Mutations in the Mouse Sharpin Gene Cause the Chronic Proliferative Dermatitis Phenotype

Seymour, Rosemarie

January 2008

No description available.

Developmental genetics

Immune system -- Genetics

Mice -- Development -- Genetics

Immunological characterization and localization of cell cycle regulatory proteins in preimplantation mouse embryos

Leroy, Brendan A.

January 1999

The anticonvulsant drug, Dilantin, in many cases must be taken by epileptic mothers to control seizures during pregnancy, but unfortunately, it has been characterized as a human teratogen. It has also been demonstrated that many of the teratogenic effects of Dilantin occur during postimplantation, but some studies implicate a detrimental role for Dilantin during the preimplantation stages of development. Some of the postimplantation effects include congenital malformations and the potential'loss of the fetus. Our lab has proposed that in preimplantation mouse embryos the drug may be altering the timing of expression of cell cycle regulatory proteins and therefore, we have begun to examine the expression of these proteins. Thus, it was the goal of this study to characterize and localize various cell cycle proteins at specific time points in normal in vivo preimplantation mouse embryos, as this will provide important baseline information for studies on how anticonvulsant drugs may alter cell cycle regulation in embryos.Western blotting has confirmed the presence of cyclin BI in G1 of the first cell cycle. Both cyclin E and CDK2 were not detected in GI or G2/M of the first cell cycle or GI of the second cell cycle.From the immunogold TEM experiments, the density of cyclin B1 staining was observed to be the highest at G1 of the first cell cycle and declined at S and G2/M. Cyclin B 1 was detected in all regions of the embryo including the microvilli, cortical cytoplasm, interior cytoplasm, and was observed to be associated with vesicles and some filaments. The gold particles at GI, S, and G2/N4 of the first cell cycle and G1 of the second cell cycle appear to be associated with filamentous and membraneous structures and not free in the cytoplasmic spaces. Cyclin B 1 expression was more concentrated around vesicles at G1 of the first cell cycle and in general, was more concentrated around vesicles than in microvilli and cortical cytoplasm, interior cytoplasm, or around filaments at each cell cycle stage tested. / Department of Biology

Teratogenicity testing.

Anticonvulsants -- Side effects.

Mice -- Embryos -- Physiology.

Mice -- Development.

Phenytoin.

The unfolded protein response couples neuronal identity to circuit formation in the developing mouse olfactory system

Shayya, Hani

January 2023

Complex genetic mechanisms both endow developing neuronal subtypes with distinct molecular identities and translate those identities into the signatures of cell surface axon guidance molecules that direct neural circuit assembly. The final steps of this process, where axon guidance molecules instruct circuit outcomes, are well-understood. However, the upstream identity molecules that define guidance molecule signatures, and the molecular mechanisms by which cell type identity is transformed into these signatures, remain enigmatic. The murine olfactory system contains nearly 1,5000 olfactory sensory neuron (OSN) subtypes which are intermixed in the olfactory epithelium (OE). Each OSN subtype expresses a unique olfactory receptor (OR) protein which both tunes its response properties to odorants in the environment and acts as an identity molecule that ensures all axons of a given OSN type converge to a single set of target glomeruli in the olfactory bulb (OB). Using a combination of bioinformatic and mouse genetic approaches, we have discovered an unanticipated role for endoplasmic reticulum stress (ER stress) and the unfolded protein response (UPR) in the translation of OR identity to OSN axon guidance molecule expression and glomerular targeting. We find that slight differences in OR amino acid sequences lead to differential activation of the ER stress sensor PERK in different OSN subtypes. Graded patterns of the UPR are then interpreted through a master regulator transcription factor, Ddit3, which controls a set of stress-responsive axon guidance molecules that orchestrate the process of glomerular segregation in the OB. Our results define a novel paradigm for axon guidance in which graded activation of a canonical stress response pathway is leveraged towards the conversion of discrete neuronal identities into discrete circuit formation outcomes. These findings may be widely relevant for the formation of neural circuits across a variety of systems.

Neurosciences

Developmental biology

Mice--Genetics

Mice--Development

Olfactory receptors

Axons

Neural circuitry

In vivo Studies of Postnatal Physiologic and Pathologic Neural Network Activity Development

Ma, Liang

January 2024

Mature neural network functions and their activity correlates are not innate properties of the neonatal brain. Neural network oscillations mediating cognitive processes such as long-term memory require postnatal developmental emergence. Early cortical activity patterns are discontinuous and often externally driven, whereas later in development mature, complex, continuous and internally generated patterns emerge. However, the postnatal time course of this transition of cortical dynamics is poorly characterized. Specific cognitive processes such as memory consolidation and reconsolidation are differentially regulated by precise temporal coupling of hippocampal and cortical oscillations, including sleep spindles, hippocampal sharp wave-ripples, and cortical ripples. Yet the developmental emergence of cortical ripples and its coupling patterns remain unknown, in part due to challenges in recording from distributed brain regions in small immature animals. Furthermore, neurodevelopmental disorders often disrupt activity maturation, but large-scale investigations of pathological network development are lacking. We first conducted in vivo electrophysiology in mice during early development, and identified an evolutionarily conserved developmental trajectory of large-scale cortical dynamics. Next, we developed and validated high-density conformable neural probes (NeuroShanks) for targeting deep brain regions in developing animals. We then used NeuroShanks to investigate ripple-band oscillations in the developing hippocampal-cortical network, and proposed a conceptual model of network maturation. Finally, we extended our methods to uncover early dysregulation and pathological maturation in a pediatric mouse model of genetic epilepsy.

Neurosciences

Developmental biology

Neural networks (Neurobiology)

Mice--Development

Electrophysiology

Probes (Electronic instruments)

NORMAL AND PATHOLOGICAL DEVELOPMENT OF THE RODENT PRIMORDIAL DIAPHRAGM

Abou Marak Dit Roum, Darine

Unknown Date

No description available.

Mice -- Development

Mice -- Embryos

Diaphragm -- Research

Embryology -- Research

Diaphragmatic hernia -- Pathogenesis

Phrenic nerve -- Cytology

Muscle cells -- Cytology

Mesenchymal stem cells