Back

Cell-specific transcription dysregulation in human Huntington's disease-positive developing striatum

Precious, S. V.; Bartley, O. J.; Linehan, P.; Aston, A. N.; Hills, R.; McGorrian, A.-M.; Dion, V.; Rosser, A. E.

2026-06-19 neuroscience
10.64898/2026.06.19.733377 bioRxiv
Show abstract

Huntingtons disease (HD) is an autosomal dominant neurodegenerative disorder caused by a CAG-repeat expansion in the HTT gene. Progressive loss of striatal projection neurons leads to cognitive, psychiatric, and motor impairments that typically manifest in midlife, despite the presence of the expansion from conception. Increasing evidence supports a neurodevelopmental component to HD; however, authentic human developing HD striatal tissue has not previously been characterised. We analysed an HD positive human fetal striatal sample alongside an age- and sex-matched control. CAG-repeat length was determined, and single-cell RNA sequencing was used to investigate gene expression. We compared the fetal HD transcriptional signature with publicly available datasets from postmortem adult HD brain tissue. We identified 2,032 differentially expressed genes and defined nine cellular clusters, each exhibiting distinct transcriptional profiles. Gene enrichment analysis revealed disruption of key biological processes across the developing HD striatum, with pathway-level dysregulation varying between clusters. There was overlap in gene expression changes between fetal and adult HD striatal tissues. Together, these findings demonstrate that molecular features of HD pathology are present during early human striatal development, supporting the concept that disease mechanisms are established decades prior to clinical onset.

Matching journals

The top 9 journals account for 50% of the predicted probability mass.

1
Acta Neuropathologica Communications
89 papers in training set
Top 0.1%
11.8%
2
Brain
168 papers in training set
Top 0.3%
9.7%
3
Neurobiology of Disease
148 papers in training set
Top 0.3%
9.7%
4
Acta Neuropathologica
58 papers in training set
Top 0.2%
6.2%
5
Nature Communications
5641 papers in training set
Top 32%
4.0%
6
Molecular Neurodegeneration
55 papers in training set
Top 0.7%
2.6%
7
PLOS ONE
5266 papers in training set
Top 42%
2.4%
8
JCI Insight
277 papers in training set
Top 3%
2.4%
9
Human Molecular Genetics
141 papers in training set
Top 1.0%
2.4%
50% of probability mass above
10
Brain Communications
166 papers in training set
Top 1%
2.4%
11
npj Parkinson's Disease
105 papers in training set
Top 0.7%
2.4%
12
Movement Disorders
71 papers in training set
Top 0.5%
2.1%
13
Scientific Reports
3612 papers in training set
Top 48%
2.1%
14
Cell Death & Disease
126 papers in training set
Top 1%
2.1%
15
Proceedings of the National Academy of Sciences
2444 papers in training set
Top 25%
2.0%
16
eLife
5828 papers in training set
Top 49%
1.7%
17
EMBO Molecular Medicine
95 papers in training set
Top 0.9%
1.7%
18
Translational Neurodegeneration
10 papers in training set
Top 0.2%
1.4%
19
Journal of Neuroinflammation
61 papers in training set
Top 1.0%
1.3%
20
Science Advances
1243 papers in training set
Top 25%
1.1%
21
Molecular Psychiatry
282 papers in training set
Top 4%
1.1%
22
Neuron
337 papers in training set
Top 4%
1.1%
23
Life Science Alliance
285 papers in training set
Top 5%
1.1%
24
Neurotherapeutics
14 papers in training set
Top 0.2%
1.1%
25
Experimental Neurology
61 papers in training set
Top 1%
1.0%
26
Journal of Biomedical Science
17 papers in training set
Top 0.2%
1.0%
27
Molecular Therapy
81 papers in training set
Top 1%
1.0%
28
Communications Biology
993 papers in training set
Top 25%
1.0%
29
Cell Reports
1498 papers in training set
Top 25%
1.0%
30
Disease Models & Mechanisms
119 papers in training set
Top 3%
0.6%