Your search keyword '"Holt MG"' showing total 5 results

1. Traumatic brain injury promotes neurogenesis at the cost of astrogliogenesis in the adult hippocampus of male mice.

Author

Bielefeld P, Martirosyan A, Martín-Suárez S, Apresyan A, Meerhoff GF, Pestana F, Poovathingal S, Reijner N, Koning W, Clement RA, Van der Veen I, Toledo EM, Polzer O, Durá I, Hovhannisyan S, Nilges BS, Bogdoll A, Kashikar ND, Lucassen PJ, Belgard TG, Encinas JM, Holt MG, and Fitzsimons CP

Subjects

Animals, Male, Mice, Neurons metabolism, Mice, Inbred C57BL, Dentate Gyrus pathology, Disease Models, Animal, Cell Differentiation, Transcriptome, Brain Injuries, Traumatic pathology, Brain Injuries, Traumatic physiopathology, Neurogenesis, Hippocampus pathology, Hippocampus cytology, Astrocytes metabolism, Neural Stem Cells metabolism, Neural Stem Cells cytology

Abstract

Traumatic brain injury (TBI) can result in long-lasting changes in hippocampal function. The changes induced by TBI on the hippocampus contribute to cognitive deficits. The adult hippocampus harbors neural stem cells (NSCs) that generate neurons (neurogenesis), and astrocytes (astrogliogenesis). While deregulation of hippocampal NSCs and neurogenesis have been observed after TBI, it is not known how TBI may affect hippocampal astrogliogenesis. Using a controlled cortical impact model of TBI in male mice, single cell RNA sequencing and spatial transcriptomics, we assessed how TBI affected hippocampal NSCs and the neuronal and astroglial lineages derived from them. We observe an increase in NSC-derived neuronal cells and a concomitant decrease in NSC-derived astrocytic cells, together with changes in gene expression and cell dysplasia within the dentate gyrus. Here, we show that TBI modifies NSC fate to promote neurogenesis at the cost of astrogliogenesis and identify specific cell populations as possible targets to counteract TBI-induced cellular changes in the adult hippocampus., (© 2024. The Author(s).)

Published

2024

2. A conformational switch controlling the toxicity of the prion protein.

Author

Frontzek K, Bardelli M, Senatore A, Henzi A, Reimann RR, Bedir S, Marino M, Hussain R, Jurt S, Meisl G, Pedotti M, Mazzola F, Siligardi G, Zerbe O, Losa M, Knowles T, Lakkaraju A, Zhu C, Schwarz P, Hornemann S, Holt MG, Simonelli L, Varani L, and Aguzzi A

Subjects

Animals, Antibodies metabolism, Cerebellum metabolism, Ligands, Mice, Prion Proteins chemistry, Prion Proteins genetics, Prion Proteins metabolism, PrPC Proteins chemistry, PrPC Proteins genetics, Prions metabolism, Prions toxicity

Abstract

Prion infections cause conformational changes of the cellular prion protein (PrP C ) and lead to progressive neurological impairment. Here we show that toxic, prion-mimetic ligands induce an intramolecular R208-H140 hydrogen bond ('H-latch'), altering the flexibility of the α2-α3 and β2-α2 loops of PrP C . Expression of a PrP 2Cys mutant mimicking the H-latch was constitutively toxic, whereas a PrP R207A mutant unable to form the H-latch conferred resistance to prion infection. High-affinity ligands that prevented H-latch induction repressed prion-related neurodegeneration in organotypic cerebellar cultures. We then selected phage-displayed ligands binding wild-type PrP C , but not PrP 2Cys . These binders depopulated H-latched conformers and conferred protection against prion toxicity. Finally, brain-specific expression of an antibody rationally designed to prevent H-latch formation prolonged the life of prion-infected mice despite unhampered prion propagation, confirming that the H-latch is an important reporter of prion neurotoxicity., (© 2022. The Author(s).)

Published

2022

3. Identification of region-specific astrocyte subtypes at single cell resolution.

Author

Batiuk MY, Martirosyan A, Wahis J, de Vin F, Marneffe C, Kusserow C, Koeppen J, Viana JF, Oliveira JF, Voet T, Ponting CP, Belgard TG, and Holt MG

Subjects

Animals, Astrocytes metabolism, Calcium Signaling, Cell Shape, Gene Expression Regulation, Mice, Inbred C57BL, Neurogenesis genetics, RNA, Messenger genetics, RNA, Messenger metabolism, Astrocytes cytology, Organ Specificity genetics, Single-Cell Analysis

Abstract

Astrocytes, a major cell type found throughout the central nervous system, have general roles in the modulation of synapse formation and synaptic transmission, blood-brain barrier formation, and regulation of blood flow, as well as metabolic support of other brain resident cells. Crucially, emerging evidence shows specific adaptations and astrocyte-encoded functions in regions, such as the spinal cord and cerebellum. To investigate the true extent of astrocyte molecular diversity across forebrain regions, we used single-cell RNA sequencing. Our analysis identifies five transcriptomically distinct astrocyte subtypes in adult mouse cortex and hippocampus. Validation of our data in situ reveals distinct spatial positioning of defined subtypes, reflecting the distribution of morphologically and physiologically distinct astrocyte populations. Our findings are evidence for specialized astrocyte subtypes between and within brain regions. The data are available through an online database (https://holt-sc.glialab.org/), providing a resource on which to base explorations of local astrocyte diversity and function in the brain.

Published

2020

4. Differential centrifugation-based biochemical fractionation of the Drosophila adult CNS.

Author

Depner H, Lützkendorf J, Babkir HA, Sigrist SJ, and Holt MG

Subjects

Animals, Drosophila Proteins chemistry, Drosophila Proteins isolation & purification, Head, Reproducibility of Results, Synaptic Transmission, Synaptosomes chemistry, Workflow, Central Nervous System chemistry, Centrifugation methods, Chemical Fractionation methods, Drosophila chemistry, Synapses chemistry

Abstract

Drosophila is widely used as a genetic model in questions of development, cellular function and disease. Genetic screens in flies have proven to be incredibly powerful in identifying crucial components for synapse formation and function, particularly in the case of the presynaptic release machinery. Although modern biochemical methods can identify individual proteins and lipids (and their binding partners), they have typically been excluded from use in Drosophila for technical reasons. To bridge this essential gap between genetics and biochemistry, we developed a fractionation method to isolate various parts of the synaptic machinery from Drosophila, thus allowing it to be studied in unprecedented biochemical detail. This is only possible because our protocol has unique advantages in terms of enriching and preserving endogenous protein complexes. The procedure involves decapitation of adult flies, homogenization and differential centrifugation of fly heads, which allow subsequent purification of presynaptic (and to a limited degree postsynaptic) components. It is designed to require only a rudimentary knowledge of biochemical fractionation, and it takes ∼3.5 h. The yield is typically 4 mg of synaptic membrane protein per gram of Drosophila heads.

Published

2014

5. One SNARE complex is sufficient for membrane fusion.

Author

van den Bogaart G, Holt MG, Bunt G, Riedel D, Wouters FS, and Jahn R

Subjects

Electrophoresis, Polyacrylamide Gel, Fluorescence Resonance Energy Transfer, Liposomes chemistry, Models, Biological, Membrane Fusion physiology, SNARE Proteins chemistry, SNARE Proteins metabolism

Abstract

In eukaryotes, most intracellular membrane fusion reactions are mediated by the interaction of SNARE proteins that are present in both fusing membranes. However, the minimal number of SNARE complexes needed for membrane fusion is not known. Here we show unambiguously that one SNARE complex is sufficient for membrane fusion. We performed controlled in vitro Förster resonance energy transfer (FRET) experiments and found that liposomes bearing only a single SNARE molecule are still capable of fusion with other liposomes or with purified synaptic vesicles. Furthermore, we demonstrated that multiple SNARE complexes do not act cooperatively, showing that synergy between several SNARE complexes is not needed for membrane fusion. Our findings shed new light on the mechanism of SNARE-mediated membrane fusion and call for a revision of current views of fusion events such as the fast release of neurotransmitters.

Published

2010