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1. Regulation of proteostasis by sleep through autophagy in Drosophila models of Alzheimer’s disease

   https://doi.org/10.26508/lsa.202402681  

   Ortiz-Vega, Natalie; Lobato, Amanda G; Canic, Tijana; Zhu, Yi; Lazopulo, Stanislav; Syed, Sheyum; Zhai, R Grace (September 2024, Life Science Alliance)

   Sleep and circadian rhythm dysfunctions are common clinical features of Alzheimer’s disease (AD). Increasing evidence suggests that in addition to being a symptom, sleep disturbances can also drive the progression of neurodegeneration. Protein aggregation is a pathological hallmark of AD; however, the molecular pathways behind how sleep affects protein homeostasis remain elusive. Here we demonstrate that sleep modulation influences proteostasis and the progression of neurodegeneration inDrosophilamodels of tauopathy. We show that sleep deprivation enhanced Tau aggregational toxicity resulting in exacerbated synaptic degeneration. In contrast, sleep induction using gaboxadol led to reduced toxic Tau accumulation in neurons as a result of modulated autophagic flux and enhanced clearance of ubiquitinated Tau, suggesting altered protein processing and clearance that resulted in improved synaptic integrity and function. These findings highlight the complex relationship between sleep and regulation of protein homeostasis and the neuroprotective potential of sleep-enhancing therapeutics to slow the progression or delay the onset of neurodegeneration. 

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2. A synaptic molecular dependency network in knockdown of autism- and schizophrenia-associated genes revealed by multiplexed imaging

   https://doi.org/10.1016/j.celrep.2023.112430  

   Falkovich, Reuven; Danielson, Eric W; Perez_de_Arce, Karen; Wamhoff, Eike-C; Strother, Juliana; Lapteva, Anna P; Sheng, Morgan; Cottrell, Jeffrey R; Bathe, Mark (May 2023, Cell Reports)

   The complex functions of neuronal synapses depend on their tightly interconnected protein network, and their dysregulation is implicated in the pathogenesis of autism spectrum disorders and schizophrenia. However, it remains unclear how synaptic molecular networks are altered biochemically in these disorders. Here, we apply multiplexed imaging to probe the effects of RNAi knockdown of 16 autism- and schizophrenia-associated genes on the simultaneous joint distribution of 10 synaptic proteins, observing several protein composition phenotypes associated with these risk genes. We apply Bayesian network analysis to infer hierarchical dependencies among eight excitatory synaptic proteins, yielding predictive relationships that can only be accessed with single-synapse, multiprotein measurements performed simultaneously in situ. Finally, we find that central features of the network are affected similarly across several distinct gene knockdowns. These results offer insight into the convergent molecular etiology of these widespread disorders and provide a general framework to probe subcellular molecular networks. 

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3. The KASH5 protein involved in meiotic chromosomal movements is a novel dynein activating adaptor

   https://doi.org/10.7554/eLife.78201  

   Agrawal, Ritvija; Gillies, John P; Zang, Juliana L; Zhang, Jingjing; Garrott, Sharon R; Shibuya, Hiroki; Nandakumar, Jayakrishnan; DeSantis, Morgan E (June 2022, eLife)

   Dynein harnesses ATP hydrolysis to move cargo on microtubules in multiple biological contexts. Dynein meets a unique challenge in meiosis by moving chromosomes tethered to the nuclear envelope to facilitate homolog pairing essential for gametogenesis. Though processive dynein motility requires binding to an activating adaptor, the identity of the activating adaptor required for dynein to move meiotic chromosomes is unknown. We show that the meiosis-specific nuclear-envelope protein KASH5 is a dynein activating adaptor: KASH5 directly binds dynein using a mechanism conserved among activating adaptors and converts dynein into a processive motor. We map the dynein-binding surface of KASH5, identifying mutations that abrogate dynein binding in vitro and disrupt recruitment of the dynein machinery to the nuclear envelope in cultured cells and mouse spermatocytes in vivo. Our study identifies KASH5 as the first transmembrane dynein activating adaptor and provides molecular insights into how it activates dynein during meiosis. 

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4. Cargo adaptor identity controls the mechanism and kinetics of dynein activation

   https://doi.org/10.1016/j.jbc.2025.108358  

   Gillies, John P; Little, Saffron R; Siva, Aravintha; Hancock, William O; DeSantis, Morgan E (April 2025, Journal of Biological Chemistry)

   Not AvailableCytoplasmic dynein-1 (dynein), the primary retrograde motor in most eukaryotes, supports the movement of hundreds of distinct cargos, each with specific trafficking requirements. To achieve this functional diversity, dynein must bind to the multi-subunit complex dynactin and one of a family of cargo adaptors to be converted into an active, processive motor complex. Very little is known about the dynamic processes that promote the formation of this complex. To delineate the kinetic steps that lead to dynein activation, we developed a single-molecule fluorescence assay to visualize the real-time formation of dynein-dynactin-adaptor complexes in vitro. We found that dynactin and adaptors bind dynein independently rather than cooperatively. We also found that different dynein adaptors promote dynein-dynactin-adaptor assembly with dramatically different kinetics, which results in complex formation occurring via different assembly pathways. Despite differences in association rates or mechanism of assembly, all adaptors tested can generate a population of tripartite complexes that are very stable. Our work provides a model for how modulating the kinetics of dynein-dynactin-adaptor binding can be harnessed to promote differential dynein activation and reveals a new facet of the functional diversity of the dynein motor. 

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5. Temporal and Cell‐Specific Regulation of Synaptic Homeostasis by the Chromatin Remodeler Chd1

   https://doi.org/10.1002/advs.202510538  

   Morency, Danielle T; Cui, Tao; Cai, Yimei; Lok, Chloe; Nokku, Rachel E; Huang, Ruoxian; Chu, Grace L; Xie, Yumeng; Abu‐Tayeh, Saleem W; He, Kaikai; et al (March 2026, Advanced Science)

   ABSTRACT Disruptions in chromatin remodelers and synaptic proteins represent major genetic risk factors for autism spectrum disorder (ASD), yet how these distinct gene classes converge to impair circuit function remains unclear.CHD2, a chromatin remodeler linked to ASD, epilepsy, and intellectual disability, regulates gene expression through epigenetic mechanisms. InDrosophila, its homologueChd1functions as a key regulator of presynaptic homeostatic potentiation (PHP), a conserved form of synaptic plasticity that stabilizes neurotransmission. Electrophysiology, calcium imaging, super‐resolution microscopy, behavioral assays, and machine learning‐based analysis reveal thatChd1acts in a temporal and cell type‐specific manner: it is required in perineurial glia for rapid PHP induction and in motoneurons, muscle, and glia for long‐term maintenance.Chd1controls presynaptic calcium influx and expansion of the readily releasable vesicle pool, both core features of homeostatic compensation. An electrophysiology‐based genetic screen guided by unsupervised machine learning identifies 14Chd1‐dependent genes necessary for acute PHP, including the glial‐specific effectorCadherin 74A. Loss ofChd1increases seizure susceptibility and disrupts motor function, mirroring phenotypes observed inCHD2‐related neurodevelopmental disorders. These findings establish a mechanistic connection between chromatin remodeling and synaptic homeostasis and identify glial epigenetic regulation as a critical modulator of circuit stability in health and disease. 

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