Russell G. Snell

A novel gene containing a trinucleotide repeat that is expanded and unstable on Huntington's disease chromosomes

The Huntingtons disease (HD) gene has been mapped in 4p16.3 but has eluded identification. We have used haplotype analysis of linkage disequilibrium to spotlight a small segment of 4p16.3 as the likely location of the defect. A new gene, IT15, isolated using cloned trapped exons from the target area contains a polymorphic trinucleotide repeat that is expanded and unstable on HD chromosomes. A (CAG)n repeat longer than the normal range was observed on HD chromosomes from all 75 disease families examined, comprising a variety of ethnic backgrounds and 4p16.3 haplotypes. The (CAG)n repeat appears to be located within the coding sequence of a predicted approximately 348 kd protein that is widely expressed but unrelated to any known gene. Thus, the HD mutation involves an unstable DNA segment, similar to those described in fragile X syndrome, spino-bulbar muscular atrophy, and myotonic dystrophy, acting in the context of a novel 4p16.3 gene to produce a dominant phenotype.

An ovine transgenic Huntington's disease model

Huntingtons disease (HD) is an inherited autosomal dominant neurodegenerative disorder caused by an expansion of a CAG trinucleotide repeat in the huntingtin (HTT) gene [Huntingtons Disease Collaborative Research Group (1993) A novel gene containing a trinucleotide repeat that is expanded and unstable on Huntingtons disease chromosomes. The Huntingtons Disease Collaborative Research Group. Cell, 72, 971-983]. Despite identification of the gene in 1993, the underlying life-long disease process and effective treatments to prevent or delay it remain elusive. In an effort to fast-track treatment strategies for HD into clinical trials, we have developed a new large-animal HD transgenic ovine model. Sheep, Ovis aries L., were selected because the developmental pattern of the ovine basal ganglia and cortex (the regions primarily affected in HD) is similar to the analogous regions of the human brain. Microinjection of a full-length human HTT cDNA containing 73 polyglutamine repeats under the control of the human promotor resulted in six transgenic founders varying in copy number of the transgene. Analysis of offspring (at 1 and 7 months of age) from one of the founders showed robust expression of the full-length human HTT protein in both CNS and non-CNS tissue. Further, preliminary immunohistochemical analysis demonstrated the organization of the caudate nucleus and putamen and revealed decreased expression of medium size spiny neuron marker DARPP-32 at 7 months of age. It is anticipated that this novel transgenic animal will represent a practical model for drug/clinical trials and surgical interventions especially aimed at delaying or preventing HD initiation. New sequence accession number for ovine HTT mRNA: FJ457100.

Amyloid-like inclusions in Huntington's disease.

Huntingtons disease is a progressive, autosomal dominantly inherited, neurodegenerative disease that is characterized by involuntary movements (chorea), cognitive decline and psychiatric manifestations. This is one of a number of late-onset neurodegenerative disorders caused by expanded glutamine repeats, with a likely similar biochemical basis. Immunohistochemical studies on Huntingtons disease tissue, using antibodies raised to the N-terminal region of huntingtin (adjacent to the repeat) and ubiquitin, have recently identified neuronal inclusions within densely stained neuronal nuclei, peri-nuclear and within dystrophic neuritic processes. However, the functional significance of inclusions is unknown. It has been suggested that the disease-causing mechanism in Huntingtons disease (and the other polyglutamine disorders) is the ability of polyglutamine to undergo a conformational change that can lead to the formation of very stable anti-parallel beta-sheets; more specifically, amyloid structures. We examined, using Congo Red staining and both polarizing and confocal microscopy, post mortem human brain tissue from five Huntingtons disease cases, two Alzheimers disease cases and two normal controls. Brains from five transgenic mice (R6/2)(12) expressing exon 1 of the human huntingtin gene with expanded polyglutamine, and five littermate controls, were also examined by the same techniques. We have shown that some inclusions in Huntingtons disease brain tissue possess an amyloid-like structure, suggesting parallels with other amyloid-associated diseases such as Alzheimers and prion diseases.

Molecular analysis and clinical correlations of the Huntington's disease mutation

The genetic mutation underlying Huntingtons disease (HD) has been identified as an expansion and instability of a specific CAG repeat sequence in a gene (IT15) on chromosome 4. We have investigated the relation of the phenotype of HD to this molecular defect and assessed the feasibility of HD mutation analysis in diagnosis and prediction. Analysis of DNA from 449 HD patients (351 familial and 98 apparently isolated cases) revealed the mutation in more than 95% of patients from both groups. No molecular difference was found between patients presenting with psychiatric symptoms and those in whom chorea or other motor defects were the principal features; additionally, there was a wide range of age at onset for any specific repeat number, though the small group with juvenile onset and presenting with rigidity showed the largest expansions. The findings suggest that molecular analysis will be an accurate and specific diagnostic test for HD and valuable in presymptomatic detection in individuals at risk. However, such testing will require considerable caution to avoid serious difficulties; the well-established guidelines developed for the use of linked markers in relation to the prediction of HD should continue to be followed, though they will require reassessment in relation to use in diagnosis.

Compound heterozygosity and nonsense mutations in the alpha(1)-subunit of the inhibitory glycine receptor in hyperekplexia

The α1-inhibitory glycine receptor is a ligand-gated chloride channel composed of three ligand-binding α1-subunits and two structural β-subunits that are clustered on the postsynaptic membrane of inhibitory glycinergic neurons. Dominant and recessive mutations in GLRA1 subunits have been associated with a proportion of individuals and families with startle disease or hyperekplexia (MIM: 149400). Following SSCP and bi-directional di-deoxy fingerprinting mutational analysis of 22 unrelated individuals with hyperekplexia and hyperekplexia-related conditions, we report further novel missense mutations and the first nonsense point mutations in GLRA1, the majority of which localise outside the regions previously associated with dominant, disease-segregating mutations. Population studies reveal the unique association of each mutation with disease, and reveals that a proportion of sporadic hyperekplexia is accounted for by the homozygous inheritance of recessive GLRA1 mutations or as part of a compound heterozygote.

TATA-binding protein in neurodegenerative disease

TATA binding protein (TBP) is a general transcription factor that plays an important role in initiation of transcription. In recent years evidence has emerged implicating TPB in the molecular mechanism of a number of neurodegenerative diseases. Wild type TBP in humans contains a long polyglutamine stretch ranging in size from 29 to 42. It has been found associated with aggregated proteins in several of the polyglutamine disorders. Expansion in the CAA/CAG composite repeat beyond 42 has been shown to cause a cerebellar ataxia, SCA17. The involvement of such an important housekeeping protein in the disease mechanism suggests a major impact on the functioning of cells. The question remains, does TBP contribute to these diseases through a loss of normal function, likely to be catastrophic to a cell, or the gain of an aberrant function? This review deals with the function of TBP in transcription and cell function. The distribution of the polyglutamine coding allele lengths in TBP of the normal population and in SCA17 is reviewed and an outline is given on the reported cases of SCA17. The role of TBP in other polyglutamine disorders will be addressed as well as its possible role in other neurodegenerative diseases.

Linkage disequilibrium in Huntington's disease: an improved localisation for the gene.

The search for the Huntingtons disease gene has recently concentrated on the telomere of the short arm of chromosome 4. The evidence suggesting this position has been based on single crossover events, but there is conflicting evidence regarding the position of the gene relative to the most terminal markers. We have found significant linkage disequilibrium between the markers D4S98 (probe BS731B-C) and D4S95 (probe BS674E-D) and HD, which supports a localisation for the gene proximal to D4S90 and makes a telomeric localisation unlikely. This disequilibrium may also prove to be important in the future in allowing modification of risk estimates based on genetic linkage.

Mutation in Bovine β-Carotene Oxygenase 2 Affects Milk Color

β-Carotene biochemistry is a fundamental process in mammalian biology. Aberrations either through malnutrition or potentially through genetic variation may lead to vitamin A deficiency, which is a substantial public health burden. In addition, understanding the genetic regulation of this process may enable bovine improvement. While many bovine QTL have been reported, few of the causative genes and mutations have been identified. We discovered a QTL for milk β-carotene and subsequently identified a premature stop codon in bovine β-carotene oxygenase 2 (BCO2), which also affects serum β-carotene content. The BCO2 enzyme is thereby identified as a key regulator of β-carotene metabolism.

Insoluble TATA-binding protein accumulation in Huntington’s disease cortex

Huntingtons disease is a dominantly inherited neurological disorder where specific neurodegeneration is caused by an extended polyglutamine stretch in the huntingtin protein. Proteins with expanded polyglutamine regions have the ability to self-aggregate and previous work in our laboratory, and by others, revealed sparse amyloid-like deposits in the Huntingtons disease brain, supporting the hypothesis that the polyglutamine stretches may fold into regular beta-sheet structures. This process of folding has similarities to other neurodegenerative disorders including Alzheimers disease, Parkinsons disease, and the prion diseases which all exhibit beta-sheet protein accumulation. We were therefore interested in testing the hypothesis that TATA-binding protein may play a role in Huntingtons disease as it contains an elongated polymorphic polyglutamine stretch that ranges in size from 26 to 42 amino acids in normal individuals. A proportion of TBP alleles fall within the range of glutamine length that causes neurodegeneration when located in the huntingtin protein. In this study the distribution and cellular localisation of TATA-binding protein was compared to the distribution and cellular localisation of the huntingtin protein in the middle frontal gyrus of Huntingtons disease and neurologically normal subjects. Seven different morphological forms of TATA-binding protein-positive structures were detected in Huntingtons disease but not in control brain. TATA-binding protein labelling was relatively more abundant than huntingtin labelling and increased with the grade of the disease. At least a proportion of this accumulated TBP exists as insoluble protein. This suggests that TBP may play a role in the disease process.

Genetic variation in PLAG1 associates with early life body weight and peripubertal weight and growth in Bos taurus

Variation at the pleiomorphic adenoma gene 1 (PLAG1) locus has recently been implicated in the regulation of stature and weight in Bos taurus. Using a population of 942 outbred Holstein-Friesian dairy calves, we report confirmation of this effect, demonstrating strong association of early life body weight with PLAG1 genotype. Peripubertal body weight and growth rate were also significantly associated with PLAG1 genotype. Growth rate per kilogram of body weight, daily feed intake, gross feed efficiency and residual feed intake were not significantly associated with PLAG1 genotype. This study supports the status of PLAG1 as a key regulator of mammalian growth. Further, the data indicate the utility of PLAG1 polymorphisms for the selection of animals to achieve enhanced weight gain or conversely to aid the selection of animals with lower mature body weight and thus lower maintenance energy requirements.