Mitochondria is energy generating organelle. It synthesizes ATP, which is the essential energy source of many cellular processes. During producing energy, some redox centres leak electrons to oxygen and it is contributory to the reactive oxygen species. Besides, mitochondria have significant functions in metabolism, calcium homeostasis, and fatty acid oxidation. Also mitochondria has importance to the breakdown of the ovarian follicles and could be factor determining oocyte of quality adversely. Increasing evidence shows that the number of mitochondria affect oocyte of developmental competence and maturation detrimentally during aging. Oocyte is the mitochondria-rich cell and enable the organelle to have competence for fertilization and early embryonic development. Occurrence of blastomere depends on distribution change of mitochondria which present in the egg. Lonicera caerulea treatment inhibited ovarian mitochondrial oxidative damage by suppressing mitochondrial reactive oxygen species (mROS) generation, decreasing apoptosis, controlling disintegration of mitochondrial membrane potential and conserving respiratory chain complex activities. The purpose of this study is to identify if mouse accepting treatment with L. caerulea could counter age-induced sterility and ovarian mitochondrial OS in a model organism of ovarian ageing.

Sex hormones including progesterons, androgens, and estrogens are influential in differentiation of ovarian tissues and competence of fertility. These steroid hormones derived from cholesterol are required for cumulus-oocyte complexes(COCs) during oocyte maturation. COCs is a total functional and active entity playing a central role in oocyte. Lipid metabolism in the mammalian COCs is controlled by environmental factors. The intracellular cholesterol contents go through remarkable changes. It plays an important part of oocyte developmental competence. However, heat stress affects steroid hormone by decreasing progesterone, estrogen concentrations, and resumption of meiosis in COCs maturation. Reduction of the hormone and meiotic resumption might lead to the decline of ovarian function, follicle maturation, and subsequent embryogenesis. In the same vein, heat stress also influence on germinal vesicle breakdown, lipolytic variations, and loss of the nuclear envelope in the course of maturation of oocytes. In summary, we examined the effects of thermal stress on oocyte maturation through steroid hormone contents of change identifying the molecular mechanisms of lipids metabolism. It may have the solution to further the therapy methods for disorders regarding sterility.

Mammalian oocytes are sensitive to psychological stress at each period of follicular development. Especially, thermal stress interfere with reproductive condition by inducing formation of reactive oxygen species (ROS) and oxidative stress (OS). ROS lead to oocyte apoptosis, weakening oocyte quality and lowering the fertilization rate. As a result, the pregnancy rate is lowered, leading to infertility. Thermal stress also seems to influence zygotes through physiological changes in the maternal environment surrounding them. Loss of developmental competence suggests hyperthermia-induced oxidative stress in embryos. Interest in organic Lonicera caerulea berries has increased in recent years. They are abundant in various health-improving materials. Berries that found from natural products can be as free as possible from the bioactive toxicity of the active ingredient without side effects, and it can be a big advantage because it can work. Mammalian oocytes are arrested at the first meiotic prophase stage and get their meiotic competence to produce offspring during the development of follicle. A series of nuclear and cytoplasmic maturations are involved in this process and these vary in temperature sensitivity. Our study demonstrated that L. caerulea can relieve the negative effects of maternal hyperthermia by reducing ROS level at the developmental stage.

Neural precursor cells (NPCs) with abilities to self-renew and differentiate into neurons are born in the subventricular zone of the hippocampus and the subgranular zone in the adult mammalian brain. NPCs maintain their population by symmetric cell division and neuronal cell differentiation started by asymmetric cell division. Asymmetric cell division produces two daughter cells with different cellular fates. It has been shown that multiple transcription factors, like homeodomain transcription factors and basic helix loop helix (bHLH) transcription factors, play cruel role in cell fate determination (Bertrand et al., 2002). Multipotent cortical progenitors are maintained in a proliferative state by bHLH factors including Id and Hes families. The transition from proliferation to neurogenesis involves a coordinate increase in the activity of proneural bHLH factors (Mash1, Neurogenin1, and Neurogenin2). As development proceeds, inhibition of proneural bHLH factors in cortical progenitors promotes the formation of astrocytes. Finally, the formation of oligodendrocytes is triggered by an increase in the activity of bHLH factors Olig1 and Olig2 that may be coupled with a decrease in Id activity. Thus, bHLH factors have key roles in corticogenesis, affecting the timing of differentiation and the specification of cell fate. Hes1 is a vertebrate homologue of the Drosophila bHLH protein Hairy, originally known as a transcriptional repressor that negatively regulates neuronal differentiation. Hes1 expression in neuronal precursors precedes and represses the expression of the neuronal commitment gene Mash1, a bHLH activator homologus to the proneuronal Achaete-Scute genes in Drosophila (Campuzano and Modolell, 1992). Down regulation of Hes1 expression in developing neuroblasts may be necessary for the induction of a regulatory cascade of bHLH activator proteins that controls the commitment and progression of neural differentiation. Expression of Hes1 inhibited neurite outgrowth, whereas Mash1 expression increased neurite outgrowth. Mash1 can induce bipolar neuron differentiation (Tomita et al., 1996) and NSCs culture obtained from Mash1-/- mice cannot differentiate into GBAergic neurons (Oishi et al., 2009) Hes1 is an essential effector for Notch signaling, which regulates the maintenance of undifferentiated cells (Artavanis-Tsakonas et al., 1999). In contrast, it is previously reported that platelet-derived growth factor induces the expression of Mash1 mRNA by regulating the phosphorylation of Hes1 and TLE1 (Ju et al., 2004). Hes1 is required for neuronal differentiation in PDGF treated NSC cultures. The major cell types in the cerebral cortex and hippocampus are the glutamatergic neurons and the GABAergic neurons. Cholinergic neurons are important in spatial learning and memory formation and depleted in patient’s brain of early Alzheimer’s disease. It has not been clear, however, whether new born adult NPCs could generate different cell types of neurons with distinct cellular and physiological properties. During the development, glutamatergic neurons consisting of radially migrating neurons are originated from the ventricular zone of the dorsal telenchephalon (pallium) and give rise to pyramidal neurons. Glutamate and glutamate receptors are involved in cognitive functions by forming major excitatory network. GABAergic neurons in the neocortex and hippocampus are in part migrated from the ventral telenchephalon or from the dorsal NPCs and function as local interneurons by forming inhibitory networks which regulate large populations of glutamatergic pyramidal neurons. During the development, spatiotemporal gene expression regulated by extracellular signaling factors is believed to determine the formation of neuronal phenotypes. Platelet derived growth factor B is known to induce the differentiation into neurons rather than glial cells in the rat NPCs. We found that platelet derived growth factor B is expressed in dorsal cortex and hippocampus more than in ventral cortex in the period of pyramidal cell differentiation of the embryonic rat brain. It indeed induces cell type specific differentiation into glutamatergic cells that produce the glutamate transpoter, vGluT1 and glutamate at the late stage of differentiation although it promotes neuronal differentiation at the early stage in NPCs primarily cultured from the rat embryonic hippocampus. Brain-derived neurotrophic factor, however, facilitated GABAergic differentiation in the hippocampal NPCs that generate glutamatergic pyramidal cells in a similar manner. We also found many transcriptional factors such as homeobox genes (Dlx1, Nkx2.1, Pax6) and bHLH genes (NeuroD, Ngn1, Hes1) are involved in cell type specific differentiation into glutamatergic, GABAergic, and cholinergic cells. We observed the expression of Pax6, homeodomain transcription factor, and Hes1, bHLH transcription factor, increased during PDGF-induced early differentiation in neural stem cells. These transcription factors, however, are also expressed in differentiated neurons with specific phenotype at late differentiation stage. We found pax6 is expressed in cholinergic neurons in the adult brains and in cultures. Phosphorylation of neurogenic transcription factors by protein kinases has been reported as predominant strategy in gene regulation during neuronal development and these regulated activities of different transcription factors are known to be involved in cell fate determination. Homeodomaininteracting protein kinases2 (HIPK2) which belongs to HIPK family has been identified as a nuclear serine-threonine kinase and is known to interact with several transcription factors to regulate gene transcriptions. Among several transcription factors, HIPK2 is mainly reported to target the homeodomain transcription factors such as Nkx and Pax6. Considering the importance of homeodomain transcription factors in neurogenesis and differentiation, HIPK2 also seem to play critical roles in those transcriptional regulations during embryogenesis. To define the roles of HIPK2 in neuronal differentiation during embryonic development, we investigated the expression patterns of neurogenic transcription factors such as Pax6, Hes1 and Mash1 in HIPK2 overexpressing NSCs. Hes1 showed different expression patterns between the wild type and mutant HIPK2 overexpressed cells and Mash1, which is reported to be repressed by Hes1, also showed altered expression patterns. We detected the mRNA expression of Hes1 is upregulated by HIPK2 during neuronal differentiation. The overexpressed Pax6 induced differentiation of neural stem cells into cholinergic neurons and suppressed differentiation into GABAnergic neuron both in vitro and in vivo transplantation study. To evaluate the effect of Pax6 on the transcriptional activation of Hes1 promoter, we performed luciferase reporter assay in NIH3T3 cells. Reporter expression of Hes1 promoter was enhanced upon stimulation with wild type Pax6 and wild type HIPK2. Furthermore, the HDAC inhibition mediated by TSA(Trichostatin A) has been shown to repress the reporter expression. The treatment of TSA increased neurofilaments and GAD expression in E14.5 cortical neuronal cell. These findings suggest that Pax6 promotes neuronal subtype differentiation via regulation of Hes1 bHLH transcription factor, which is mediated by HDAC. To examine the effect of Pax6 and HIPK2 on the transcriptional activation of Hes1, efficiency of hes1 promoter was measured by a luciferase reporter assay. When DNA constructs encoding Pax6 and HIPK2 were transfected along with Hes1 promoter, the expression of the reporter was highly increased. Furthermore, the HDAC inhibition mediated by TSA(Trichostatin A) repressed the reporter expression. Interaction of Pax6 and HIPK2 was shown by co-immunoprecipitation and binding of Pax6 to hes1 promoter was detected by chromatin immunoprecipitation. I also found overexpression of HIPK2 and Pax6 facilitated neural stem cells to differentiate into cholinergic cell fate in NSCs primarily cultured from the rat hippocampus. This is also supported by analysis of the brains of sey/neu Pax6 mutant mice and HIPK2 knock out mice. These findings suggest that Pax6 activation by HIPK2 promotes neuronal subtype differentiation via up regulation of Hes1 and down regulation of Mash1 and it is mediated by HDAC.