-17 families and identified three missense mutations (G272V, P301L and R406W) and three mutations in the 5' splice site of exon in
Abstract: Thirteen families have been described with an autosomal dominantly inherited dementia named frontotemporal dementia and parkinsonism linked to chromosome 17 (FTDP-17)(1-9), historically termed Pick's disease(10) Most FTDP-17 cases show neuronal and/or glial inclusions that stain positively with antibodies raised against the microtubule-associated protein Tau, although the Tau pathology varies considerably in both its quantity (or severity) and characteristics(1-8,12) Previous studies have mapped the FTDP-17 locus to a 2-centimorgan region on chromosome 17q2111; the tau gene also lies within this region We have now sequenced tau in FTDP-17 families and identified three missense mutations (G272V, P301L and R406W) and three mutations in the 5' splice site of exon in The splice-site mutations all destabilize a potential stem-loop structure which is probably involved in regulating the alternative splicing of exon10 (ref 13) This causes more frequent usage of the 5' splice site and an increased proportion of tan transcripts that include exon 10 The increase in exon 10(+) messenger RNA will increase the proportion of Tau containing four microtubule-binding repeats, which is consistent with the neuropathology described in several families with FTDP-17 (refs 12, 14)

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"Monogenic Parkinson's disease and p..." refers background in this paper

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Frequently Asked Questions (12)
Q1. What are the contributions mentioned in the paper "Monogenic parkinson’s disease and parkinsonism: clinical phenotypes and frequencies of known mutations" ?

This review summarizes the clinical features of diseases caused by mutations in 

More than 100 different parkin mutations have been reported from PD patients, including copy number variations (deletions, insertions, multiplications), missense and truncating mutations [101]. 

In a recently published international multicenter study, only 49 of 8,371 (0.58%) PD patients of European and Asian origin carried a LRRK2 G2019S mutation [44]. 

Other studies found homozygous or compound heterozygous parkin mutations in a lower percentage of patients with early onset-PD (before 40 or 45 years), ranging from 8.2% in Italy, 2.7% in Korea, 2.5% in Poland, to 1.4% in Australia [8, 98-100]. 

In rare patients, parkinsonism has been the presenting or predominant clinical manifestation of GRN mutation [77], but mutations in MAPT or GRN are not considered a major cause of familial parkinsonism, especially in the absence of other clinical signs and symptoms. 

In families with recessive patterns of inheritance, cosegregation analysis is often limited to a few siblings, but siblings have a 25% chance probability to have inherited the identical allele. 

12Puschmann: Review monogenic PDFeatures common to patients with parkin mutations and PD, aside from young or very young age at onset, are probably a good and lasting effect of levodopa, albeit with the occurrence of dyskinesias during the disease course, and a lower risk for non-motor symptoms such as cognitive decline and dysautonomia [102]. 

The phenotypes caused by mutations in SNCA or the recessive PD genes (parkin, PINK1, DJ1) represent characteristic subtypes of PD. 

Given the prevalence of D620N of 0.14% among PD patients in the two initial studies and of 0.4% in the multicentre study [58], and the fact that replication studies in Belgium [61] or China [62] have not identified additional cases, this mutation is rare. 

Late-onset PD was reported in the Austrian family, one member had only developed depression and tremor with a pathological DATscan indicating incipient PD [55]. 

Genetic testing can today be offered to a subset of patients with unusually young onset, dominant inheritance, and/or a clinical phenotype suggesting a defined monogenic form of parkinsonism. 

Carriers of mutations in the other genes may develop parkinsonism with or without additional symptoms, but rarely a disease resembling PD.