Jan-Matthias Braun scite author profile

Many mouse models are currently available, providing avenues to elucidate gene function and to recapitulate specific pathological conditions. To a large extent, successful translation of clinical evidence or analytical data into appropriate mouse models is possible through progress in transgenic or gene-targeting technology. Beginning with a review of standard mouse transgenics and conventional gene targeting, this article will move on to discussing the basics of conditional gene expression: the tetracycline (tet)-off and tet-on systems based on the transactivators tet-controlled transactivator (Tta) and reverse tet-on transactivator (rtTA) that allow downregulation or induction of gene expression; Cre or Flp recombinase-mediated modifications, including excision, inversion, insertion and interchromosomal translocation; combination of the tet and Cre systems, permitting inducible knockout, reporter gene activation or activation of point mutations; the avian retroviral system based on delivery of rtTA specifically into cells expressing the avian retroviral receptor, which enables cell type-specific, inducible gene expression; the tamoxifen system, one of the most frequently applied steroid receptor-based systems, allows rapid activation of a fusion protein between the gene of interest and a mutant domain of the estrogen receptor, whereby activation does not depend on transcription; and techniques for cell type-specific ablation. The diphtheria toxin receptor system offers the advantage that it can be combined with the 'zoo' of Cre recombinase driver mice. Having described the basics we move on to the cutting edge: generation of genome-wide sets of conditional knockout mice. To this end, large ongoing projects apply two strategies: gene trapping based on random integration of trapping vectors into introns leading to truncation of the transcript, and gene targeting, representing the directed approach using homologous recombination. It can be expected that in the near future genome-wide sets of such mice will be available. Finally, the possibilities of conditional expression systems for investigating gene function in tissue regeneration will be illustrated by examples for neurodegenerative disease, liver regeneration and wound healing of the skin.

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Impaired mitochondrial Ca2+ homeostasis in respiratory chain-deficient cells but efficient compensation of energetic disadvantage by enhanced anaerobic glycolysis due to low ATP steady state levels

Kleist-Retzow

Hornig-Do

Schauen

et al. 2007

Experimental Cell Research

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Proinflammatory Responses to Lipo‐oligosaccharide ofNeisseria meningitidisImmunotype Strains in Relation to Virulence and Disease

et al. 2002

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Inflammatory responses to lipo-oligosaccharide (LOS) contribute to the severity of meningococcal disease. Strains that express the L(3,7,9) LOS immunotypes are isolated from the majority of patients, but other immunotypes are isolated predominantly from carriers. Inflammatory responses elicited from a human monocytic cell line (THP-1) that had been pretreated with vitamin D3 (VD3) were compared after stimulation with purified LOSs from standard immunotype strains. The neutralizing effects of normal human serum and serum from mice immunized with strain B:2a:P1.5,2:L3 were compared. LOSs of immunotypes L3, L7, L8, and L9 induced significantly higher levels of tumor necrosis factor-alpha and interleukin-6, compared with other immunotypes. Normal human serum neutralized the proinflammatory responses to LOSs of all immunotypes tested. Immune mouse serum neutralized inflammatory responses against LOSs from immunotypes with epitopes cross-reactive with L(3,7,9) moieties. Antibodies found in normal human serum and immune mouse serum to the oligosaccharide, core, and lipid A moieties of meningococcal endotoxin contribute to neutralizing activity.

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Rabbit neurospheres as a novel in vitro tool for studying neurodevelopmental effects induced by intrauterine growth restriction

Barenys

Illa

Hofrichter

et al. 2020

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The aim of this study was to develop a rabbit neurosphere culture to characterize differences in basic processes of neurogenesis induced by intrauterine growth restriction (IUGR). A novel in vitro neurosphere culture has been established using fresh or frozen neural progenitor cells from newborn (PND0) rabbit brains. After surgical IUGR induction in pregnant rabbits and cesarean section 5 days later, neural progenitor cells from both control and IUGR groups were isolated and directly cultured or frozen at −80 C. These neural progenitor cells spontaneously formed neurospheres after 7 days in culture. The ability of control and IUGR neurospheres to migrate, proliferate, differentiate to neurons, astrocytes, or oligodendrocytes was compared and the possibility to modulate their responses was tested by exposure to several positive and negative controls. Neurospheres obtained from IUGR brains have a significant impairment in oligodendrocyte differentiation, whereas no significant differences are observed in other basic processes of neurogenesis. This impairment can be reverted by in vitro exposure of IUGR neurospheres to thyroid hormone, which is known to play an essential role in white matter maturation in vivo. Our new rabbit neurosphere model and the results of this study open the possibility to test several substances in vitro as neuroprotective candidates against IUGR induced neurodevelopmental damage while decreasing the number of animals and resources and allowing a more mechanistic approach at a cellular functional level.

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