Lauren C. Boudewyn scite author profile

Changes in neuronal structure are thought to underlie long-term behavioral modifications associated with learning and memory. In particular, considerable evidence implicates the destabilization and retraction of dendritic spines along with the loss of spine synapses as an important cellular mechanism for refining brain circuits, yet the molecular mechanisms regulating spine elimination remain ill-defined. The postsynaptic density protein, PSD-95, is highly enriched in dendritic spines and has been associated with spine stability. Because spines with low levels of PSD-95 are more dynamic, and the recruitment of PSD-95 to nascent spines has been associated with spine stabilization, we hypothesized that loss of PSD-95 enrichment would be a prerequisite for spine retraction. To test this hypothesis, we used dual-color time-lapse two-photon microscopy to monitor rat hippocampal pyramidal neurons co-transfected with PSD-95-GFP and DsRed-Express, and we analyzed the relationship between PSD-95-GFP enrichment and spine morphological changes. Consistent with our hypothesis, we found that the majority of spines that retracted were relatively unenriched for PSD-95-GFP. However, in the subset of PSD-95-GFP-enriched spines that retracted, spine shrinkage and loss of PSD-95-GFP were tightly coupled, suggesting that loss of PSD-95-GFP enrichment did not precede spine retraction. Moreover, we found that in some instances spine retraction resulted in a significant enrichment of PSD-95-GFP on the dendritic shaft. Our data support a model of spine retraction in which loss of PSD-95 enrichment is not required prior to the destabilization of spines.

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Current concepts in the neuropathogenesis of mucolipidosis type IV

Boudewyn

Walkley

2018

Journal of Neurochemistry

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Mucolipidosis type IV (MLIV) is an autosomal recessive, lysosomal storage disorder causing progressively severe intellectual disability, motor and speech deficits, retinal degeneration often culminating in blindness, and systemic disease causing a shortened lifespan. MLIV results from mutations in the gene MCOLN1 encoding the transient receptor potential channel mucolipin-1. It is an ultra-rare disease and is currently known to affect just over 100 diagnosed individuals. The last decade has provided a wealth of research focused on understanding the role of the enigmatic mucolipin-1 protein in cell and brain function and how its absence causes disease. This review explores our current understanding of the mucolipin-1 protein in relation to neuropathogenesis in MLIV and describes recent findings implicating mucolipin-1's important role in mechanistic target of rapamycin and TFEB (transcription factor EB) signaling feedback loops as well as in the function of the greater endosomal/lysosomal system. In addition to addressing the vital role of mucolipin-1 in the brain, we also report new data on the question of whether haploinsufficiency as would be anticipated in MCOLN1 heterozygotes is associated with any evidence of neuron dysfunction or disease. Greater insights into the role of mucolipin-1 in the nervous system can be expected to shed light not only on MLIV disease but also on numerous processes governing normal brain function. This article is part of the Special Issue "Lysosomal Storage Disorders".

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N-butyldeoxynojirimycin delays motor deficits, cerebellar microgliosis, and Purkinje cell loss in a mouse model of mucolipidosis type IV

Boudewyn

Sikora

Kuchař

et al. 2017

Neurobiology of Disease

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Mucolipidosis type IV (MLIV) is a lysosomal storage disease exhibiting progressive intellectual disability, motor impairment, and premature death. There is currently no cure or corrective treatment. The disease results from mutations in the gene encoding mucolipin-1, a transient receptor potential channel believed to play a key role in lysosomal calcium egress. Loss of mucolipin-1 and subsequent defects lead to a host of cellular aberrations, including accumulation of glycosphingolipids (GSLs) in neurons and other cell types, microgliosis and, as reported here, cerebellar Purkinje cell loss. Several studies have demonstrated that N-butyl-deoxynojirimycin (NB-DNJ, also known as miglustat), an inhibitor of the enzyme glucosylceramide synthase (GCS), successfully delays the onset of motor deficits, improves longevity, and rescues some of the cerebellar abnormalities (e.g., Purkinje cell death) seen in another lysosomal disease known as Niemann-Pick type C (NPC). Given the similarities in pathology between MLIV and NPC, we examined whether miglustat would be efficacious in ameliorating disease progression in MLIV. Using a full mucolipin-1 knockout mouse (Mcoln1−/−), we found that early miglustat treatment delays the onset and progression of motor deficits, delays cerebellar Purkinje cell loss, and reduces cerebellar microgliosis characteristic of MLIV disease. Quantitative mass spectrometry analyses provided new data on the GSL profiles of murine MLIV brain tissue and showed that miglustat partially restored the wild type profile of white matter enriched lipids. Collectively, our findings indicate that early miglustat treatment delays the progression of clinically relevant pathology in an MLIV mouse model, and therefore supports consideration of miglustat as a therapeutic agent for MLIV disease in humans.

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Characterization of Dendritogenesis in Cortical Pyramidal Layer V Neurons in Niemann‐Pick Type C Disease Using Yellow Fluorescent Protein

et al. 2015

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Niemann‐Pick type C (NPC) disease is an autosomal recessive lysosomal storage disorder affecting mostly children, causing progressive neurological deterioration and death. NPC disease is caused by a mutation in either the NPC1 or NPC2 gene, leading to a loss of functional NPC1 or NPC2 protein. These proteins play a role in lipid egress from late endosomes and lysosomes, a deficiency in either results in intracellular accumulation of unesterified cholesterol and gangliosides. Storage is prominent in neurons, influencing cellular pathology, such as growth of ectopic dendrites on pyramidal neurons. This aberrant growth of dendrites following normal dendritogenesis has been documented in several lysosomal diseases characterized by ganglioside storage. Until recently, the visualization of this process depended on the Golgi method. New techniques, such as endogenous expression of fluorescent proteins, provide an in‐depth analysis of neuronal structure. We hypothesized that the accumulation of gangliosides in NPC disease will cause an initial enhancement of dendritogenesis along with ectopic dendrite growth followed by a subsequent degeneration of dendritic trees later in disease. Subsequently, we generated a transgenic Npc1 murine mouse model whose layer V cortical pyramidal neurons express yellow fluorescent protein (YFP) to investigate the dendritic abnormalities of NPC disease relative to lysosomal storage. Confocal imaging and Neurolucida Software are being used to image YFP+ pyramidal neurons, which will be analyzed for changes in dendritic size, complexity and pathological state.

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Assessment of n-butyl-deoxynojirimycin as a therapeutic option for mucolipidosis type IV

Boudewyn

Sikora²,

Kuchař³

et al. 2016

Molecular Genetics and Metabolism

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