Svetlana Potapova scite author profile

Laboratory mouse studies are paramount for understanding basic biological phenomena but also have limitations. These include conflicting results caused by divergent microbiota and limited translational research value. To address both shortcomings, we transferred C57BL/6 embryos into wild mice, creating “wildlings.” These mice have a natural microbiota and pathogens at all body sites and the tractable genetics of C57BL/6 mice. The bacterial microbiome, mycobiome, and virome of wildlings affect the immune landscape of multiple organs. Their gut microbiota outcompete laboratory microbiota and demonstrate resilience to environmental challenges. Wildlings, but not conventional laboratory mice, phenocopied human immune responses in two preclinical studies. A combined natural microbiota- and pathogen-based model may enhance the reproducibility of biomedical studies and increase the bench-to-bedside safety and success of immunological studies.

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Neuroblastoma amplified sequence gene is associated with a novel short stature syndrome characterised by optic nerve atrophy and Pelger-Huet anomaly

Максимова¹,

Hara

Nikolaeva³

et al. 2010

Journal of Medical Genetics

117

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BackgroundHereditary short stature syndromes are clinically and genetically heterogeneous disorders and the cause have not been fully identified. Yakuts are a population isolated in Asia; they live in the far east of the Russian Federation and have a high prevalence of hereditary short stature syndrome including 3-M syndrome. A novel short stature syndrome in Yakuts is reported here, which is characterised by autosomal recessive inheritance, severe postnatal growth retardation, facial dysmorphism with senile face, small hands and feet, normal intelligence, Pelger-Huët anomaly of leucocytes, and optic atrophy with loss of visual acuity and colour vision. This new syndrome is designated as short stature with optic atrophy and Pelger-Huët anomaly (SOPH) syndrome.AimsTo identify a causative gene for SOPH syndrome.MethodsGenomewide homozygosity mapping was conducted in 33 patients in 30 families.ResultsThe disease locus was mapped to the 1.1 Mb region on chromosome 2p24.3, including the neuroblastoma amplified sequence (NBAS) gene. Subsequently, 33 of 34 patients were identified with SOPH syndrome and had a 5741G/A nucleotide substitution (resulting in the amino acid substitution R1914H) in the NBAS gene in the homozygous state. None of the 203 normal Yakuts individuals had this substitution in the homozygous state. Immunohistochemical analysis revealed that the NBAS protein is well expressed in retinal ganglion cells, epidermal skin cells, and leucocyte cytoplasm in controls as well as a patient with SOPH syndrome.ConclusionThese findings suggest that function of NBAS may associate with the pathogenesis of short stature syndrome as well as optic atrophy and Pelger-Huët anomaly.

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Meiotic Knockdown and Complementation Reveals Essential Role of RAD51 in Mouse Spermatogenesis

et al. 2017

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SUMMARY Meiotic homologous recombination (HR) is important for proper chromosomal segregation during gametogenesis and facilitates evolutionary adaptation via genomic reshuffling. In most eukaryotes, HR is mediated by two recombinases, the ubiquitous RAD51 and the meiosis-specific DMC1. The role of RAD51 in mammalian meiosis is unclear and study of its function is limited due to embryonic lethality of RAD51 knockouts. Here, we developed an in-vivo meiotic knockdown and protein complementation system to study RAD51 during mouse spermatogenesis. We show that RAD51 is crucial during meiotic prophase and its loss leads to depletion of late prophase I spermatocytes through a p53-dependent apoptotic pathway. This phenotype is distinct from that observed in the DMC1 knockdown. Our meiotic knockdown and complementation system establishes an experimental platform for mechanistic studies of meiotic proteins with unknown functions or essential genes for which a testis-specific knockout is not possible.

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Double-strand break repair plays a role in repeat instability in a fragile X mouse model

et al. 2019

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Expansion of a CGG-repeat tract in the 5'UTR of FMR1 is responsible for the Fragile X-related disorders (FXDs), FXTAS, FXPOI and FXS. Previous work in a mouse model of these disorders has implicated proteins in the base excision and the mismatch repair pathways in the expansion mechanism. However, the precise role of these factors in this process is not well understood. The essential role of MutLγ, a complex that plays a minor role in mismatch repair (MMR) but that is essential for resolving Holliday junctions during meiosis, raises the possibility that expansions proceed via a Holliday junction-like intermediate that is processed to generate a double-strand break (DSB). We show here in an FXD mouse model that LIG4, a ligase essential for nonhomologous end-joining (NHEJ), a form of DSB repair (DSBR), protects against expansions. However, a mutation in MRE11, a nuclease that is important for several other DSBR pathways including homologous recombination (HR), has no effect on the extent of expansion. Our results suggest that the expansion pathway competes with NHEJ for the processing of a DSB intermediate. Thus, expansion likely proceeds via an NHEJ-independent DSBR pathway that may also be HR-independent.

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