TBK1 haploinsufficiency results in changes in the K63-ubiquitination profiles in brain and fibroblasts from affected and presymptomatic mutation carriers

Background Frontotemporal dementia (FTD) is a neurodegenerative disease, resulting in progressive problems in language and/or behaviour and is often diagnosed before 65 years of age. Ubiquitin positive protein aggregates in the brain are among the key pathologic hallmarks of frontotemporal lobar degeneration (FTLD) postmortem. The TANK-binding kinase 1 gene (TBK1) is on the list of genes that can contribute to the development of FTD as well as the related neurodegenerative disease amyotrophic lateral sclerosis (ALS). Methods In this study, using an array of clinical and neuropathological data combined with biochemical and proteomics assays, we analyze the TBK1 splice-mutation (c.1340 + 1G > A) in a Swedish family with a history of FTD and ALS. We also explore the K63 ubiquitination landscape in post-mortem brain tissue and fibroblast cultures. Results The intronic (c.1340 + 1G > A) mutation in TBK1 results in haploinsufficiency and affects the activity of the protein in symptomatic and pre-symptomatic mutation carriers. Conclusion Our results suggest that the mutation leads to a significant reduction of TBK1 activity and induce alterations in K63 ubiquitination profile of the cell already in the presymptomatic stages.

Presenilin 1 and APP Gene Mutations in Early-Onset AD Families from a Southeast Region of China

Background: Early-Onset Familial Alzheimer’s Disease (EOFAD) has been reported to be associated with Presenilin 1 (PSEN1), Presenilin 2 (PSEN2), and Amyloid Precursor Protein (APP) genes. The spectrum of mutations in Chinese patients with EOFAD was rarely investigated. Objective: To investigate the spectrum of mutations in patients with EOFAD in Chinese population. Methods: We performed whole-exome sequencing and described relevant clinical features in a total of 67 subjects from 3 families with EOFAD. Results: A splice mutation (p.S290C) in PSEN1 and a missense mutation (p.V717I) in APP were identified. Conclusion: The variant p. S290C (c.869-2>G) in PSEN1 in Chinese EOAD family revealed different clinical phenotypes when compared with that of Europeans.

Investigation of an LPA KIV-2 nonsense mutation in 11,000 individuals: the importance of linkage disequilibrium structure in LPA genetics

ObjectiveElevated Lp(a) plasma concentrations are determined mainly genetically by the LPA gene locus, but up to 70% of the coding sequence is located in the so-called “kringle IV type 2” (KIV-2) copy number variation. This region is not resolved by common genotyping technologies and large epidemiological studies on this region are therefore missing. The Arg21Ter variant (R21X, variant frequency ≈2%) is a functional variant in this region, but it has never been analyzed in large cohorts and is it unknown whether it is captured by genome-wide association studies.Approach and ResultsWe developed a highly sensitive allele-specific qPCR assay and genotyped R21X in 10,910 individuals from three populations (GCKD, KORA F3, KORA F4). R21X carriers showed significantly lower mean Lp(a) concentrations (−11.7 mg/dL [−15.5;−7.82], p=3.39e-32). Of particular note, virtually all R21X carriers also carried the splice mutation rs41272114 (D’=0.957, R2=0.275), as confirmed by pulsed-field gel electrophoresis and long-range haplotyping. This proposes that the R21X mutation arose on the background of the rs41272114 splice variant.ConclusionsWe performed the largest epidemiological study on an LPA KIV-2 variant so far. Interestingly, R21X is located on the same haplotype as the splice mutation rs41272114, creating “double-null” LPA alleles that are inactivated by two independent mutations. The effect of the R21X nonsense mutation can thus not be discerned from the effect of rs41272114 splice site mutation. This emphasizes the importance of assessing the complex LD structure within LPA even for functional variants.

Functional analysis of KIT gene structural mutations causing porcine dominant white phenotype by using genome edited mouse models

Dominant white phenotype in pigs is considered to be caused by two structural mutations in KIT gene, including a 450-kb duplication encompassing the entire KIT gene, and a splice mutation (G > A) at the first base in intron 17, which leads to the deletion of exon 17 in mature KIT mRNA, and the production of KIT protein lacking a critical catalytic domain of kinase. However, this speculation has not yet been validated by functional studies. Here, by using CRISPR/Cas9 technology, we created two mouse models mimicing the structural mutations of KIT gene in dominant white pigs, including the splice mutation mouse model KIT D17/+ with exon 17 of one allele of KIT gene deleted, and duplication mutation mouse model KIT Dup/+ with one allele of KIT gene coding sequence (CDS) duplicated. We found that each mutation individually can not cause dominant white phenotype. Splice mutation homozygote is lethal and heterozygous mice present piebald coat. Inconsistent with previous speculation, we found KIT gene duplication mutation did not confer the patched phenotype, and had no obvious impact on coat color. Interestingly, combination of these two mutations lead to dominant white phenotype. Further molecular analysis revealed that combination of these two structural mutations could inhibit the kinase activity of the KIT protein, thus reduce the phosphorylation level of PI3K and MAPK pathway associated proteins, which may be related to the observed impaired migration of melanoblasts during embryonic development, and eventually lead to dominant white phenotype. Our study provides a further insight into the underlying genetic mechanisms of porcine dominant white coat colour.Author summaryKIT plays a critical role in control of coat colour in mammals. Two mutation coexistence in KIT are considered to be the cause of the Dominant white phenotype in pigs. One mutation is a 450-kb large duplication encompassing the entire KIT gene, another mutation is a splice mutation causing the skipping of KIT exon 17. The mechanism of these two mutations of KIT on coat color formation has not yet been validated. In this study, by using genome edited mouse models, we found each structural mutation individual does not lead dominant white phenotype, but combination of these two mutations could lead to a nearly complete white coat colour similar to pig dominant white phenotype, possibly due to the inhibition of the kinase activity of the KIT protein, thus its signalling function on PI3K and MAPK pathways, leading to impaired migration of melanoblasts during embryonic development, and eventually lead to dominant white phenotype. Our study provides a further insight into the underlying genetic mechanisms of porcine dominant white coat colour.