Helen Latsoudis

LRRK2 mutations on Crete: R1441H associated with PD evolving to PSP.

Mutations of the LRRK2 gene that encodes the protein dardarin occur in Parkinson disease (PD)1 with the G2019S change being the most common cause of hereditary parkinsonism. While the G2019S mutation phenotype is that of typical PD,2 three different amino acid substitutions at residue 1441 (4322G>A: [R1441H], 4321C>T: [R1441C], 4321C>G: [R1441G]) have been associated with pleomorphic phenotypic expressions.3 There is evidence, however, that not all LRRK2 mutations are sufficient to cause PD and that additional genetic or environmental factors may be involved. An oligogenic inheritance for PD has also been suggested in a study of 247 index patients with PD from Crete.4 Here we searched for susceptibility genes to PD in our cohort of 266 cases with PD and 13 patients with progressive supranuclear palsy (PSP) by testing them for LRRK2 mutations. PD was diagnosed by established criteria.4 PSP was diagnosed by the National Institute of Neurologic Disorders and Stroke–SPSP criteria, requiring early postural instability and falls, vertical supranuclear palsy, pseudobulbar palsy, and akinetic-rigid parkinsonism (with prominent axial rigidity) unrelieved by levodopa. Controls (n = 300) were healthy subjects natives of Crete. All patients and controls were analyzed for five LRRK2 …

Patients with horizontal gaze palsy and progressive scoliosis due to ROBO3 E319K mutation have both uncrossed and crossed central nervous system pathways and perform normally on neuropsychological testing

Background: Horizontal gaze palsy and progressive scoliosis (HGPPS) is caused by mutations of the ROBO3 gene, which encodes a receptor associated with axonal guidance during development. Although there is evidence for uncrossed cuneatal and corticospinal tracts in HGPPS, it is unclear whether other central nervous system pathways are involved. Objective: To study two patients with HGPPS homozygotic for the ROBO3 E319K mutation using a variety of neurophysiological and neuropsychological tests. Methods: A battery of neuropsychological tests was applied to assess various cognitive and perceptual functions. The corticospinal, somatosensory and auditory pathways were evaluated using appropriate neurophysiological tests. To access motor pathways to the neck muscles, electromyographic recordings were obtained from the sternocleidomastoideus and splenius capitis muscle during active head rotation. Results: Both patients performed normally on manual dexterity, complex sensory and visuospatial functions, reading and general intelligence tests. Motor evoked potentials in both patients showed uncrossed corticospinal tracts for the extremities, although in one patient, electromyography indicated pyramidal tract crossing for the neck muscles. Although somatosensory evoked potentials showed uncrossed somatosensory fibres subserving proprioception and light touch, right median nerve somatosensory evoked potential in one patient indicated a partial lemniscal crossing. Sympathetic skin response and blink reflex showed a midline crossing of the spinothalamic and quintothalamic tracts. Brain stem auditory evoked potentials indicated a lack of crossing in the level of the trapezoid body. Conclusions: Our patients with the ROBO3 E319Κ mutation show normal perceptual and cognitive functions and have both crossed and uncrossed motor, sensory and auditory pathways.

The human GLUD2 glutamate dehydrogenase and its regulation in health and disease

Whereas glutamate dehydrogenase in most mammals (hGDH1 in the human) is encoded by a single functional GLUD1 gene expressed widely, humans and other primates have acquired through retroposition an X-linked GLUD2 gene that encodes a highly homologous isoenzyme (hGDH2) expressed in testis and brain. Using an antibody specific for hGDH2, we showed that hGDH2 is expressed in testicular Sertoli cells and in cerebral cortical astrocytes. Although hGDH1 and hGDH2 have similar catalytic properties, they differ markedly in their regulatory profile. While hGDH1 is potently inhibited by GTP and may be controlled by the need of the cell for ATP, hGDH2 has dissociated its function from GTP and may metabolize glutamate even when the Krebs cycle generates GTP amounts sufficient to inactivate hGDH1. As astrocytes are known to provide neurons with lactate that largely derives from the Krebs cycle via conversion of glutamate to α-ketoglutarate, the selective expression of hGDH2 may facilitate metabolic recycling processes essential for glutamatergic transmission. As there is evidence for deregulation of glutamate metabolism in degenerative neurologic disorders, we sequenced GLUD1 and GLUD2 genes in neurologic patients and found that a rare T1492G variation in GLUD2 that results in substitution of Ala for Ser445 in the regulatory domain of hGDH2 interacted significantly with Parkinsons disease (PD) onset. Thus, in two independent Greek and one North American PD cohorts, Ser445Ala hemizygous males, but not heterozygous females, developed PD 6-13 years earlier than subjects with other genotypes. The Ala445-hGDH2 variant shows enhanced catalytic activity that is resistant to modulation by GTP, but sensitive to inhibition by estrogens. These observations are thought to suggest that enhanced glutamate oxidation by the Ala445-hGDH2 variant accelerates nigral cell degeneration in hemizygous males and that inhibition of the overactive enzyme by estrogens protects heterozygous females. We then evaluated the interaction of estrogens and neuroleptic agents (haloperidol and perphenazine) with the wild-type hGDH1 and hGDH2 and found that both inhibited hGDH2 more potently than hGDH1 and that the evolutionary Arg443Ser substitution was largely responsible for this sensitivity. Hence, the properties acquired by hGDH2 during its evolution have made the enzyme a selective target for neuroactive steroids and drugs, providing new means for therapeutic interventions in disorders linked to deregulation of this enzyme.

Gain-of-function variant in GLUD2 glutamate dehydrogenase modifies Parkinson's disease onset

Parkinsons disease (PD), a common neurodegenerative disorder characterized by progressive loss of dopaminergic neurons and their terminations in the basal ganglia, is thought to be related to genetic and environmental factors. Although the pathophysiology of PD neurodegeneration remains unclear, protein misfolding, mitochondrial abnormalities, glutamate dysfunction and/or oxidative stress have been implicated. In this study, we report that a rare T1492G variant in GLUD2, an X-linked gene encoding a glutamate dehydrogenase (a mitochondrial enzyme central to glutamate metabolism) that is expressed in brain (hGDH2), interacted significantly with age at PD onset in Caucasian populations. Individuals hemizygous for this GLUD2 coding change that results in substitution of Ala for Ser445 in the regulatory domain of hGDH2 developed PD 6–13 years earlier than did subjects with other genotypes in two independent Greek PD groups and one North American PD cohort. However, this effect was not present in female PD patients who were heterozygous for the DNA change. The variant enzyme, obtained by substitution of Ala for Ser445, showed an enhanced basal activity that was resistant to GTP inhibition but markedly sensitive to modification by estrogens. Thus, a gain-of-function rare polymorphism in hGDH2 hastens the onset of PD in hemizygous subjects, probably by damaging nigral cells through enhanced glutamate oxidative dehydrogenation. The lack of effect in female heterozygous PD patients could be related to a modification of the overactive variant enzyme by estrogens.

Haplotype analysis of Lrrk2 R1441H carriers with parkinsonism

The Roc domain of the Lrrk2 protein harbors two pathogenic mutations which cause autosomal dominant parkinsonism (R1441C and R1441G). A third putatively pathogenic variant (R1441H) has been identified in four probands of diverse ethnicity with parkinsonism. Herein we show that the R1441H substitutions lie on different haplotypes within our patients, confirming this codon as a mutational hotspot. The absence of this variant in control subjects and the presence of two other pathogenic variants at this amino acid position collectively support the contention that R1441H is a pathogenic substitution.

The human GLUD2 glutamate dehydrogenase: Localization and functional aspects

In all mammals, glutamate dehydrogenase (GDH), an enzyme central to the metabolism of glutamate, is encoded by a single gene (GLUD1 in humans) which is expressed widely (housekeeping). Humans and other primates also possess a second gene, GLUD2, which encodes a highly homologous GDH isoenzyme (hGDH2) expressed predominantly in retina, brain and testis. There is evidence that GLUD1 was retro-posed <23 million years ago to the X chromosome, where it gave rise to GLUD2 through random mutations and natural selection. These mutations provided the novel enzyme with unique properties thought to facilitate its function in the particular milieu of the nervous system. hGDH2, having been dissociated from GTP control (through the Gly456Ala change), is mainly regulated by rising levels of ADP/l-leucine. To achieve full-range regulation by these activators, hGDH2 needs to set its basal activity at low levels (<10% of full capacity), a property largely conferred by the evolutionary Arg443Ser change. Studies of structure/function relationships have identified residues in the regulatory domain of hGDH2 that modify basal catalytic activity and regulation. In addition, enzyme concentration and buffer ionic strength can influence basal enzyme activity. While mature hGDH1 and hGDH2 isoproteins are highly homologous, their predicted leader peptide sequences show a greater degree of divergence. Study of the subcellular sites targeted by hGDH2 in three different cultured cell lines using a GLUD2/EGFP construct revealed that hGDH2 localizes mainly to mitochondria and to a lesser extent to the endoplasmic reticulum of these cells. The implications of these findings for the potential role of this enzyme in the biology of the nervous system in health and disease are discussed.

Mitochondrial DNA polymorphisms and haplogroups in Parkinson's disease and control individuals with a similar genetic background

AbstractMitochondrial complex I deficiency has been implicated in the pathogenesis of Parkinsons disease (PD), but as yet no mitochondrial DNA (mtDNA) variations have been identified that could account for the impaired complex I activity. On the other hand, it has been suggested that mtDNA polymorphisms (mtSNPs) or haplogroups may modify the risk of developing PD. Here, we determined the distributions of ten mtSNPs that define the nine major European haplogroups among 224 PD patients and 383 controls from Crete, an island of 0.6 million inhabitants who share a similar genetic background and a common environment. The recruitment of patients and controls was restricted to individuals of Cretan origin for at least three generations from both parental sides in order to avoid population admixture and subsequent genetic heterogeneity. We found no mtSNP or mtDNA haplogroup that predisposes to PD, although there was a trend for haplogroups J, T, U and I and the supercluster of haplogroups UKJT to be slightly underrepresented in our PD patients as compared to controls. While a combination of common mtSNPs (present in ≥5% of the general population) may decrease the chance of developing PD, this effect was minor in the Cretan population.

Novel mutation of the PRNP gene of a clinical CJD case

BackgroundTransmissible spongiform encephalopathies (TSEs), a group of neurodegenerative diseases, are thought to be caused by an abnormal isoform of a naturally occurring protein known as cellular prion protein, PrPC. The abnormal form of prion protein, PrPSc accumulates in the brain of affected individuals. Both isoforms are encoded by the same prion protein gene (PRNP), and the structural changes occur post-translationally. Certain mutations in the PRNP gene result in genetic TSEs or increased susceptibility to TSEs.Case presentationA 70 year old woman was admitted to the hospital with severe confusion and inability to walk. Relatives recognized memory loss, gait and behavioral disturbances over a six month period prior to hospitalization. Neurological examination revealed Creutzfeldt-Jakob disease (CJD) related symptoms such as incontinence, Babinski sign and myoclonus. EEG showed periodic sharp waves typical of sporadic CJD and cerebrospinal fluid analysis (CSF) was positive for the presence of the 14-3-3-protein. As the disease progressed the patient developed akinetic mutism and died in the tenth month after onset of the disease symptoms. Unfortunately, no autopsy material was available. PRNP sequencing showed the occurrence of a point mutation on one allele at codon 193, which is altered from ACC, coding for a threonine, to ATC, encoding an isoleucine (T193I).ConclusionHere we report a novel mutation of the PRNP gene found in an elderly female patient resulting in heterozygosity for isoleucine and threonine at codon 193, in which normally homozygosity for threonine is expected (T193). The patient presented typical clinical symptoms of CJD. EEG findings and the presence of the 14-3-3 protein in the CSF, contributed to CJD diagnosis, allowing the classification of this case as a probable CJD according to the World Health Organization (WHO) accepted criteria.

Mutations in human GLUD2 glutamate dehydrogenase affecting basal activity and regulation

Glutamate dehydrogenase (GDH) in human exists in GLUD1 and GLUD2 gene‐encoded isoforms (hGDH1 and hGDH2, respectively), differing in their regulation and tissue expression pattern. Whereas hGDH1 is subject to GTP control, hGDH2 uses for its regulation, a novel molecular mechanism not requiring GTP. This is based on the ability of hGDH2 to maintain a baseline activity of <10% of its capacity subject to full activation by rising ADP/l‐leucine levels. Here we studied further the molecular mechanisms regulating hGDH2 function by creating and analyzing hGDH2 mutants harboring single amino acid substitutions in the regulatory domain (antenna, pivot helix) of the protein. Five hGDH2 mutants were obtained: two with an amino acid change (Gln441Arg, Ser445Leu) in the antenna, two (Lys450Glu, His454Tyr) in the pivot helix, and one (Ser448Pro) in the junction between the two structures. Functional analyses revealed that, while the antenna mutations increased basal enzyme activity without affecting its allosteric properties, the pivot helix mutations drastically reduced basal activity and impaired enzyme regulation. On the other hand, the Ser448Pro mutation reduced basal activity but did not alter allosteric regulation. Also, compared with wild‐type hGDH2, the antenna mutants were relatively thermostable, whereas the pivot helix mutants were extremely heat labile. Hence, the present data further our understanding of the molecular mechanisms involved in the function and stability of hGDH2, an enzyme thought to be of importance for nerve tissue biology.

Differential Expression of miR-4520a Associated With Pyrin Mutations in Familial Mediterranean Fever (FMF)

Familial Mediterranean fever (FMF) is an autosomal recessive disease characterized by recurrent, acute, and self‐limiting attacks of fever. Mutations in MEFV gene encoding pyrin account for FMF, but the high number of heterozygote patients with typical symptoms of the disease has driven a number of alternative aetiopathogenic hypotheses. The MEFV gene was knocked down in human myelomonocytic cells that express endogenous pyrin to identify deregulated microRNAs (miRNAs). Microarray analyses revealed 29 significantly differentially expressed miRNAs implicated in pathways associated with cellular integrity and survival. Implementation of in silico gene network prediction algorithms and bioinformatics analyses showed that miR‐4520a is predicted to target genes implicated in autophagy through regulation of RHEB/mTOR signaling. Differential expression levels of RHEB were confirmed by luciferase reporter gene assays providing further evidence that is directly targeted by miR‐4520a. Although the relative expression levels of miR‐4520a were variable among FMF patients, the statistical expression of miR‐4520a was different between FMF mutation carriers and controls (P = 0.0061), indicating an association between miR‐4520a expression and MEFV mutations. Comparison between FMF patients bearing the M694V mutation, associated with severe disease, and healthy controls showed a significant increase in miR‐4520a expression levels (P = 0.00545). These data suggest that RHEB, the main activator of mTOR signaling, is a valid target of miR‐4520a with the relative expression levels of the latter being significantly deregulated in FMF patients and highly dependent on the presence of pyrin mutations, especially of the M694V type. These results suggest a role of deregulated autophagy in the pathogenesis of FMF. J. Cell. Physiol. 232: 1326–1336, 2017.