Correction:Comprehensive genetic screening of early-onset dementia patients in an Austrian cohort-suggesting new disease-contributing genes (Human Genomics, (2023), 17, 1, (55), 10.1186/s40246-023-00499-z)

Following publication of the original article [1], the authors reported an error in Table 1. The correct Table 1 has been provided in this Correction. (Table presented.) Basic clinical and genetic characteristics of all 60 EOD patients ID Diagnosis AAO (years) Sex FH APOE Gene Variant Position Transcript CADD ClinVar Significance for disease EOD-1 EOD-2 c.184G &gt; A; p.R62C chr6:41129208-41129208 NM_001271821.1 25.5 n.r Risk modifier Risk modifier EOD-3 AD 45 f 2 E3/E3 EOD-4 AD 51 f 4 E4/E3 Risk modifier EOD-5 nfPPA 58 f 2 E3/E2 EOD-6 AD 56 f 3 E3/E3 EOD-7 AD/PCA 56 f 4 E3/E3 EOD-8 bvFTD 56 m 4 E3/E3 c.1427T &gt; C; p.M476T chr11:117160361-117160361 NM_012104.3 26.4 n.r Unknown c.9757A &gt; G; p.S3253G chr15:62173781-62173781 NM_020821.2 29.5 n.r Unknown EOD-9 AD 55 f 3,5 E4/E3 Risk modifier EOD-10 AD 58 f 3,5 E3/E3 EOD-11 AD 63 m 4 E3/E3 EOD-12 mixed dementia (AD + VD) 55 m 3,5 E4/E3 Risk modifier EOD-13 AD 61 m 4,5 E3/E3 EOD-14 AD/lpPPA 61 m 4 E4/E3 Risk modifier c.4300C &gt; T; p.V1434I chr15:62244179-62244179 NM_020821.2 24.8 n.r Unknown EOD-15 nfPPA 64 m 2 E3/E3 c.2218C &gt; T; p.E740K chr2:74594514-74594514 NM_004082.4 24.0 n.r Unknown EOD-16 AD 56 f 4 E3/E3 EOD-17 AD (PD) 60 m 1 E4/E3 Risk modifier g.chr16:1816528 A &gt; G; c.2817-2A &gt; G chr16:1816528-1816528 NM_015133.3 22.3 n.r Unknown EOD-18a c.2914C &gt; T; p.P972S chr19:1051537-1051537 NM_019112.3 25.3 n.r Potential risk modifier EOD-19 EOD-19 (2)b EOD-20 AD 57 m 4,5 E3/E3 c.7397T &gt; A; p.L2466H chr12:40760814-40760814 NM_198578.3 25.7 VUS Unknown EOD-21 EOD-22 EOD-23 EOD-24 EOD-25 EOD-26 AD 56 f 4 E3/E3 c.2980G &gt; C; p.P994A chr2:74590268-74590268 NM_023019.3 17.3 VUS Unknown c.2087G &gt; A; p.R696H chr16:1814180-1814180 NM_015133.3 31.0 n.r Unknown EOD-27 AD 57 f 4 E4/E3 Risk modifier EOD-28 AD 54 m 4 E3/E3 EOD-29 AD 54 m 4 E3/E3 EOD-30 AD 64 m 4 E3/E3 EOD-31 mixed dementia (AD + VD) 58 m 3,5 E3/E3 EOD-32 FTD/svPPA 61 m 4 E3/E3 EOD-33 AD 62 f 4,5 E4/E3 Risk modifier c.521G &gt; A; p.S174L chr2:74598788-74598788 NM_004082.4 24.4 VUS Unknown EOD-34 AD 59 f 2 E4/E3 Risk modifier EOD-35 AD 55 m 3,5 E4/E3 Risk modifier EOD-36c AD 64 m 2 E4/E3 c.140G &gt; A; p.R47H chr6:41129252-41129252 NM_018965.3 9.7 LB Risk modifier Risk modifier EOD-37 AD 52 f 3,5 E3/E3 c.7397T &gt; A; p.L2466H chr12:40760814-40760814 NM_198578.3 25.7 VUS Unknown EOD-38 AD 52 f 3,5 E4/E3 Risk modifier EOD-39 AD 63 f 3 E4/E3 Risk modifier EOD-40 AD 55 f 4 E4/E3 Risk modifier EOD-41 AD 58 m 3,5 E3/E3 EOD-42 AD 39 m 4 E3/E2 EOD-43 AD 63 m 4 E3/E3 c.3148A &gt; G; p.I1050V chr15:62256964-62256964 NM_020821.2 0.001 VUS Unknown EOD-44 AD/lpPPA 58 f 3,5 E3/E3 c.3014T &gt; G; p.M1005R chr11:121430331-121430331 NM_003105.5 27.9 n.r Potential risk modifier EOD-45 AD 65 m 4 E3/E3 EOD-46 CBS + AD 51 f 3,5 E3/E3 c.4606G &gt; A; p.G1536S chr11:121474988-121474988 NM_003105.5 25.2 B Risk modifier EOD-47 AD 54 f 4 E3/E3 EOD-48 bvFTD 57 m 4 E3/E3 EOD-49 FTD/nfPPA + ALS 58 m 4 E3/E3 c.986T &gt; C; p.L276P chr12:64875636-64875636 NM_013254.3 n.r Potential risk modifier c.7436T &gt; C; p.I2429T chr15:62212307-62212307 NM_020821.2 n.r Unknown EOD-50 Risk modifier EOD-51 FTD/svPPA 62 f 4 E3/E3 EOD-52 AD 57 m 4 E4/E3 Risk modifier EOD-53 c.7377G &gt; A; p.M2459I chr12:40758839-40758839 NM_198578.3 17.7 n.r Unknown EOD-54 AD 59 m 1 E4/E3 Risk modifier EOD-55 AD 49 m 4 E3/E3 EOD-56 AD 61 m 3,5 E3/E3 EOD-57 AD/lpPPA 57 f 4 E3/E3 EOD-58 AD + VD 64 f 3 E3/E3 c.823C &gt; T; p.R141C chr2:74598126-74598126 NM_004082.3 29.3 VUS Unknown EOD-59 bvFTD 52 m 4 E4/E3 Risk modifier EOD-60 a, EOD-18: The APP duplication of was confirmed to be 'de novo'. Both parents did not show this duplication b, EOD-19 (2) is the brother of EOD19. He was also affected by AD and carrier of the same duplication. EOD 19 (2) was not included in the analyses of AAO and FH c, EOD-36: ClinVar assessment of TREM2 p.R47H of LB (likely benign) refers to Nasu-Hakola disease. However, p.R47H is an established risk variant for dementia (Ref. 15) The original article [1] has been corrected.</p

The Parkinson's disease VPS35[D620N] mutation enhances LRRK2 mediated Rab protein phosphorylation in mouse and human

Missense mutations in the LRRK2 and VPS35 genes result in autosomal dominant Parkinson’s disease. The VPS35 gene encodes for the cargo-binding component of the retromer complex, while LRRK2 modulates vesicular trafficking by phosphorylating a subgroup of Rab proteins. Pathogenic mutations in LRRK2 increase its kinase activity. It is not known how the only thus far described pathogenic VPS35 mutation, [D620N] exerts its effects. We reveal that the VPS35[D620N] knock-in mutation, strikingly elevates LRRK2 mediated phosphorylation of Rab8A, Rab10 and Rab12 in mouse embryonic fibroblasts. The VPS35[D620N] mutation also increases Rab10 phosphorylation in mouse tissues (lung, kidney, spleen and brain). Furthermore, LRRK2 mediated Rab10 phosphorylation is increased in neutrophils as well as monocytes isolated from three Parkinson’s patients with a heterozygous VPS35[D620N] mutation compared to healthy donors and idiopathic Parkinson’s patients. LRRK2 mediated Rab10 phosphorylation is significantly suppressed by knock-out or knock-down of VPS35 in wild type, LRRK2[R1441C] or VPS35[D620N] cells. Finally, VPS35[D620N] mutation promotes Rab10 phosphorylation more potently than LRRK2 pathogenic mutations. Available data suggest that Parkinson’s patients with VPS35[D620N] develop the disease at a younger age than those with LRRK2 mutations. Our observations indicate that VPS35 controls LRRK2 activity and that the VPS35[D620N] mutation results in a gain of function, potentially causing Parkinson’s disease through hyperactivation of the LRRK2 kinase. Our findings suggest that it may be possible to elaborate compounds that target the retromer complex to suppress LRRK2 activity. Moreover, patients with VPS35[D620N] associated Parkinson’s might benefit from LRRK2 inhibitor treatment that have entered clinical trials in humans

Elevated urine BMP phospholipids in LRRK2 and VPS35 mutation carriers with and without Parkinson's disease

Participant demographic and clinical characteristics, and urine BMP phospholipid levels. For each participant, sample collection site is provided as: BCN (Barcelona), VIE (Vienna), DND (Dundee), or SSB (San Sebastian). Also provided are age at study participation, age at PD diagnosis (where applicable), sex (M, for male, and F, for female), experimental group (control, iPD –idiopathic PD –, LRRK2 G2019S, LRRK2 R1441G/C, VPS35 D620N, GBA, or other), and PD status (NMC for non-manifesting mutation carriers, or PD). Values for all measured BMP species presented as ng of BMP per mg of creatinine are provided. Additionally, urine creatinine (mg/ml) and non-normalized BMP levels are provided. BQL designates BMP levels that were below quantification level and NM designates values that were not measured for a particular individual

C9orf72 repeat length might influence clinical sub-phenotypes in dementia patients

Background: C9orf72 repeat expansions have been observed in a wide variety of neurodegenerative disorders. The cut-off between normal and pathogenic alleles is not well established as repeat sizing methods are often semi-quantitative. However, intermediate alleles might influence disease prevalence and phenotype, as seen for other repeat expansion disorders. We aimed to further delineate the prevalence of small, intermediate and expanded C9orf72 alleles and elucidate their potential influence on the disease phenotype. Methods: DNA derived from patients (n = 1804) and healthy individuals (n = 643) was obtained from multiple collectives in Austria. Genotyping was performed using a two-step PCR assay followed by Southern blotting. Results: 3.4% of clinically diagnosed frontotemporal dementia (FTD; n = 5/147) cases and 0.8% of clinically diagnosed Alzheimer's disease (AD; n = 5/602) cases were carriers of a pathological C9orf72 repeat expansion. A significantly earlier disease onset was detected in expansion carriers compared to non-carriers in the FTD and AD cohorts (median 50 years, range 39–64 vs. median 64 years, range 36–92, p = 0.018 and median 63 years, range 54–71 vs. median 74 years, range 45–92, p = 0.006, respectively). C9orf72 intermediate alleles were significantly associated with cerebellar symptoms (p = 0.0004) and sensory deficits in the dementia cohort (p = 0.01). Conclusions: C9orf72 repeat expansion carriers showed earlier disease onset compared to non-carriers with clinical diagnosis of FTD and AD. Furthermore, C9orf72 intermediate repeats might modify the phenotypic expression in dementia

TPP2 mutation associated with sterile brain inflammation mimicking MS

Objective To ascertain the genetic cause of a consanguineous family from Syria suffering from a sterile brain inflammation mimicking a mild nonprogressive form of MS. Methods We used homozygosity mapping and next-generation sequencing to detect the disease-causing gene in the affected siblings. In addition, we performed RNA and protein expression studies, enzymatic activity assays, immunohistochemistry, and targeted sequencing of further MS cases from Austria, Germany, Canada and Jordan. Results In this study, we describe the identification of a homozygous missense mutation (c.82T&gt;G, p.Cys28Gly) in the tripeptidyl peptidase II (TPP2) gene in all 3 affected siblings of the family. Sequencing of all TPP2-coding exons in 826 MS cases identified one further homozygous missense variant (c.2027C&gt;T, p.Thr676Ile) in a Jordanian MS patient. TPP2 protein expression in whole blood was reduced in the affected siblings. In contrast, TPP2 protein expression in postmortem brain tissue from MS patients without TPP2 mutations was highly upregulated. Conclusions The homozygous TPP2 mutation (p.Cys28Gly) is likely responsible for the inflammation phenotype in this family. TPP2 is an ubiquitously expressed serine peptidase that removes tripeptides from the N-terminal end of longer peptides. TPP2 is involved in various biological processes including the destruction of major histocompatibility complex Class I epitopes. Recessive loss-of-function mutations in TPP2 were described in patients with Evans syndrome, a rare autoimmune disease affecting the hematopoietic system. Based on the gene expression results in our MS autopsy brain samples, we further suggest that TPP2 may play a broader role in the inflammatory process in MS

Variant in the sequence of the LINGO1 gene confers risk of essential tremor

To access publisher full text version of this article. Please click on the hyperlink in Additional Links fieldWe identified a marker in LINGO1 showing genome-wide significant association (P = 1.2 x 10(-9), odds ratio = 1.55) with essential tremor. LINGO1 has potent, negative regulatory influences on neuronal survival and is also important in regulating both central-nervous-system axon regeneration and oligodendrocyte maturation. Increased axon integrity observed in Lingo1 mouse [corrected] knockout models highlights the potential role of LINGO1 in the pathophysiology of ET [corrected