Lis Hasholt

Molecular and behavioral analysis of the R6/1 Huntington's disease transgenic mouse.

Transgenic mice expressing exon 1 of the human Huntingtons disease (HD) gene carrying a 115 CAG repeat (line R6/1) are characterized by a neurologic phenotype involving molecular, behavioral and motor disturbances. We have characterized the R6/1 to establish a set of biomarkers, which could be semi-quantitatively compared. We have measured motor fore- and hindlimb coordination, fore- and hindpaw footprinting, general activity and anxiety, feetclasping, developmental instability. Molecular investigations involved measurements of cannabinoid receptor 1 mRNA, met-enkephalin peptide, dopamine and cyclic AMP-regulated phosphoroprotein 32 kDa and neuronal inclusions. Molecular and behavioral testing was performed on female hemizygotic R6/1 transgenic mice and female wildtype littermates between 6 and 36 weeks of age. We show that the cannabinoid receptor 1 receptor is severely and rapidly downregulated in the R6/1 mouse between the 8(th) to the 10(th) week of age. At 14 weeks of age the first transgenic mice showed a behavioral phenotype measured by feetclasping. However, there was great variation between the individual animals. At 11 weeks of age the mice demonstrated progressively increasing developmental instability as measured by fluctuating asymmetry. Weight differences were evident by 22 weeks of age. Mice tested at 23 and 24 weeks of age showed significant impairments in open field and plus-maze analysis respectively. We observed no significant abnormalities in stride length of the R6/1 mouse model. As the analyzed parameters are easily detected and measured, the R6/1 mouse appears to be a good model for evaluating new drugs or types of therapy for HD.

Fabry disease mimicking hypertrophic cardiomyopathy: genetic screening needed for establishing the diagnosis in women

Fabry disease, an X‐linked storage disorder caused by defective lysosomal enzyme alpha‐galactosidase A activity, may resemble sarcomere‐gene‐associated hypertrophic cardiomyopathy (HCM). The ‘cardiac variant’ of Fabry disease which only affects the heart may be missed unless specifically tested for.

Autosomal dominant pure spastic paraplegia: a clinical, paraclinical, and genetic study

OBJECTIVES At least three clinically indistinguishable but genetically different types of autosomal dominant pure spastic paraplegia (ADPSP) have been described. In this study the clinical, genetic, neurophysiological, and MRI characteristics of ADPSP were investigated. METHODS Sixty three at risk members from five families were clinically evaluated. A diagnostic index was constructed for the study. Microsatellite genotypes were determined for chromosomes 2p, 14q, and 15q markers and multipoint linkage analyses were performed. Central motor conduction time studies (CMCT), somatosensory evoked potential (SSEP) measurement, and MRI of the brain and the total spinal cord were carried out in 16 patients from four families. RESULTS The clinical core features of ADPSP were homogeneously expressed in all patients but some features were only found in some families and not in all the patients within the family. In two families non-progressive “congenital” ADPSP was seen in some affected members whereas adult onset progressive ADPSP was present in other affected family members. As a late symptom not previously described low backache was reported by 47%. Age at onset varied widely and there was a tendency for it to decline in successive generations in the families, suggesting anticipation. Genetic linkage analysis confined the ADPSP locus to chromosome 2p21-p24 in the five families. The lod scores obtained by multipoint linkage analysis were positive with a combined maximum lod score of Z=8.60. The neurophysiological studies only showed minor and insignificant prolongation of the central motor conduction time and further that peripheral conduction and integrity of the dorsal columns were mostly normal. Brain and the total spinal cord MRI did not disclose any significant abnormalities compared with controls. CONCLUSIONS ADPSP linked to chromosome 2p21-p24 is a phenotypic heterogeneous disorder characterised by both interfamilial and intrafamilial variation. In some families the disease may be “pure” but the existence of “pure plus” families is suggested in others. The neurophysiological and neuroimaging investigations did not show any major abnormalities.

High-throughput analysis of fragile X (CGG)n alleles in the normal and premutation range by PCR amplification and automated capillary electrophoresis.

Fragile X syndrome is caused by expansion of a (CGG)n trinucleotide repeat within the 5′ untranslated region of the FMR1 gene transcript. The disease is reliably dignosed by Southern blotting, but this method constitutes a significant workload and requires large samples. Therefore, for large research or screening projects in which a large majority of the samples will be normal, a more rapid and less expensive method is needed. We present a method for accurate, high-throughput analysis of the FRAXA (CGG)n region in the normal and premutation range. The method is based on polymerase chain reaction (PCR) amplification of DNA extracted from whole blood or eluted from dried blood spots on filter-paper, followed by automated capillary electrophoresis and detection by multicolour fluorescence. This method allows a throughput of 144 samples in 48 h, with an intra-assay accuracy in size determination of 0.2–1.8 bp. We performed a blind reanalysis of samples from 30 patients, previously analysed by Southern blotting or PCR with radioactive labelling. In this study normal and premutation alleles, ranging from 28–121 (CGG)n repeats, were correctly determined with respect to number of (CGG)n repeats. All full-mutation alleles and one large premutation allele in a sample of a heterozygote failed to amplify. The method was used to determine the distribution of FRAXA (CGG)n repeats in the Danish population.

Platelet serotonin transporters and the transporter gene in control subjects, unipolar patients and bipolar patients

Objective: The purpose of the present study was to relate the number of platelet serotonin transporters in unipolar and bipolar patients and in control subjects to two polymorphisms in the serotonin transporter gene: a VNTR in intron 2 and a deletion/insertion in the promoter region.

Functional and structural nerve fiber findings in heterozygote patients with Fabry disease

ABSTRACT Fabry disease is an X‐linked inherited lysosomal disorder with dysfunction of the lysosomal enzyme &agr;‐galactosidase A causing accumulation of glycolipids in multiple organs including the nervous system. Pain and somatosensory disturbances are prominent manifestations of this disease. Until recently disease manifestations in female carriers of Fabry disease have been questioned. To explore the frequency of symptoms and the functional and structural involvement of the nervous system in female patients we examined the presence of pain, manifestations of peripheral neuropathy and nerve density in skin biopsies in 19 female patients with Fabry disease and 19 sex‐ and age‐matched controls. Diaries, quantitative sensory testing, neurophysiologic tests and skin biopsies were performed. Daily pain was present in 63% of patients, with a median VAS score of 4.0. Tactile detection threshold and pressure pain threshold were lower and cold detection thresholds increased in patients. Sensory nerve action potential amplitude and maximal sensory conduction velocity were not different, whereas there was a highly significant reduction in intraepidermal nerve fiber density. We found no correlation between pain VAS score, quantitative sensory testing and intraepidermal nerve fiber density. Our study demonstrates that careful evaluation of symptoms in female Fabry patients is important as small fiber disease manifestations are present, which in some cases is only detected by skin biopsy.

Antisense downregulation of mutant huntingtin in a cell model

Huntingtons disease (HD) is an inherited neurodegenerative disorder which is caused by an expansion of a CAG repeat sequence in the HD gene. The repeat encodes an expanded polyglutamine tract in the protein huntingtin. The still unknown pathological mechanisms leading to death of specific neurons in the brains of HD patients correlate with the expression of mutant huntingtin. Therefore, we have studied whether mutant huntingtin expression can be downregulated by antisense technique.

Impaired glucose tolerance in the R6/1 transgenic mouse model of Huntington's disease.

Previous reports have highlighted a possible link between Huntington’s disease (HD) and diabetes mellitus (DM), but the association has not been characterised in detail. A transgenic mouse model for HD, the R6/2 mouse, also develops diabetes. In the present study, we examined the R6/1 mouse, which carries a shorter CAG repeat than the R6/2 mouse, and found that, although not diabetic, the mice showed several signs of impaired glucose tolerance. First, following i.p. glucose injection, the blood glucose concentration was approximately 30% higher in young R6/1 mice (10 weeks) compared to wild‐type mice (P = 0.004). In older mice (38 weeks), glucose tolerance was further impaired in both R6/1 and wild‐type animals. Second, during glucose challenge, the R6/1 mice reached higher plasma insulin levels than wild‐type mice, but the peripheral insulin sensitivity was normal as measured by injection of human or mouse insulin or when evaluated by the quantitative insulin sensitivity check index (QUICKI). Third, the beta cell volume was 17% and 39% smaller at 10 and 38 weeks of age, respectively, compared to age‐matched wild‐type littermates and the reduction was not caused by apoptosis at either age. Finally, we demonstrated the presence of the HD gene product, huntingtin (htt), in both alpha‐ and beta‐cells in R6/1 islets of Langerhans. Since pancreatic beta cells and neurons share several common traits, clarification of the mechanism associating neurodegenerative diseases with diabetes might improve our understanding of the pathogenic events leading to both groups of diseases.

Inhibition of Huntingtin Synthesis by Antisense Oligodeoxynucleotides

The Huntington disease gone encodes the protein huntington, which is widely expressed during embryonic development and in mature tissues. In order to elucidate the physiological function of huntington, which so far is unknown, we intend to study the effect of antisense down-regulated huntington expression. We have found an inhibiting effect of a phosphorothioated oligodeoxynucleotide (PS-ODN) added to the culture medium of embryonic teratocarcinoma cells (NT2) and postmitotic neurons (NT2N neurons) differentiated from the NT2 cells. Specific inhibition of expression of endogenous huntington was achieved in NT2N neurons in the concentration range of 1-5 microM PS-ODN, whereas no inhibition was obtained in NT2 cells. We describe in detail the selection of the target sequence for the antisense oligo and the uptake, intracellular distribution, and stability of the antisense PS-ODN in the two cell types. Antisense down-regulation of huntington in this model of human neurons represents a suitable approach to study its normal function.

Neuron-specific RNA interference using lentiviral vectors.

Viral vectors have been used in several different settings for the delivery of small hairpin (sh) RNAs. However, most vectors have utilized ubiquitously‐expressing polymerase (pol) III promoters to drive expression of the hairpin as a result of the strict requirement for precise transcriptional initiation and termination. Recently, pol II promoters have been used to construct vectors for RNA interference (RNAi). By embedding the shRNA into a micro RNA‐context (miRNA) the endogenous miRNA processing machinery is exploited to achieve the mature synthetic miRNA (smiRNA), thereby expanding the possible promoter choices and eventually allowing cell type specific down‐regulation of target genes.