Aimee M. Guillotte scite author profile

Lis1 and Ndel1 are essential for animal development. They interact directly with one another and with cytoplasmic dynein. The developing brain is especially sensitive to reduced Lis1 or Ndel1 levels, as both proteins influence spindle orientation, neural cell fate decisions, and neuronal migration. We report here that Lis1 and Ndel1 reduction in a mitotic cell line impairs prophase nuclear envelope (NE) invagination (PNEI). This dynein-dependent process facilitates NE breakdown (NEBD) and occurs before the establishment of the bipolar spindle. Ndel1 phosphorylation is important for this function, regulating binding to both Lis1 and dynein. Prophase cells in the ventricular zone (VZ) of embryonic day 13.5 Lis1+/− mouse brains show reduced PNEI, and the ratio of prophase to prometaphase cells is increased, suggesting an NEBD delay. Moreover, prophase cells in the VZ contain elevated levels of Ndel1 phosphorylated at a key cdk5 site. Our data suggest that a delay in NEBD in the VZ could contribute to developmental defects associated with Lis1–Ndel1 disruption.

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Regulation of Cytoplasmic Dynein ATPase by Lis1

Mesngon

Tarricone

Hebbar

et al. 2006

J. Neurosci.

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Mutations in, but the mechanistic significance of this interaction is not well understood. We now report that recombinant Lis1 binds to native brain dynein and significantly increases the microtubule-stimulated enzymatic activity of dynein in vitro. Lis1 does this without increasing the proportion of dynein that binds to microtubules, indicating that Lis1 influences enzymatic activity rather than microtubule association. Dynein stimulation in vitro is not a generic feature of microtubule-associated proteins, because tau did not stimulate dynein. To our knowledge, this is the first indication that Lis1 or any other factor directly modulates the enzymatic activity of cytoplasmic dynein. Lis1 must be able to homodimerize to stimulate dynein, because a C-terminal fragment (containing the dynein interaction site but missing the self-association domain) was unable to stimulate dynein. Binding and colocalization studies indicate that Lis1 does not interact with all dynein complexes found in the brain. We propose a model in which Lis1 stimulates the activity of a subset of motors, which could be particularly important during neuronal migration and long-distance axonal transport.

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Characterization of inositol phospho-sphingolipid-phospholipase C 1 (Isc1) inCryptococcus neoformansreveals unique biochemical features

Henry

Guillotte

Luberto

et al. 2011

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a b s t r a c tIn this work, we biochemically characterized inositol phosphosphingolipid-phospholipase C (Isc1) from the pathogenic fungus Cryptococcus neoformans. Unlike Isc1 from other fungi and parasites which hydrolyze both fungal complex sphingolipids (IPC-PLC) and mammalian sphingomyelin (SM-PLC), C. neoformans Isc1 only exerts IPC-PLC activity. Genetic mutations thought to regulate substrate recognition in other Isc1 proteins do not restore SM-PLC activity of the cryptococcal enzyme. C. neoformans Isc1 regulates the level of complex sphingolipids and certain species of phytoceramide, especially when fungal cells are exposed to acidic stress. Since growth in acidic environments is required for C. neoformans to cause disease, this study has important implications for understanding of C. neoformans pathogenicity.

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Genetic Enhancement of the Lis1+/– Phenotype by a Heterozygous Mutation in the Adenomatous Polyposis Coli Gene

et al. 2007

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Hemizygous Lis1 mutations cause type 1 lissencephaly, a neuronal migration disorder in humans. The Lis1+/– mouse is a model for lissencephaly; mice exhibit neuronal migration defects but are viable and fertile. On an inbred genetic background, 20% of Lis1+/– mice develop hydrocephalus and die prematurely. Lis1 functions with the microtubule motor cytoplasmic dynein. Because dynactin, a dynein regulator, interacts with end-binding protein 1 (EB1) and β-catenin, two known binding partners of the adenomatous polyposis coli (APC) protein, we looked for a genetic interaction between Lis1 and APC. Mice with a heterozygous truncating mutation in APC (Min mutation) do not exhibit neuronal migration defects or develop hydrocephalus. However, the presence of the APC mutation increases the migration deficit and the incidence of hydrocephalus in Lis1+/– animals. Lis1 and dynein distribution is altered in cells derived from Min mice, and both Lis1 and dynein interact with the C terminus of APC in vitro. Together, our findings point to a previously unknown interaction between APC and Lis1 during mammalian brain development.

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Lis1 Immunofluorescence Reveals Rings and Lattices

2004

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