Huntington’s disease (HD) is an autosomal dominant neurodegenerative disorder characterized by motor, cognitive and psychiatric manifestations. Since the mutation responsible for the disease was identified as an unstable expansion of CAG repeats in the gene encoding the huntingtin protein in 1993, numerous mouse models of HD have been generated to study disease pathogenesis and evaluate potential therapeutic approaches. Of these, knock-in models best mimic the human condition from a genetic perspective since they express the mutation in the appropriate genetic and protein context. Behaviorally, however, while some abnormal phenotypes have been detected in knock-in mouse models, a model with an earlier and more robust phenotype than the existing models is required. We describe here for the first time a new mouse line, the zQ175 knock-in mouse, derived from a spontaneous expansion of the CAG copy number in our CAG 140 knock-in colony [1]. Given the inverse relationship typically observed between age of HD onset and length of CAG repeat, since this new mouse line carries a significantly higher CAG repeat length it was expected to be more significantly impaired than the parent line. Using a battery of behavioral tests we evaluated both heterozygous and homozygous zQ175 mice. Homozygous mice showed motor and grip strength abnormalities with an early onset (8 and 4 weeks of age, respectively), which were followed by deficits in rotarod and climbing activity at 30 weeks of age and by cognitive deficits at around 1 year of age. Of particular interest for translational work, we also found clear behavioral deficits in heterozygous mice from around 4.5 months of age, especially in the dark phase of the diurnal cycle. Decreased body weight was observed in both heterozygotes and homozygotes, along with significantly reduced survival in the homozygotes. In addition, we detected an early and significant decrease of striatal gene markers from 12 weeks of age. These data suggest that the zQ175 knock-in line could be a suitable model for the evaluation of therapeutic approaches and early events in the pathogenesis of HD.
Huntington's disease (HD) is an autosomal dominant, progressive neurodegenerative disorder caused by expansion of CAG repeats in the huntingtin gene. Tissue transglutaminase 2 (TG2), a multi-functional enzyme, was found to be increased both in HD patients and in mouse models of the disease. Furthermore, beneficial effects have been reported from the genetic ablation of TG2 in R6/2 and R6/1 mouse lines. To further evaluate the validity of this target for the treatment of HD, we examined the effects of TG2 deletion in two genetic mouse models of HD: R6/2 CAG 240 and zQ175 knock in (KI). Contrary to previous reports, under rigorous experimental conditions we found that TG2 ablation had no effect on either motor or cognitive deficits, or on the weight loss. In addition, under optimal husbandry conditions, TG2 ablation did not extend R6/2 lifespan. Moreover, TG2 deletion did not change the huntingtin aggregate load in cortex or striatum and did not decrease the brain atrophy observed in either mouse line. Finally, no amelioration of the dysregulation of striatal and cortical gene markers was detected. We conclude that TG2 is not a valid therapeutic target for the treatment of HD.
The genome of the Bacterial Artificial Chromosome (BAC) transgenic mouse model of Huntington’s Disease (BAC HD) contains the 170 kb human HTT locus modified by the addition of exon 1 with 97 mixed CAA-CAG repeats. BAC HD mice present robust behavioral deficits in both the open field and the accelerating rotarod tests, two standard behavioral assays of motor function. BAC HD mice, however, also typically present significantly increased body weights relative to wildtype littermate controls (WT) which potentially confounds the interpretation of any motor deficits associated directly with the effects of mutant huntingtin. In order to evaluate this possible confound of body weight, we directly compared the performance of BAC HD and WT female mice under food restricted versus free feeding conditions in both the open field and rotarod tasks to test the hypothesis that some of the motor deficits observed in this HTT-transgenic mouse line results solely from increased body weight. Our results suggest that the rotarod deficit exhibited by BAC HD mice is modulated by both body weight and non-body weight factors resulting from overexpression of full length mutant Htt. When body weights of WT and BAC HD transgenic mice were normalized using restricted feeding, the deficits exhibited by BAC HD mice on the rotarod task were less marked, but were still significant. Since the rotarod deficit between WT and BAC HD mice is attenuated when body weight is normalized by food restriction, utilization of this task in BAC HD mice during pre-clinical evaluation must be powered accordingly and results carefully considered as therapeutic benefit can result from decreased overall body weight and or motoric improvement that may not be related to body mass. Furthermore, after controlling for body weight differences, the hypoactive phenotype displayed by ad libitum fed BAC HD mice in the open field assay was not observed in the BAC HD mice undergoing food restriction. These findings suggest that assessment of spontaneous locomotor activity, as measured in the open field test, may not be the appropriate behavioral endpoint to evaluate the BAC HD mouse during preclinical evaluation since it appears that the apparent hypoactive phenotype in this model is driven primarily by body weight differences.
Naturally occurring genetic markers can be exploited in a number of ways to measure natural selection in fungal populations. The potentials and pitfalls of these approaches are outlined. A review of existing experiments that have used genetic markers to estimate selection coefficients (s) in experimental and natural fungal populations indicates that differences in fitness between clones, populations, and subspecies may be substantial (mean s = 0.322), and that significant changes in the intensity and direction of selection may occur when environmental conditions alter. A reciprocal transplant experiment is described in which the relative selective values of three genetically marked populations of the canker pathogen Crumenulopsis sororia were compared under natural conditions. Large differences in selective value were found both among populations and within sites, but there was no evidence that genetic differentiation among populations was adaptive. The potential application of genetic markers for experimentally investigating mechanisms of speciation, adaptive genetic differentiation, and response to environmental change in fungi is discussed. Key words: genetic marker, natural selection, selection coefficient, Crumenulopsis sororia.
Background: Huntington's disease (HD) is characterized not only by severe motor deficits but also by early cognitive dysfunction that significantly increases the burden of the disease for patients and caregivers. Considerable efforts have concentrated, therefore, on the assessment of cognitive deficits in some HD mouse models. However, many of these models that exhibit cognitive deficits also have contemporaneous serious motor deficits, confounding interpretation of cognitive decline. Objective: The BACHD and zQ175 mouse models present a more slowly progressing disease phenotype in both motor and cognitive domains, and might therefore offer a better opportunity to measure cognitive decline over a longer timeframe; such models could be useful in screening therapeutic compounds. In order to better define the cognitive impairments evident in BACHD and zQ175 HD mice, both were tested in an instrumental touchscreen visual discrimination assay designed to assess discrimination learning and cognitive flexibility. Methods: BACHD and zQ175 mice, as well as their WT controls were tested for their ability to discriminate two complex visual stimuli. Following this discrimination phase, the reinforcement contingencies were reversed and the previously incorrect stimulus became the correct stimulus. In a final, third phase of testing, two novel stimuli were introduced and mice were required to undergo a second round of discrimination testing with these stimuli. Results: Our results show that learning during the discrimination phase was similar between the WT and BACHD mice. In contrast, the zQ175 at 26 weeks of age showed decreased accuracy over the last 10 days of discrimination, compared to WT controls. During subsequent reversal and novel stimuli phases, both BACHD and zQ175 mice exhibited significant deficits compared to WT controls. Conclusions: Our results suggest that the BACHD, and for the first time, zQ175 HD models exhibit cognitive inflexibility and psychomotor slowing, a phenotype that is consistent with cognitive symptoms described in HD patients.
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