Gene expression analysis in the compartments of the murine uterus.

Embryo implantation, a key critical feature of mammalian pregnancy, involves co-ordinate interplay between an incoming blastocyst and a receptive uterus. Aberrations in signaling cascades during this process result in pregnancy loss in mammals, including women. Analysis of the complete uterus at any given point either during preparation for implantation or during and after embryo attachment and invasion makes it difficult to assign specific signaling mechanism to the individual cellular compartments of the uterus. Here, we describe methods for the specific isolation of the luminal epithelium (LE) and subsequent analysis of gene expression/signaling pathways during embryo attachment. We further describe the analysis of RNA and proteins by specific techniques of quantitative PCR (qPCR), immunostaining and Western blotting of uterine tissues. These methods can be applied to the other cellular compartments of the uterus and embryo invasion and endometrial development. These techniques will be beneficial to investigators for delineating the mechanisms involved during embryo attachment and female reproduction as well as providing a means to studying highly dynamic changes in gene expression in tissues.

Disruption of SUMO-specific protease 2 induces mitochondria mediated neurodegeneration.

Post-translational modification of proteins by small ubiquitin-related modifier (SUMO) is reversible and highly evolutionarily conserved from yeasts to humans. Unlike ubiquitination with a well-established role in protein degradation, sumoylation may alter protein function, activity, stability and subcellular localization. Members of SUMO-specific protease (SENP) family, capable of SUMO removal, are involved in the reversed conjugation process. Although SUMO-specific proteases are known to reverse sumoylation in many well-defined systems, their importance in mammalian development and pathogenesis remains largely elusive. In patients with neurodegenerative diseases, aberrant accumulation of SUMO-conjugated proteins has been widely described. Several aggregation-prone proteins modulated by SUMO have been implicated in neurodegeneration, but there is no evidence supporting a direct involvement of SUMO modification enzymes in human diseases. Here we show that mice with neural-specific disruption of SENP2 develop movement difficulties which ultimately results in paralysis. The disruption induces neurodegeneration where mitochondrial dynamics is dysregulated. SENP2 regulates Drp1 sumoylation and stability critical for mitochondrial morphogenesis in an isoform-specific manner. Although dispensable for development of neural cell types, this regulatory mechanism is necessary for their survival. Our findings provide a causal link of SUMO modification enzymes to apoptosis of neural cells, suggesting a new pathogenic mechanism for neurodegeneration. Exploring the protective effect of SENP2 on neuronal cell death may uncover important preventive and therapeutic strategies for neurodegenerative diseases.

Six2 and Wnt regulate self-renewal and commitment of nephron progenitors through shared gene regulatory networks.

A balance between Six2-dependent self-renewal and canonical Wnt signaling-directed commitment regulates mammalian nephrogenesis. Intersectional studies using chromatin immunoprecipitation and transcriptional profiling identified direct target genes shared by each pathway within nephron progenitors. Wnt4 and Fgf8 are essential for progenitor commitment; cis-regulatory modules flanking each gene are cobound by Six2 and ß-catenin and are dependent on conserved Lef/Tcf binding sites for activity. In vitro and in vivo analyses suggest that Six2 and Lef/Tcf factors form a regulatory complex that promotes progenitor maintenance while entry of ß-catenin into this complex promotes nephrogenesis. Alternative transcriptional responses associated with Six2 and ß-catenin cobinding events occur through non-Lef/Tcf DNA binding mechanisms, highlighting the regulatory complexity downstream of Wnt signaling in the developing mammalian kidney.

Spatiotemporal ablation of myelinating glia-specific neurofascin (Nfasc NF155) in mice reveals gradual loss of paranodal axoglial junctions and concomitant disorganization of axonal domains.

The evolutionary demand for rapid nerve impulse conduction led to the process of myelination-dependent organization of axons into distinct molecular domains. These domains include the node of Ranvier flanked by highly specialized paranodal domains where myelin loops and axolemma orchestrate the axoglial septate junctions. These junctions are formed by interactions between a glial isoform of neurofascin (Nfasc(NF155)) and axonal Caspr and Cont. Here we report the generation of myelinating glia-specific Nfasc(NF155) null mouse mutants. These mice exhibit severe ataxia, motor paresis, and death before the third postnatal week. In the absence of glial Nfasc(NF155), paranodal axoglial junctions fail to form, axonal domains fail to segregate, and myelinated axons undergo degeneration. Electrophysiological measurements of peripheral nerves from Nfasc(NF155) mutants revealed dramatic reductions in nerve conduction velocities. By using inducible PLP-CreER recombinase to ablate Nfasc(NF155) in adult myelinating glia, we demonstrate that paranodal axoglial junctions disorganize gradually as the levels of Nfasc(NF155) protein at the paranodes begin to drop. This coincides with the loss of the paranodal region and concomitant disorganization of the axonal domains. Our results provide the first direct evidence that the maintenance of axonal domains requires the fence function of the paranodal axoglial junctions. Together, our studies establish a central role for paranodal axoglial junctions in both the organization and the maintenance of axonal domains in myelinated axons.

Recombineering-based procedure for creating Cre/loxP conditional knockouts in the mouse.

Gene targeting in the mouse is an essential tool for studying gene function and creating models of human disease. The method described in this unit takes advantage of bacterial artificial chromosomes, Cre/loxP and FLPe/FRT systems, and recently evolved recombineering approaches to simplify the preparation of targeting constructs for generation of conditional knockout (CKO) animals. This method has been used to generate >30 CKO constructs, most of them successfully used to target mouse ES cells and establish mutant mice. Design and preparation of the CKO construct, as well as step-wise troubleshooting guidelines, are described in detail.

A BAC transgenic mouse model to analyze the function of astroglial SPARCL1 (SC1) in the central nervous system.

Extracellular matrix associated Sparc-like 1 (SC1/SPARCL1) can influence the function of astroglial cells in the developing and mature central nervous system (CNS). To examine SC1's significance in the CNS, we generated a BAC transgenic mouse model in which Sc1 is expressed in radial glia and their astrocyte derivatives using the astroglial-specific Blbp (Brain-lipid binding protein; [Feng et al., (1994) Neuron 12:895-908]) regulatory elements. Characterization of these Blbf-Sc1 transgenic mice show elevated Sc1 transcript and protein in an astroglial selective pattern throughout the CNS. This model provides a novel in vivo system for evaluating the role of SC1 in brain development and function, in general, and for understanding SC1's significance in the fate and function of astroglial cells, in particular.

Cochlin, a secreted von Willebrand factor type a domain-containing factor, is regulated by leukemia inhibitory factor in the uterus at the time of embryo implantation.

Embryo implantation is a required step in the reproduction of all mammals. In mice, a transient rise in the uterine expression of leukemia inhibitory factor (LIF) occurs on d 4 of pregnancy and is essential for embryo implantation. However, which genes are regulated by LIF in the uterus at implantation has not been determined. We performed a subtractive hybridization assay between luminal epithelial (LE) mRNAs from d 3 and 4 of pregnancy to find genes up-regulated on d 4 and which would be potentially regulated by LIF. One candidate, Coch-5b2, was up-regulated on the day of implantation. Coch mRNA localized to the LE of wild-type mice and was not detected in uteri from Lif-deficient mice. Treatment of LE with LIF, both in vitro and in vivo, resulted in the up-regulation of Coch. Coch is also highly expressed in other tissues, including the spleen and inner ear, but only in the uterus is Coch expression regulated by LIF. Mice were derived in which Coch was either deleted or tagged with a LacZ reporter. In mice carrying the tagged Coch gene, expression of Coch was detected in the LE and also at the site of embryo implantation. However, mice in which the Coch gene was deleted were normal, showing no overt defects in their reproduction. Although loss of Coch expression is not essential to reproduction in mice, it may serve as a useful marker for assessing the state of uterine receptivity in response to LIF at the onset of implantation.

Loss of cyclooxygenase-2 retards decidual growth but does not inhibit embryo implantation or development to term.

Previous reports have described that female mice deficient in cyclooxygenase-2 (COX2) are largely infertile because of failure to ovulate, poor fertilization, and defective implantation and decidualization. In the present study, we reinvestigated reproduction in these mice and found they do show a reduction in the numbers of ovulated and fertilized eggs. However, we did not observe any substantial effect on embryo implantation frequencies or an inability of COX2-deficient females to support embryo development to weaning. Pseudopregnant COX2-null recipients do not show any alteration in the timing of implantation following blastocyst transfer, but they do show a delay in the initial rate of decidual growth after implantation that lags by approximately 24 h compared to that in heterozygous or wild-type recipients. These results support previous findings that COX2 has a role in mediating the initial uterine decidual response but is not essential to sustaining decidual growth and embryo development throughout the remainder of pregnancy.