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Start date: 2023Subject: search.filters.subject.HDAC4

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    N-terminal oligomerization drives HDAC4 nuclear condensation and neurodevelopmental dysfunction in Drosophila
    (The Royal Society, 2025-10) Hawley HR; Sutherland-Smith AJ; Savoian MS; Fitzsimons HL
    Histone deacetylase four (HDAC4) undergoes dynamic nucleocytoplasmic shuttling, a process critical for regulating its activity. However, aberrant nuclear accumulation of HDAC4 is associated with both neurodevelopmental and neurodegenerative disease, and in our Drosophila model, impairs normal neuronal development. Upon nuclear accumulation, HDAC4 forms biomolecular condensates, previously termed aggregates, that correlate with the severity of defects in development of the Drosophila mushroom body and adult eye. Here we determined that nuclear condensation of HDAC4 is dependent on self-oligomerization, and that impairing oligomerization reduces condensation and the severity of neurodevelopmental phenotypes in Drosophila. HDAC4 condensates are highly dynamic and are stabilized by the presence of MEF2, which promotes their formation, ultimately exacerbating phenotypic severity. These data provide insight into the role of HDAC4 condensates in normal neuronal function and suggest that their dysregulation may contribute to neurodevelopmental disorders. Consequently, targeting oligomerization of HDAC4 and its interaction with MEF2 present potential therapeutic strategies for diseases associated with HDAC4 nuclear accumulation.
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    Characterising CG5846 (Peep) in Drosophila melanogaster neural function : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Biochemistry at Massey University, Manawatū, New Zealand
    (Massey University, 2024) Wilson, Sarah Jean
    Histone deacetylase 4 (HDAC4) is a transcriptional regulator that has been implicated in a number of neurodevelopmental and neurodegenerative diseases that are associated with intellectual disability, cognitive defects, and/or memory loss. Both the accumulation of nuclear HDAC4 and its loss-of-function have been linked to these conditions, therefore exploring HDAC4’s role in neuronal function is essential to understand the molecular mechanisms underlying these diseases. In Drosophila, overexpression of HDAC4 results in defects in morphogenesis of axons in the mushroom body, a structure essential for memory formation, as well as long-term memory defects and disruption to the development of the compound eye. The molecular mechanisms underlying these HDAC4-induced phenotypes are currently unknown. RNA-sequencing on fly heads in which HDAC4 was overexpressed has previously been performed and showed few genes were transcriptionally regulated by HDAC4. In addition, an enhancer/suppressor rough eye phenotype screen has also been performed which identified a number of genes that interact genetically in the same molecular pathway as HDAC4. To further investigate the molecular mechanisms underlying HDAC4 dysfunction, an RNA interference (RNAi) based candidate screen for potential HDAC4-interactors was performed, which involved quantification of developmental defects in the mushroom body and eye following RNAi knockdown of each candidate. It was hypothesised that if a phenotype resulting from RNAi knockdown was similar to that induced by HDAC4 overexpression, that candidate may function in similar molecular pathways. A single candidate-interactor was selected (CG5846, named Peep) for further investigation. On overexpression, Peep and HDAC4 co- distribute in nuclei of mushroom body neurons, however no physical interaction was detected. Furthermore, overexpression of Peep did not rescue the HDAC4-induced mushroom body or eye defects. Due to the uncharacterised nature of Peep, a thorough investigation was performed to assess the importance of Peep in survival, longevity, motor function, brain development, courtship learning and memory, and wing development. Peep was observed to be essential for survival of glial cells and for normal mushroom body development, which warrants further investigation. Reduced expression of Peep also resulted in a unique severe necrotic eye phenotype, and through this, Peep was shown to play a potential role in processes involved in regulating mitochondrial and proteasomal function, apoptosis and oxidative stress. These data provide the first documented characterisation of the functional role of Peep in Drosophila development and provide the basis for further investigation into the underlying molecular mechanisms involved in mushroom body and eye development.
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    Ankyrin2 is essential for neuronal morphogenesis and long-term courtship memory in Drosophila.
    (BioMed Central Ltd, 2023-05-16) Schwartz S; Wilson SJ; Hale TK; Fitzsimons HL
    Dysregulation of HDAC4 expression and/or nucleocytoplasmic shuttling results in impaired neuronal morphogenesis and long-term memory in Drosophila melanogaster. A recent genetic screen for genes that interact in the same molecular pathway as HDAC4 identified the cytoskeletal adapter Ankyrin2 (Ank2). Here we sought to investigate the role of Ank2 in neuronal morphogenesis, learning and memory. We found that Ank2 is expressed widely throughout the Drosophila brain where it localizes predominantly to axon tracts. Pan-neuronal knockdown of Ank2 in the mushroom body, a region critical for memory formation, resulted in defects in axon morphogenesis. Similarly, reduction of Ank2 in lobular plate tangential neurons of the optic lobe disrupted dendritic branching and arborization. Conditional knockdown of Ank2 in the mushroom body of adult Drosophila significantly impaired long-term memory (LTM) of courtship suppression, and its expression was essential in the γ neurons of the mushroom body for normal LTM. In summary, we provide the first characterization of the expression pattern of Ank2 in the adult Drosophila brain and demonstrate that Ank2 is critical for morphogenesis of the mushroom body and for the molecular processes required in the adult brain for the formation of long-term memories.
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    Investigating HDAC4 aggregation in a Drosophila model of neuronal development : a dissertation presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Biochemistry at Massey University, Manawatū, New Zealand
    (Massey University, 2024-06-21) Hawley, Hannah Rose
    Histone deacetylase four (HDAC4) is essential in neuronal development and function, and dysregulation of HDAC4 has been observed in a number of neurodevelopmental and neurodegenerative diseases, including Alzheimer’s and Parkinson’s diseases. In particular, its aberrant nuclear accumulation is a common feature among these diseases, and it has been observed that upon upregulation or accumulation in the nucleus, HDAC4 forms punctate foci in neuronal nuclei. Previous research in a Drosophila model determined that overexpression of HDAC4 disrupted both neuronal development and long-term memory, and this was largely mediated by the nuclear pool of HDAC4. Based on these data, it was hypothesised that aggregates of HDAC4 are responsible for the neurotoxicity that leads to disrupted neurodevelopment and memory. Therefore, this study aimed to determine whether the presence of HDAC4 nuclear aggregates correlated with neurodevelopmental deficits in a Drosophila model of neurodevelopment, and if so, how they mediate their toxic effects. The N-terminus of HDAC4 forms homo-oligomers in solution, and it was hypothesised that full-length HDAC4 similarly oligomerises, and that this is required for its aggregation in neuronal nuclei. Mutations predicted to prevent oligomerisation were introduced into the N- terminus of HDAC4 and were shown to significantly reduce aggregation of HDAC4 in Drosophila neurons. Furthermore, their presence also reduced the severity of HDAC4 overexpression-induced impairments in neurodevelopment. Conversely, stabilisation of oligomerisation increased aggregation and the severity of neurodevelopmental phenotypes, together indicating that aggregation positively correlates with the severity of neurodevelopmental deficits. HDAC4 aggregates have been previously shown to sequester the transcription factor MEF2, and further investigation revealed that the presence of MEF2 stabilised aggregation and increased the severity of defects in neuronal development. Importantly, targeting the interaction between HDAC4 and MEF2 reduced the severity of these defects. Other than MEF2, the composition of HDAC4 aggregates is unknown, and therefore immunoprecipitation-coupled mass spectrometry was performed on nuclear HDAC4 to identify candidate interactors of aggregates. This revealed a number of proteins with roles in neuronal development and function, as well as those involved in splicing and protein homeostasis, suggesting that aggregates may be impairing these processes to mediate toxicity. Together these data indicate that nuclear aggregation of HDAC4 impairs neurodevelopment, and may constitute a novel biomarker of disease or therapeutic target. Given the overlap in aetiology between neurodevelopmental and neurodegenerative diseases, further investigation of whether HDAC4 aggregation contributes to the severity and/or progression of neurodegenerative disorders is warranted.
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    Deciphering the roles of subcellular distribution and interactions involving the MEF2 binding region, the ankyrin repeat binding motif and the catalytic site of HDAC4 in Drosophila neuronal morphogenesis
    (BioMed Central Ltd, 2024-12) Tan WJ; Hawley HR; Wilson SJ; Fitzsimons HL
    BACKGROUND: Dysregulation of nucleocytoplasmic shuttling of histone deacetylase 4 (HDAC4) is associated with several neurodevelopmental and neurodegenerative disorders. Consequently, understanding the roles of nuclear and cytoplasmic HDAC4 along with the mechanisms that regulate nuclear entry and exit is an area of concerted effort. Efficient nuclear entry is dependent on binding of the transcription factor MEF2, as mutations in the MEF2 binding region result in cytoplasmic accumulation of HDAC4. It is well established that nuclear exit and cytoplasmic retention are dependent on 14-3-3-binding, and mutations that affect binding are widely used to induce nuclear accumulation of HDAC4. While regulation of HDAC4 shuttling is clearly important, there is a gap in understanding of how the nuclear and cytoplasmic distribution of HDAC4 impacts its function. Furthermore, it is unclear whether other features of the protein including the catalytic site, the MEF2-binding region and/or the ankyrin repeat binding motif influence the distribution and/or activity of HDAC4 in neurons. Since HDAC4 functions are conserved in Drosophila, and increased nuclear accumulation of HDAC4 also results in impaired neurodevelopment, we used Drosophila as a genetic model for investigation of HDAC4 function. RESULTS: Here we have generated a series of mutants for functional dissection of HDAC4 via in-depth examination of the resulting subcellular distribution and nuclear aggregation, and correlate these with developmental phenotypes resulting from their expression in well-established models of neuronal morphogenesis of the Drosophila mushroom body and eye. We found that in the mushroom body, forced sequestration of HDAC4 in the nucleus or the cytoplasm resulted in defects in axon morphogenesis. The actions of HDAC4 that resulted in impaired development were dependent on the MEF2 binding region, modulated by the ankyrin repeat binding motif, and largely independent of an intact catalytic site. In contrast, disruption to eye development was largely independent of MEF2 binding but mutation of the catalytic site significantly reduced the phenotype, indicating that HDAC4 acts in a neuronal-subtype-specific manner. CONCLUSIONS: We found that the impairments to mushroom body and eye development resulting from nuclear accumulation of HDAC4 were exacerbated by mutation of the ankyrin repeat binding motif, whereas there was a differing requirement for the MEF2 binding site and an intact catalytic site. It will be of importance to determine the binding partners of HDAC4 in nuclear aggregates and in the cytoplasm of these tissues to further understand its mechanisms of action.
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    Ankyrin2 is essential for neuronal morphogenesis and long-term courtship memory in Drosophila
    (BioMed Central Ltd, 2023-05-16) Schwartz S; Wilson SJ; Hale TK; Fitzsimons HL
    Dysregulation of HDAC4 expression and/or nucleocytoplasmic shuttling results in impaired neuronal morphogenesis and long-term memory in Drosophila melanogaster. A recent genetic screen for genes that interact in the same molecular pathway as HDAC4 identified the cytoskeletal adapter Ankyrin2 (Ank2). Here we sought to investigate the role of Ank2 in neuronal morphogenesis, learning and memory. We found that Ank2 is expressed widely throughout the Drosophila brain where it localizes predominantly to axon tracts. Pan-neuronal knockdown of Ank2 in the mushroom body, a region critical for memory formation, resulted in defects in axon morphogenesis. Similarly, reduction of Ank2 in lobular plate tangential neurons of the optic lobe disrupted dendritic branching and arborization. Conditional knockdown of Ank2 in the mushroom body of adult Drosophila significantly impaired long-term memory (LTM) of courtship suppression, and its expression was essential in the γ neurons of the mushroom body for normal LTM. In summary, we provide the first characterization of the expression pattern of Ank2 in the adult Drosophila brain and demonstrate that Ank2 is critical for morphogenesis of the mushroom body and for the molecular processes required in the adult brain for the formation of long-term memories.
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    Increased Abundance of Nuclear HDAC4 Impairs Neuronal Development and Long-Term Memory
    (Frontiers Media, 30/03/2021) Fitzsimons H; Main P; Wheeler D; Tan WJ
    Dysregulation of the histone deacetylase HDAC4 is associated with both neurodevelopmental and neurodegenerative disorders, and a feature common to many of these disorders is impaired cognitive function. HDAC4 shuttles between the nucleus and cytoplasm in both vertebrates and invertebrates and alterations in the amounts of nuclear and/or cytoplasmic HDAC4 have been implicated in these diseases. In Drosophila, HDAC4 also plays a critical role in the regulation of memory, however, the mechanisms through which it acts are unknown. Nuclear and cytoplasmically-restricted HDAC4 mutants were expressed in the Drosophila brain to investigate a mechanistic link between HDAC4 subcellular distribution, transcriptional changes and neuronal dysfunction. Deficits in mushroom body morphogenesis, eye development and long-term memory correlated with increased abundance of nuclear HDAC4 but were associated with minimal transcriptional changes. Although HDAC4 sequesters MEF2 into punctate foci within neuronal nuclei, no alteration in MEF2 activity was observed on overexpression of HDAC4, and knockdown of MEF2 had no impact on long-term memory, indicating that HDAC4 is likely not acting through MEF2. In support of this, mutation of the MEF2 binding site within HDAC4 also had no impact on nuclear HDAC4-induced impairments in long-term memory or eye development. In contrast, the defects in mushroom body morphogenesis were ameliorated by mutation of the MEF2 binding site, as well as by co-expression of MEF2 RNAi, thus nuclear HDAC4 acts through MEF2 to disrupt mushroom body development. These data provide insight into the mechanisms through which dysregulation of HDAC4 subcellular distribution impairs neurological function and provides new avenues for further investigation.