Mutant huntingtin forms in vivo complexes with distinct context-dependent conformations of the polyglutamine segment

Huntington's disease (HD) is caused by an expanded glutamine tract, which confers a novel aggregation-promoting property on the 350-kDa huntingtin protein. Using specific antibodies, we have probed the structure of the polyglutamine segment in mutant huntingtin complexes formed in cell culture from either truncated or full-length protein. Complexes formed by a mutant amino terminal fragment most frequently entail a change in conformation that eliminates reactivity with the polyglutamine-specific mAb 1F8, coincident with production of insoluble aggregate. By contrast, complexes formed by the full-length mutant protein remain soluble and are invariably 1F8-reactive, indicating a soluble polyglutamine conformation. Therefore, aggregates in HD may form by different biochemical mechanisms that invoke different possibilities for the pathogenic process. If pathogenesis is triggered by a truncated fragment, it probably involves the formation of an insoluble aggregate. However, the observation of soluble complexes in which an HD-specific pathogenic conformation of the glutamine tract remains accessible suggests that pathogenesis could also be triggered at the level of full-length huntingtin by abnormal aggregation with normal or abnormal protein partners

Mot1p is essential for TBP recruitment to selected promoters during in vivo gene activation

Recruitment of TATA-binding protein (TBP) is central to activation of transcription by RNA polymerase II (pol II). This depends upon co-activator proteins including TBP-associated factors (TAFs). Yeast Mot1p was identified as a general transcriptional repressor in genetic screens and is also found associated with TBP. To obtain insight into Mot1p function in vivo, we determined the mRNA expression profile of the mot1-1 temperature-sensitive (Ts) strain. Unexpectedly, this indicated that Mot1p mostly plays a positive role for transcription. For one potential activation target, HXT2, we analyzed promoter recruitment of Mot1p, TBP, Taf1p (Taf130p) and pol II by chromatin immunoprecipitation assays. Whereas TBP becomes stably associated upon activation of the HXT2 and HXT4 promoters, Mot1p showed only a transient association. TBP recruitment was compromised in two different mot1 mutant strains, but was only moderately affected in a taf1 Ts strain. Together, our data indicate that Mot1p can assist in recruitment of TBP on promoters during gene activation in vivo

Missense variants in TAF1 and developmental phenotypes: Challenges of determining pathogenicity

We recently described a new neurodevelopmental syndrome (TAF1/MRXS33 intellectual disability [ID] syndrome) (MIM# 300966) caused by pathogenic variants involving the X-linked gene TATA-box binding protein associated factor 1 (TAF1), which participates in RNA polymerase II transcription. The initial study reported 11 families, and the syndrome was defined as presenting early in life with hypotonia, facial dysmorphia, and developmental delay that evolved into ID and/or autism spectrum disorder. We have now identified an additional 27 families through a genotype-first approach. Familial segregation analysis, clinical phenotyping, and bioinformatics were capitalized on to assess potential variant pathogenicity, and molecular modeling was performed for those variants falling within structurally characterized domains of TAF1. A novel phenotypic clustering approach was also applied, in which the phenotypes of affected individuals were classified using 51 standardized Human Phenotype Ontology terms. Phenotypes associated with TAF1 variants show considerable pleiotropy and clinical variability, but prominent among previously unreported effects were brain morphological abnormalities, seizures, hearing loss, and heart malformations. Our allelic series broadens the phenotypic spectrum of the TAF1/MRXS33 ID syndrome and the range of TAF1 molecular defects in humans. It also illustrates the challenges for determining the pathogenicity of inherited missense variants, particularly for a gene mapping to chromosome X