Y-27632 enhances differentiation of blastocyst like cystic human embryoid bodies to endocrinologically active trophoblast cells on a biomimetic platform

Trophoblast differentiation and formation of the placenta are important events linked to post-implantation embryonic development. Models mimicking the biology of trophoblast differentiation in a post-implantation maternal microenvironment are needed for understanding disorders like placental-ischemia or for applications in drug-screening, and would help in overcoming the ethical impasse on using human embryos for such research. Here we attempt to create such a model by using embryoid bodies (EBs) and a biomimetic platform composed of a bilayer of fibronectin and gelatin on top of low-melting agarose. Using this model we test the hypothesis that cystic-EBs (day 30) that resemble blastocysts morphologically, are better sources as compared to noncytic EBs (day 10), for functional trophoblast differentiation; and that the Rho kinases inhibitor Y27632 can enhance this differentiation. Non/cytic EBs with/out Y27632 were grown on this platform for 28 days, and screened from secretion and expression of trophoblast and other lineage markers using ECLIA, RT-PCR, and Immunofluorescence. All EBs attached on this surface and rapidly proliferated into hCG and progesterone (P2) secreting functional trophoblast cells. However, the cells derived from cytic-EBs and cytic-EBs+ Y27632 showed the maximum secretion of these hormones and expressed IGF2, supporting our hypothesis. Also Y27632 reduced extraembryonic endoderm and trophoblast lineage differentiation from early noncystic-EBs, whereas, it specifically enhanced the induction of trophoblast and multinucleated syncitiotrophoblast differentiation from late cystic-EBs. In vivo trophoblast differentiation can be replicated in fibronectin based biomaterials, using cytic-EBs and by maneuvering the Rho-ROCK pathways. Response of EBs to a compound may vary temporally, and determination of their right stage is crucial for applications in directed-differentiation or drug-screening

Gene targeting in immunology

733-745Transgenics and gene targeting by homologous recombination provide an ideal opportunity to delineate immune functions of specific genes. These gene knockout mice are powerful tools to understand complex mechanism of immune system and molecular processes underlying autoimmune diseases and immunodeficiencies. Availability of an increased pool of genetically manipulated mice will provide a basic foundation for developing of novel strategies to treat immunological diseases

Instability of CGG Repeats in Transgenic Mice

Dynamic mutation resulting in the expansion of CGG repeats in the untranslated region (UTR) of the first exon of the FMR1 gene in humans results in fragile X syndrome. Long stretches of CGG repeats that are known to be highly unstable in humans have so far failed to show similar intergenerational instability in transgenic mice. We generated transgenic lines that show a dramatic increase from 26 to >300 repeats in three generations. One of the salient features of our transgene is the inclusion of the origin of replication of simian virus-40 (SV40), which is known to exclude nucleosomes. Three founder mice in FVB/NJ background show expansion of CGG repeats present in the transgene, supporting a postzygotic mechanism for CGG expansion that is independent of a genomic imprinting effect. We discuss here the results of analyzing one of the lines established

A testicular protein important for fertility has glutathione S-transferase activity and is localized extracellularly in the seminiferous tubules

A 24-kDa protein isolated by preparative gel electrophoresis from rat testes was reported by us as an active immunogen in rats. Anti-24-kDa antibodies inhibited murine sperm-oocyte binding in vitro. Here, we show similarity at the NH2 terminus shared by this protein purified on Sephadex G-75 followed by anion exchange high performance liquid chromatography with glutathione S-transferase (GST)-μ subunits. This protein purified by glutathione affinity chromatography also demonstrated similarity to GST-μ NH2 terminus in a 30-amino-acid overlap. Both proteins showed activity toward the GST substrate 1-chloro-2,4-dinitrobenzene (Km of 33 μ M and 50 μ M) which was inhibited by 17β -estradiol 3-sulfate. Antisera against both proteins recognized liver GST-μ on Western blots and sperm acrosome of multiple species immunocytochemically. Both antisera significantly inhibited in vitro fertilization of goat oocytes by sperm preincubated with them while anti-liver GST sera did not. GST activity was localized on rat sperm, seminiferous tubular fluid, and Sertoli cells. Seminiferous tubular fluid 24-kDa protein shared similarity to the NH2 terminus of GST-μ subunits in a 20-amino-acid overlap. Time-dependent accumulation of GST was detected in the spent culture medium of seminiferous tubules from rats of different ages suggesting secretion

Invitro cultured Spodoptera frugiperda insect cells: model for oxidative stress-induced apoptosis

Cellular imbalance in the levels of antioxidants and reactive oxygen species (ROS) is directly associated with a number of pathological states and results in programmed cell death or apoptosis. We demonstrate the use ofin vitro cultured Spodoptera ƒrugiperda (sƒ9) insect cells as a model to study oxidative stress induced programmed cell death. Apoptosis ofin vitro cultured sf9 cells was induced by the exogenous treatment of H2O2 to cells growing in culture. The AD50 (concentration of H2O2 inducing about 50% apoptotic response) varied with the duration of treatment, batch to batch variation of H2O2 and the physiological state of cells. At 24 h post-treatment with H2O2 AD50 was about 475 Mm. Apoptosis could also be induced byin situ generation of H2O2 by the inhibition of catalase activity upon hydroxylamine treatment. Hydroxylamine acted synergistically with H2O2 with an AD50 of 2.2 mM. DMSO, a free radical scavenger, inhibited H2O2-induced apoptosis thereby confirming the involvement of reactive oxygen species. Exposure of cells to UV radiation (312 nm) resulted in a dose-dependent induction of apoptosis. These results provide evidence on the novel use of insect cells as a model for oxidative stress-induced apoptosis