표피는 각질형성세포의 분화로부터 재생되어 계층화되는 상피 조직으로서 물리적 장벽을 형성함으로써 다양한 외부 오염원으로부터 개체를 보호한다. 자가포식 작용(autophagy)은 단백질 축적물, 손상된 세포 소기관, 세포내 미생물 등이 리소좀으로 운반되고 분해되도록 매개하는 기작이다. 최근 연구 결과에 의하면 자가포식 작용이 각질형성세포의 대사 기관과 핵을 제거하여 각질층으로 최종 분화하는데 중요한 역할을 하는 것이 보고 되었다. 그러나 자가포식 작용을 촉진함으로써 표피 분화를 유도할 수 있는지는 알려져 있지 않다. 본 연구에서는 천연물 유래 단일 화합물 라이브러리를 스크리닝하여 베타인(betaine)이 인간 각질형성세포주인 HaCaT 세 포에서 세포질 내 LC3 punctate 소포체 및 LC3-I에서 LC3-II로의 변환을 증가시켜 자가포식 작용을 촉진함을 규명했다. 자가포식 작용의 억제 신호인 mTOR 경로는 베타인에 의해 영향을 받지 않았으므로, 베타인에 의해 유도된 자가포식 작용은 mTOR에 독립적임을 알 수 있었다. 베타인에 의해 촉진되는 자가포식 작용은 primary keratinocyte 및 skin equivalent에서도 관찰되었다. 또한, 베타인 처리된 인공피부에서 표피층 두께가 증가함을 확인하였다. 이러한 결과들로부터, 자가포식 작용의 새로운 조절소재로서 베타인이 표피의 턴오버를 촉진하여 표피의 장벽기능을 개선하고 피부노화를 방지할 수 있음을 시사한다.

Molecular targeting for the altered signaling pathways has been proven to be effective for the treatment of many types of human cancer, including colorectal cancer (CRC). The dual phosphatidylinositol-3-kinase (PI3K) and mammalian target of rapamycin (mTOR) inhibitor BEZ235 has shown to exhibit potent antitumor activity against solid tumors. Autophagy is a cellular lysosomal catabolic process to maintain metabolic homeostasis, which has been known to be induced in response to many therapeutic agents in cancer cells. This process is negatively regulated by mTOR and often acts as prosurvival or prodeath mechanism following cancer therapeutics. The current study was designed to investigate the antiproliferation activity of BEZ235 and to evaluate the role of autophagy induced by BEZ235 using HCT15 CRC cells bearing ras oncogene mutation. We found that BEZ235 decreases cell viability, which was mostly dependent on G1 arrest of cell cycle via suppression of cyclin A expression. BEZ235 affects PI3K/Akt/mTOR signaling pathway by increasing the phosphorylation of AKT at Ser473 and RAS/RAF/MEK/ERK pathway by decreasing the phosphorylation of ERK at Tyr204. BEZ235 also stimulated autophagy induction as evidenced by the increased expression of LC3-II and abundant acidic vesicular organelles (AVOs) in the cytoplasm. In addition, the combination of BEZ235 with autophagy inhibitor chloroquine, a known antagonist of autophagy, counteracted the antiproliferation effect of BEZ235. Thus, our study indicates that autophagy induced in response to BEZ235 treatment appears to act as cell death mechanism in HCT15 CRC cells.

Cytokinesis is the final event in the cell division. After cytokinesis, one parent cell divided into two symmetric daughter cells. Unlike somatic cell which is symmetrically divided, oocyte meiotic maturation is highly asymmetric division, producing mature ovum and polar body. Class III phosphoinositide 3-kinase (PI3K) has been known as a key molecular component that regulates cell cycle progression, autophagy and endosomal trafficking. However, emerging evidences suggest that class III PI3K and its interactors are involved in midbody abscission during cytokinesis. Here we showed that beclin-1, a key component of PI3K is required to regulate midbody abscission during oocyte asymmetric division. Beclin-1 was widely distributed during meiotic maturation forming small vesicles. However, these vesicles were not colocalized with autophagosomal marker LC3. Instead, beclin-1 was detectable at the midbody ring during cytokinesis. Depletion of beclin-1 showed various defects including the failure of cytokinetic abscission, spindle separation and chromosome decondensation. Similar phenotype was observed when class III PI3K activity was inhibited. Therefore, our results demonstrate that PI3K is essential for cytokinesis but not autophagy during oocyte meiosis.

Autophagy is a self-degradative process which accompanies the formation of double-membraned vesicles inside the cell. In the mouse uterus, autophagy is enhanced during steroid hormone deprivation and associated with acute inflammation. There are 17 major Autophagy related genes (Atg). Herein we investigated the role for Atg7 by using uterine cell-specific deletion model of this gene. We crossed Atg7flox/flox (Atg7f/f) mouse and Anti-Mullerian hormone type 2 receptor (Amhr2)-Cre mice (Amhr2-Cre; Atg7f/f). Amhr2 is mainly expressed in stroma and myometrium in the uterus, ovary, and oviduct, during 30 to 60 days. To confirm the region of Cre expression and to monitor whether conditional deletion of Atg7 was by Cre recombinase, we isolated uterine epithelial and stromal cells from 8 and 16 weeks mice by enzymatic digestion and performed RT-PCR. We confirmed that Amhr2-Cre is expressed in stoma and myomotrium, but not in epithelium. Then we examined the uterine histology and embryonic development of day 3 pregnant Amhr2-Cre; Atg7f/f mice. However, there was no specific difference between Atg7f/f (control) and Amhr2-Cre; Atg7f/f mice. To examine the effect of hormone deprivation, we performed western blotting and immunofluorescence staining of p62 (SQSTM1), an indicator of autophagic flux, and LC3B, a marker of autophagic activation, in Amhr2-Cre; Atg7f/f mice ovariectomized (OVX) for 2 weeks. p62 increased dramatically in OVX Amhr2-Cre; Atg7f/f uteri but not in control mice, suggesting that autophagic activation did not occur in the absence of Atg7 in the uterine stroma and that this led to massive accumulation of p62 in this cell type. p62 marks to-be-degraded proteins and target them for autophagic-lysosomal degradation. Thus it is predictable that Atg7-driven uterine autophagy is responsible for degradation of macromolecules during hormone deprivation.

Autophagy means “self-eating” and it is a major catabolic pathway within cells. A basal level of autophagy is required for survival of cells or organisms, but prolonged activation of autophagy may have an adverse effect. In mammalian systems, autophagy is stimulated by nutrient starvation or deprivation of growth factors. Ovariectomy on day 4 of pregnancy in mice to deprive blastocysts of estrogen induces “dormancy” in blastocysts and delay the process of implantation until estrogen is given. Dormant blastocysts maintain a state of low metabolism in utero and survive for many days without initiating implantation under the unfavorable condition of estrogen deficiency. We tested the hypothesis if an autophagic response is operative in dormant blastocysts for prolonged survival in utero during the delayed implantation. We observed that autophagy is highly activated in dormant blastocysts. Interestingly, autophagic activation is more prominent in trophectoderm than in inner cell mass. Activation of blastocysts by estrogen supplementation induces formation of multivesicular bodies and exosomes in the trophectoderm. Dormant blastocysts with longer period of autophagic activation show compromised development after implantation. Thus, autophagy may be a critical cellular mechanism to provide energy source during extended survival of dormant blastocysts. However, prolonged activation of autophagy may compromise developmental outcome of blastocysts with irreparable cellular damage.

Autophagy is a homeostatic degradation process that is involved in tumor development and normal development. Autophagy is induced in cancer cells in response to chemotherapeutic agents, and inhibition of autophagy results in enhanced cancer cell death or survival. Chloroquine (CQ), an anti-malarial drug, is a lysosomotropic agent and is currently used as a potential anticancer agent as well as an autophagy inhibitor. Here, we evaluate the characteristics of these dual activities of CQ using human colorectal cancer cell line HCT15. The results show that CQ inhibited cell viability in doseand time-dependent manner in the range between 20 to 80 uM, while CQ did not show any antiproliferative activity at 5 and 10 uM. Cotreatment of CQ with antitumor agent NVP-BEZ235, a dual inhibitor of PI3K/mTOR, rescued the cell viability at low concentrations meaning that CQ acted as an autophagy inhibitor, but CQ induced the lethal effect at high concentrations. Acridine orange staining revealed that CQ at high doses induced lysosomal membrane permeabilization (LMP). High doses of CQ produced cellular reactive oxygen species (ROS) and cotreatment of antioxidants, such as NAC and trolox, with high doses of CQ rescued the cell viability. These results suggest that CQ may exert its dual activities, as autophagy inhibitor or LMP inducer, in concentration-dependent manner.

Vitrification uses cryoprotectants and liquid nitrogen, which may cause osmotic stress and cryodamage to oocytes. Autophagy is widely considered as a survival or responsive mechanism to various environmental and cellular stresses. However, the status of autophagy in vitrified-warmed oocytes has not been studied. In this work, we investigated if vitrification-warming process induces autophagy in mouse oocytes. Four-week-old female ICR mice and GFP-LC3 transgenic mice were used. The mice were superovulated with 5IU PMSG and 5IU hCG and ovulated MII oocytes were collected from oviducts. Oocytes obtained from several mice were pooled and divided into three groups. Group1: fresh oocytes. Group2: oocytes treated with vitification solutions (1.3 M EG+1.1 M DMSO and 2.7 M EG+2.1 M DMSO+0.5 M sucrose for 2.5 min) and warming solutions (0.5 M, 0.25, 0,125, and 0 M sucrose at intervals 2.5 min). Group3: vitrified-warmed oocytes (loaded onto an EM copper grid, and were stored in LN2 for 2 weeks). RT-PCR and confocal live imaging of GFP-LC3 were performed to examine the effects of vitrification-warming process on autophagy in oocytes. In RT-PCR analyses, expression of autophagy related (Atg) genes, such as Atg5, Atg7, Atg12, LC3a, LC3b, and Beclin1 was examined. Expression of Atg7 and Atg12 was slightly reduced in Group 3 (vitrified-warmed oocytes). The expression levels of other Atg genes did not change. Confocal live imaging analysis using oocytes from GFP-LC3 transgenic mice revealed that some vitrified-warmed oocytes showed green puncta which indicate autophagic activation. All oocytes of Group 1 and Group 2 show no puncta formation. Our results suggest that induction of autophagy may serve as an indicator of conditions of vitrification-warming process. Moreover, it offers the possibility that development of methods to modulate autophagic response during cryopreservation could improve efficacy of oocyte cryopreservation.

The anandamide signaling plays various roles in directing reproductive processes. Mouse embryos are shown to express high levels of CB1 receptor (CB1R). It has recently been shown that an analog of anandamide induces autophagy-mediated cell death through stimulation of ER stress response in glioma cells. Since adverse effects of high levels of anandamide agonists on embryo development and implantation are well known, we hypothesized that anandamide mediates an autophagic response in embryonic cells as in cancer cells via highly abundant CB1R on embryos. We tested this hypothesis by using a stable anandamide agonist, Methanandamide (MET) in three embryonic cell systems, i.e., mouse embryonic fibroblasts (MEF), trophoblast stem (TS) cells, and preimplantation embryos from mice. RT-PCR, immunofluorescence staining, and Western blot analysis were used to examine the effects of anandamide on autophagy in these systems. In MEF cells, the conversion of LCI to LCII was heightened by methanandamide (MET), and AM251, a selective CB1 antagonist partially reversed the effects of MET. Treating MEF cells with a high level of MET induces clustering of GFP-LC3, seen as large puncta throughout the cytoplasm. At 28 nM concentration, MET also weakly increased LC3II in TS cells. When MET was injected to day 4 pregnant mice, autophagy was increased in blastocysts in utero as demonstrated by the increased number of LC3 puncta. Formation of numerous autophagic vacuoles was also confirmed by electron microscopic observation. In conclusion, this work suggests that the anandamide-CB1 signaling pathway may be one inducer of autophagy in embryonic cells.

Autophagy is an evolutionarily conserved lysosomal pathway for degrading cytoplasmic proteins, macromolecules, and organelles, in addition to recycling protein and ATP synthesis. Although programmed cell death (PCD) is very important during embryogenesis, the mechanism underlying the dynamic development during this process remains largely unknown. In order to obtain insights into autophagy and it's relation with apoptosis in early embryo development, we first evaluated LC3 gene expression levels in mouse embryos developing in vitro. qRT-PCR revealed high expression levels from 1- to 4 cell stage embryo, and then expression decreased during morula and blastocyst formation. Indirect immunocytochemistry showed protein synthesis of LC3 in these stage embryos. Introducing of autophagy inhibitor, 3-MA (2mM) significantly decreased both developmental rate (54.85±11.0%) and total cell number (n=71±8), but increased apoptosis rate (5.68± 1.9%) at the blastocyst. Real time RT-PCR confirmed reduced expression of selected autophagy related genes, including ULK1, Atg4A, B, C, D, Atg5, Atg8, Gabarap, Atg9A, B and Atg16L. Treatment of autophagy inducer, rapamycin (50 ng/㎖) increased both mRNA expression and protein synthesis of LC3 and apoptosis rate (16.11±3.42%), but decreased developmental rates (50.16±9.78) and total cell numbers (n=60±7) as compared to control developmental rate (70.74±12.9%), Total cell number (89.8±9) and apoptotic cell death (1.11±0.7%). These results suggest that autophagy is related with apoptosis in mouse embryo, which possibly give a role for early development.

Mitochondria are important regulators of both apoptosis and autophagy. One of the triggers for mitochondrial-mediated apoptosis is the production of reactive oxygen species (ROS), which include hydrogen peroxide, superoxide, hydroxyl radical, nitric oxide, and peroxynitrite. Recently, several studies have indicated that ROS may also be involved in the induction of autophagy. In the present study, we used H2O2 to induce mitochondrial stress and examined apoptotic- and autophagic-related gene expression and observed LC3 protein (autophagosome presence marker) expression in porcine parthenotes developing in vitro. In porcine four-cell parthenotes cultured for 5 days in NCSU37 medium containing 0.4% BSA, the developmental rate and mitochondrial distribution did not differ from that of the group supplemented with 100 μM H2O2 but significantly decreased in the group supplemented with 500 μM H2O2 (P<0.05). Transmission electron microscopy (TEM) indicated that whereas normal shaped mitochondria were observed in blastocysts from the control group, abnormal mitochondria (mitophagy) and autophagic vacuoles were observed in blastocysts from the group that received 500 μM H2O2. Furthermore, addition of H2O2 (100 μM and 500 μM) decreased cell numbers (P<0.05) and increased both apoptosis (P<0.05) and LC3 protein expression in the blastocysts. Real time RT-PCR showed that H2O2 significantly decreased mRNA expression of anti-apoptotic gene Bcl-xL but increased pro-apoptotic genes, Caspase 3 (Casp3) and Bak, and autophagy-related genes, microtubule-associated protein 1 light chain 3 (Map1lc3b) and lysosomal-associated membrane protein 2 (Lamp2). However, the addition of H2O2 had no effect on mRNA expression levels in nuclear DNA-encoded mitochondrial-related genes, cytochrome oxidase (Cox) 5a, Cox5b, and Cox6b1, but decreased mitochondrial DNA-encoded genes, D-loop (Dloop) and cytochrome b (Cytb), in blastocysts. These results suggest that H2O2 leads to mitochondrial dysfunction that results in apoptosis and autophagy, which is possibly related to porcine early embryo development.