Autophagy on acid

The microenvironment of solid tumors tends to be more acidic (6.5–7.0) than surrounding normal (7.2–7.4) tissue. Chaotic vasculature, oxygen limitation and major metabolic changes all contribute to the acidic microenvironment. We have previously proposed that low extracellular pH (pHe) plays a critical role in the development and progression of solid tumors. While extracellular acidosis is toxic to most normal cells, cancer cells can adapt and survive under this harsh condition. In this study, we focused on identifying survival strategies employed by cancer cells when challenged with an acidic pHe (6.6–6.7) either acutely or for many generations. While acutely acidic cells did not grow, those acclimated over many generations grew at the same rate as control cells. We observed that these cells induce autophagy in response to acidosis both acutely and chronically, and that this adaptation appears to be necessary for survival. Inhibition of autophagy in low pH cultured cells results in cell death. Histological analysis of tumor xenografts reveals a strong correlation of LC3 protein expression in regions projected to be acidic. Furthermore, in vivo buffering experiments using sodium bicarbonate, previously shown to raise extracellular tumor pH, decreases LC3 protein expression in tumor xenografts. These data imply that autophagy can be induced by extracellular acidosis and appears to be chronically employed as a survival adaptation to acidic microenvironments.     

综述: 细胞自噬在肿瘤发生发展中的作用

自噬是保守的细胞防御机制,又是程序性细胞死亡机制．在多种人类肿瘤中存在细胞自噬活性改变．自噬活性降低促进肿瘤的发生和进展．综述了近年来细胞自噬在肿瘤中的研究进展,从基因组不稳定性、炎-癌链转化和演进、致瘤微生 物感染和宿主免疫应答、细胞凋亡途径与自噬的交叉调节等角度探讨自噬抑制肿瘤的机理,以及细胞自噬在肿瘤治疗中的作用．     

自噬抑制与肿瘤

自噬是一种在正常细胞和病理状态细胞中普遍存在的生理机制。自噬与肿瘤细胞的生存与凋亡关系密切,在很多肿瘤细胞中,其自噬活性均有改变。抑制肿瘤细胞中自噬活动可以促进肿瘤细胞的凋亡。在化疗诱导肿瘤细胞凋亡的同时,以自噬抑制剂抑制肿瘤细胞的自噬活动,可改善肿瘤的治疗效果。     

细胞自噬与肿瘤

自噬是广泛存在于真核细胞内的一种细胞分解自身构成成分的生命现象.细胞内的双层膜结构与溶酶体结合后其内包裹的受损、变形或衰老细胞器蛋白质等被水解酶类降解.细胞自噬具有多种生理功能,生命体借此维持蛋白质代谢平衡及细胞环境稳定,这一过程在细胞清除废物、结构重建、生长发育调节中发挥重要作用. 细胞自噬也与肿瘤的存活和死亡等过程密切相关. 近年来对细胞自噬的研究有了较大的深入,本文主要对自噬体的形态和发生过程及其分子机制、信号调节通路、自噬研究的检测方法,以及自噬与细胞凋亡和肿瘤发生的关系等方面进行概述,以期较全面地了解细胞自噬作用和最新研究动态.     

Autophagy across the eukaryotes

Autophagy is conserved throughout the eukaryotes and for many years, work in Saccharomyces cerevisiae has been at the forefront of autophagy research. However as our knowledge of the autophagic machinery has increased, differences between S. cerevisiae and mammalian cells have become apparent. Recent work in other organisms, such as the amoeba Dictyostelium discoideum, indicate an autophagic pathway much more similar to mammalian cells than S. cerevisiae, despite its earlier evolutionary divergence. S. cerevisiae therefore appear to have significantly specialized, and the autophagic pathway in mammals is much more ancient than previously appreciated, which has implications for how we interpret data from organisms throughout the eukaryotic tree.     

自噬及其在细胞代谢和疾病中的作用

自噬是真核细胞中广泛存在的降解/再循环系统. 自噬在氨基酸和激素的调控下对蛋白质等大分子和细胞器进行降解,降解产物可作为新合成蛋白质和细胞器的原料. 作为Ⅱ型程序性细胞死亡,自噬与凋亡相互作用,参与维持机体的自稳态,在生物体正常发育及对某些环境胁迫的响应极为关键. 对自噬在生物体发育、老化以及在肿瘤、神经退行性病变、肌病和抵御微生物侵染中的作用进行了综述.     

Autophagy and senescence

Autophagy and senescence share a number of characteristics, which suggests that both responses could serve to collaterally protect the cell from the toxicity of external stress such as radiation and chemotherapy and internal forms of stress such as telomere shortening and oncogene activation. Studies of oncogene activation in normal fibroblasts as well as exposure of tumor cells to chemotherapy have indicated that autophagy and senescence are closely related but not necessarily interdependent responses; specifically, interference with autophagy delays but does not abrogate senescence. The literature relating to this topic is inconclusive, with some reports appearing to be consistent with a direct relationship between autophagy and senescence and others indicative of an inverse relationship. Before this question can be resolved, additional studies will be necessary where autophagy is clearly inhibited by genetic silencing and where the temporal responses of both autophagy and senescence are monitored, preferably in cells that are intrinsically incapable of apoptosis or where apoptosis is suppressed. Understanding the nature of this relationship may provide needed insights relating to cytoprotective as well as potential cytotoxic functions of both autophagy and senescence.     

EGFR Signaling Stimulates Autophagy to Regulate Stem Cell Maintenance and Lipid Homeostasis in the Drosophila Testis

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Acidic extracellular pH neutralizes the autophagy-inhibiting activity of chloroquine

Acidic pH is an important feature of tumor microenvironment and a major determinant of tumor progression. We reported that cancer cells upregulate autophagy as a survival mechanism to acidic stress. Inhibition of autophagy by administration of chloroquine (CQ) in combination anticancer therapies is currently evaluated in clinical trials. We observed in 3 different human cancer cell lines cultured at acidic pH that autophagic flux is not blocked by CQ. This was consistent with a complete resistance to CQ toxicity in cells cultured in acidic conditions. Conversely, the autophagy-inhibiting activity of Lys-01, a novel CQ derivative, was still detectable at low pH. The lack of CQ activity was likely dependent on a dramatically reduced cellular uptake at acidic pH. Using cell lines stably adapted to chronic acidosis we could confirm that CQ lack of activity was merely caused by acidic pH. Moreover, unlike CQ, Lys-01 was able to kill low pH-adapted cell lines, although higher concentrations were required as compared with cells cultured at normal pH conditions. Notably, buffering medium pH in low pH-adapted cell lines reverted CQ resistance. In vivo analysis of tumors treated with CQ showed that accumulation of strong LC3 signals was observed only in normoxic areas but not in hypoxic/acidic regions. Our observations suggest that targeting autophagy in the tumor environment by CQ may be limited to well-perfused regions but not achieved in acidic regions, predicting possible limitations in efficacy of CQ in antitumor therapies.     

Acidic extracellular pH neutralizes the autophagy-inhibiting activity of chloroquine: Implications for cancer therapies

Acidic pH is an important feature of tumor microenvironment and a major determinant of tumor progression. We reported that cancer cells upregulate autophagy as a survival mechanism to acidic stress. Inhibition of autophagy by administration of chloroquine (CQ) in combination anticancer therapies is currently evaluated in clinical trials. We observed in 3 different human cancer cell lines cultured at acidic pH that autophagic flux is not blocked by CQ. This was consistent with a complete resistance to CQ toxicity in cells cultured in acidic conditions. Conversely, the autophagy-inhibiting activity of Lys-01, a novel CQ derivative, was still detectable at low pH. The lack of CQ activity was likely dependent on a dramatically reduced cellular uptake at acidic pH. Using cell lines stably adapted to chronic acidosis we could confirm that CQ lack of activity was merely caused by acidic pH. Moreover, unlike CQ, Lys-01 was able to kill low pH-adapted cell lines, although higher concentrations were required as compared with cells cultured at normal pH conditions. Notably, buffering medium pH in low pH-adapted cell lines reverted CQ resistance. In vivo analysis of tumors treated with CQ showed that accumulation of strong LC3 signals was observed only in normoxic areas but not in hypoxic/acidic regions. Our observations suggest that targeting autophagy in the tumor environment by CQ may be limited to well-perfused regions but not achieved in acidic regions, predicting possible limitations in efficacy of CQ in antitumor therapies.     

细胞自噬研究进展

细胞自噬是真核生物在进化过程中高度保守、基于溶酶体的一种胞内降解途径,对维持细胞和生物体的稳态平衡有重要作用。研究表明,自噬参与生物体发育、免疫反应、代谢调节、细胞凋亡和衰老等多种过程。自噬功能异常与神经退行性疾病、肿瘤等的发生发展密切相关。近30年,我们对细胞自噬的认识无论是在分子机制上还是生理功能方面都有了长足的发展。为进一步加深对细胞自噬的认识,该文主要对细胞自噬的概念、自噬核心机器的组成及调控机制、自噬类型、生理功能及与疾病的关系作一简单综述。     

Autophagy and mTOR pathways in mouse embryonic stem cell,lung cancer and somatic fibroblast cell lines

Embryonic developmental stages and regulations have always been one of the most intriguing aspects of science. Since the cancer stem cell discovery, striking for cancer development and recurrence, embryonic stem cells and control mechanisms, as well as cancer cells and cancer stem cell control mechanisms become important research materials. It is necessary to reveal the similarities and differences between somatic and cancer cells which are formed of embryonic stem cells divisions and determinations. For this purpose, mouse embryonic stem cells (mESCs), mouse skin fibroblast cells (MSFs) and mouse lung squamous cancer cells (SqLCCs) were grown in vitro and the differences between these three cell lines signalling regulations of mechanistic target of rapamycin (mTOR) and autophagic pathways were demonstrated by immunofluorescence and real-time polymerase chain reaction. Expressional differences were clearly shown between embryonic, cancer and somatic cells that mESCs displayed higher expressional level of Atg10, Hdac1 and Cln3 which are related with autophagic regulation and Hsp4, Prkca, Rhoa and ribosomal S6 genes related with mTOR activity. LC3 and mTOR protein levels were lower in mESCs than MSFs. Thus, the mechanisms of embryonic stem cell regulation results in the formation of somatic tissues whereas that these cells may be the causative agents of cancer in any deterioration.     

自噬过程的晚期阶段

自噬是高度保守的细胞内降解途径。在此过程中,部分细胞质和细胞器被双层膜的囊泡包裹形成自噬体,随后与溶酶体融合并降解被吞噬的物质。降解产物被释放到细胞质中重新用于必需的物质和能量合成。本文主要关注自噬的晚期阶段,即从自噬体合成结束到溶酶体再生过程。通过对这一过程相关基因及蛋白产物的研究,初步揭示了此过程的分子机制。     

Autophagy

Autophagy is an evolutionarily conserved cellular process through which long-lived proteins and damaged organelles are recycled to maintain energy homeostasis. These proteins and organelles are sequestered into a double-membrane structure, or autophagosome, which subsequently fuses with a lysosome in order to degrade the cargo. Although originally classified as a type of programmed cell death, autophagy is more widely viewed as a basic cell survival mechanism to combat environmental stressors. Autophagy genes were initially identified in yeast and were found to be necessary to circumvent nutrient stress and starvation. Subsequent elucidation of mammalian gene counterparts has highlighted the importance of this process to normal development. This review provides an overview of autophagy, the types of autophagy, its regulation and its known impact on development gleaned primarily from murine models.     

自噬过程的晚期阶段

自噬是高度保守的细胞内降解途径.在此过程中,部分细胞质和细胞器被双层膜的囊泡包裹形成自噬体,随后与溶酶体融合并降解被吞噬的物质.降解产物被释放到细胞质中重新用于必需的物质和能量合成.本文主要关注自噬的晚期阶段,即从自噬体合成结束到溶酶体再生过程.通过对这一过程相关基因及蛋白产物的研究,初步揭示了此过程的分子机制.     

Fusobacterium nucleatum and colorectal cancer: A mechanistic overview

Colorectal cancer (CRC) is the third most prevalent cancer in the world. There are many risk factors involved in CRC. According to recent findings, the tumor microenvironment and feces samples of patients with CRC are enriched by Fusobacterium nucleatum. Thus, F. nucleatum is proposed as one of the risk factors in the initiation and progression of CRC. The most important mechanisms of Fusobacterium nucleatum involved in CRC carcinogenesis are immune modulation (such as increasing myeloid-derived suppressor cells and inhibitory receptors of natural killer cells), virulence factors (such as FadA and Fap2), microRNAs (such as miR-21), and bacteria metabolism. The aim of this review was to evaluate the mechanisms underlying the action of F. nucleatum in CRC.     

低氧条件下白藜芦醇对HepG2细胞增殖及自噬的调节作用及初步机制

白藜芦醇（resveratrol）是天然存在于葡萄、红酒及花生等中的一种多酚类化合物,具有抗癌、抗氧化等作用．目前针对resveratrol抗癌作用的研究大多侧重于常氧状态,而对于更接近体内肿瘤生长环境即低氧状态的研究相对匮乏．本文以肝癌细胞HepG2为模型,探讨了低氧（1％02）条件下resveratrol抑癌的相关功能和机制．结果表明,在低氧状态下resveratrol不仅抑制HepG2细胞的活性,而且也促进了低氧诱导的自噬保护机制;进一步研究发现,去乙酰化酶Sirtl和鞘氨醇激酶SPKl也参与上述过程．本文初步揭示了低氧状态下癌细胞对resveratrol敏感性低的可能机制,更加明确resveratrol在实体瘤中的抗癌作用,并为resveratrol的药物研发提供了借鉴．