Antagonistic pleiotropy in mice carrying a CAG repeat expansion in the range causing Huntington’s disease

Morton, A. Jennifer; Skillings, Elizabeth A.; Wood, Nigel I.; Zheng, Zhiguang

doi:10.1038/s41598-018-37102-8

Cited by 11 publications

(13 citation statements)

References 80 publications

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“…The work presented in this study contributes to a larger data set showing that the relationship between CAG repeat length and disease progression in R6/2 mice is complex, with phenotypes generally worsening with increasing CAG repeat length up to ∼150 CAGs, after which phenotypes improve as the CAG repeat length increases further ( Dragatsis et al , 2009 ; Morton et al , 2009 ; Cummings et al , 2012 ; Morton et al , 2019 ). The level of huntingtin expression at both RNA and protein levels was lower in R6/2 mice with expansions in 400 CAG range as opposed to 150 CAGs ( Dragatsis et al , 2009 ), consistent with the prediction that unusual DNA structures formed by super-long CAG repeats might impair transcription ( Duzdevich et al , 2011 ).…”

Section: Discussionmentioning

confidence: 88%

Subcellular Localization And Formation Of Huntingtin Aggregates Correlates With Symptom Onset And Progression In A Huntington’S Disease Model

Landles

Milton

Ali

et al. 2020

Brain Communications

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Huntington’s disease is caused by the expansion of a CAG repeat within exon 1 of the HTT gene, which is unstable, leading to further expansion, the extent of which is brain region and peripheral tissue specific. The identification of DNA repair genes as genetic modifiers of Huntington’s disease, that were known to abrogate somatic instability in Huntington’s disease mouse models, demonstrated that somatic CAG expansion is central to disease pathogenesis, and that the CAG repeat threshold for pathogenesis in specific brain cells might not be known. We have previously shown that the HTT gene is incompletely spliced generating a small transcript that encodes the highly pathogenic exon 1 HTT protein. The longer the CAG repeat, the more of this toxic fragment is generated, providing a pathogenic consequence for somatic expansion. Here, we have used the R6/2 mouse model to investigate the molecular and behavioural consequences of expressing exon 1 HTT with 90 CAGs, a mutation that causes juvenile Huntington’s disease, compared to R6/2 mice carrying ∼200 CAGs, a repeat expansion of a size rarely found in Huntington’s disease patient’s blood, but which has been detected in post mortem brains as a consequence of somatic CAG repeat expansion. We show that nuclear aggregation occurred earlier in R6/2(CAG)90 mice and that this correlated with the onset of transcriptional dysregulation in these lines. Whereas in R6/2(CAG)200 mice, cytoplasmic aggregates accumulated rapidly and closely tracked with the progression of behavioural phenotypes and with end-stage disease. We find that aggregate species formed in the R6/2(CAG)90 brains have different properties to those in the R6/2(CAG)200 mice. Within the nucleus, they retain a diffuse punctate appearance throughout the course of the disease, can be partially solubilised by detergents and have a greater seeding potential in young mice. In contrast, aggregates from R6/2(CAG)200 brains polymerise into larger structures that appear as inclusion bodies. These data emphasise that a subcellular analysis, using multiple complementary approaches, must be undertaken in order to draw any conclusions about the relationship between HTT aggregation and the onset and progression of disease phenotypes.

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Section: Discussionmentioning

confidence: 88%

Subcellular Localization And Formation Of Huntingtin Aggregates Correlates With Symptom Onset And Progression In A Huntington’S Disease Model

Landles

Milton

Ali

et al. 2020

Brain Communications

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“…Nevertheless, this raises the intriguing possibility that the increase in melatonin in the sheep is part of a compensatory process in the presymptomatic HD brain that confers endogenous neuroprotection against the mutant protein. There is considerable evidence for the existence of such a phenomenon in presymptomatic HD mice that, despite ongoing expression of the mutation that eventually causes disease, are less susceptible to neurotoxins than control mice . Melatonin, with its well‐documented neuroprotective properties, is a prime candidate for playing a role in such autoprotection.…”

Section: Discussionmentioning

confidence: 99%

“…Finally, an intriguing possibility is that melatonin may not be coming from the pineal itself, but may be being produced directly by mitochondria in the brain . The relevance of this to HD is not yet clear, although it is interesting to note that there is increased energy metabolism in presymptomatic HD mice, and they are also more resistant to mitochondrial toxins at presymptomatic stages …”

Section: Discussionmentioning

confidence: 99%

Increased plasma melatonin in presymptomatic Huntington disease sheep (Ovis aries): Compensatory neuroprotection in a neurodegenerative disease?

Morton

Middleton

Rudiger

et al. 2019

Journal of Pineal Research

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Melatonin is a pleiotrophic hormone, synthesised primarily by the pineal gland under the control of the suprachiasmatic nuclei (SCN). It not only provides a hormonal signal of darkness but also has neuroprotective properties. Huntington's disease (HD) is a progressive neurodegenerative disorder characterised by abnormal motor, cognitive and psychiatric symptoms. There is growing evidence, particularly from animal models, that circadian rhythms may also be disturbed in HD. We measured two circadian-regulated hormones, melatonin and cortisol, in plasma samples collected around-the-clock from normal and presymptomatic transgenic HD sheep (Ovis aries) at 5 and 7 years of age, to assess SCN-driven rhythms and the effect of genotype, sex and age. Melatonin-related precursors and metabolites (tryptophan, serotonin, kynurenine) were also measured by liquid chromatography (LC)-mass spectrometry (MS). At 5 years of age in both rams and ewes, plasma melatonin levels were significantly elevated in HD sheep. In ewes measured 2 years later, there was still a significant elevation of nocturnal melatonin. Furthermore, the daytime baseline levels of melatonin were significantly higher in HD sheep. Since increased melatonin could have global beneficial effects on brain function, we suggest that the increased melatonin measured in presymptomatic HD sheep is part of an autoprotective response to mutant huntingtin toxicity that may account, at least in part, for the late onset of disease that characterises HD.

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“…Simply put, mice with small germline CAG expansions in the range typically observed in humans do not develop an overt HD phenotype during their lifetime [245,246]. HD mice with larger germline expansions typically beyond the length that is observed even in most juvenile HD cases (>80 repeats), can display robust HD phenotypes in a matter of months (e.g., [163,167,168]).…”

Section: The Journey To Pathology: Genetically Suppressing Somatic Exmentioning

confidence: 99%

“…One of the primary reasons that more definitive data directly linking somatic expansion and disease pathology in HD models has been difficult to generate relates to the length of the CAG repeat in mice necessary to generate sufficient levels of somatic expansion and/or a disease phenotype during the lifetime of a mouse, or the even shorter length of a typical project grant. Simply put, mice with small germline CAG expansions in the range typically observed in humans do not develop an overt HD phenotype during their lifetime [ 245, 246 ]. HD mice with larger germline expansions typically beyond the length that is observed even in most juvenile HD cases (>80 repeats), can display robust HD phenotypes in a matter of months (e.g., [ 163, 167, 168 ]).…”

Section: The Two Towersmentioning

confidence: 99%

The Contribution of Somatic Expansion of the CAG Repeat to Symptomatic Development in Huntington’s Disease: A Historical Perspective

Monckton

2021

JHD

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The discovery in the early 1990s of the expansion of unstable simple sequence repeats as the causative mutation for a number of inherited human disorders, including Huntington’s disease (HD), opened up a new era of human genetics and provided explanations for some old problems. In particular, an inverse association between the number of repeats inherited and age at onset, and unprecedented levels of germline instability, biased toward further expansion, provided an explanation for the wide symptomatic variability and anticipation observed in HD and many of these disorders. The repeats were also revealed to be somatically unstable in a process that is expansion-biased, age-dependent and tissue-specific, features that are now increasingly recognised as contributory to the age-dependence, progressive nature and tissue specificity of the symptoms of HD, and at least some related disorders. With much of the data deriving from affected individuals, and model systems, somatic expansions have been revealed to arise in a cell division-independent manner in critical target tissues via a mechanism involving key components of the DNA mismatch repair pathway. These insights have opened new approaches to thinking about how the disease could be treated by suppressing somatic expansion and revealed novel protein targets for intervention. Exciting times lie ahead in turning these insights into novel therapies for HD and related disorders.

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Antagonistic pleiotropy in mice carrying a CAG repeat expansion in the range causing Huntington’s disease

Cited by 11 publications

References 80 publications

Subcellular Localization And Formation Of Huntingtin Aggregates Correlates With Symptom Onset And Progression In A Huntington’S Disease Model

Subcellular Localization And Formation Of Huntingtin Aggregates Correlates With Symptom Onset And Progression In A Huntington’S Disease Model

Increased plasma melatonin in presymptomatic Huntington disease sheep (Ovis aries): Compensatory neuroprotection in a neurodegenerative disease?

The Contribution of Somatic Expansion of the CAG Repeat to Symptomatic Development in Huntington’s Disease: A Historical Perspective

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