Mechanisms of Survival of Cytomegalovirus-Infected Tumor Cells

Molecular Biology - Human cytomegalovirus (HCMV) DNA and proteins are often detected in malignant tumors, warranting studies of the role that HCMV plays in carcinogenesis and tumor progression....     

Plasma Cells: From Cytokine Production to Regulation in Experimental Autoimmune Encephalomyelitis

B cells are a critical arm of the adaptive immune system. After encounter with antigen, B cells are activated and differentiate into plasmablasts (PBs) and plasma cells (PCs). Although their frequency is low, PB/PCs can be found in all lymphoid organs including peripheral lymph nodes and spleen. Upon immunization, depending on the location of where B cells encounter their antigen, PB/PCs subsequently home to and accumuate in the bone marrow and the intestine where they can survive as long-lived plasma cells for years, continually producing antibody. Recent evidence has shown that, in addition to producing antibodies, PB/PCs can also produce cytokines such as IL-17, IL-10, and IL-35. In addition, PB/PCs that produce IL-10 have been shown to play a regulatory role during experimental autoimmune encephalomyelitis, an animal model of neuroinflammation. The purpose of this review is to describe the phenotype and function of regulatory PB/PCs in the context of experimental autoimmune encephalomyelitis and in patients with multiple sclerosis.     

A Sensitive Method to Quantify Senescent Cancer Cells

Human cells do not indefinitely proliferate. Upon external and/or intrinsic cues, cells might die or enter a stable cell cycle arrest called senescence. Several cellular mechanisms, such as telomere shortening and abnormal expression of mitogenic oncogenes, have been shown to cause senescence. Senescence is not restricted to normal cells; cancer cells have also been reported to senesce.Chemotherapeutical drugs have been shown to induce senescence in cancer cells. However, it remains controversial whether senescence prevents or promotes tumorigenesis. As it might eventually be patient-specific, a rapid and sensitive method to assess senescence in cancer cell will soon be required.To this end, the standard β-galactosidase assay, the currently used method, presents major drawbacks: it is time consuming and not sensitive. We propose here a flow cytometry-based assay to study senescence on live cells. This assay offers the advantage of being rapid, sensitive, and can be coupled to the immunolabeling of various cellular markers.     

pAkt在衰老细胞中的核转位

磷脂酰肌醇3 激酶（PI3K）/蛋白激酶B（PKB,又称为Akt）/叉头转录因子（FOXO）信号通路在从酵母菌到小鼠的寿命以及衰老的调节上都起着非常重要的作用．有研究发现,血清可以激活年轻细胞、衰老细胞胞浆内的Akt,并且年轻细胞核内磷酸化Akt(pAkt)增多,而衰老细胞核内pAkt没有增多．为了研究衰老细胞膜是否发生转位受损,即pAkt能否通过衰老细胞核膜进入核内,通过激光共聚焦显微镜（CLSM）、Western 印迹等实验方法,发现衰老细胞胞浆中pAkt可以进入核内,进入核内的pAkt很快被去磷酸化灭活．     

Targeting Autophagic Regulation of NF-kappaB in HTLV-I Transformed Cells by Geldanamycin: Implications for Therapeutic Interventions

The IκappaB kinase (IKK)/NF-κappaB signaling pathway plays an essential role in the development and survival of many types of cancers including adult T-cell leukemia (ATL) caused by the human T-cell leukemia virus type I (HTLV-I) infection. Accordingly, targeting NF-κappaB provides an attractive strategy for cancer therapy. We recently found that specific inhibition of Hsp90 by geldanamycin (GA) results in autophagic degradation of IKK and NF-κappaB-inducing kinase (NIK), an upstream kinase of IKK, and inactivation of NF-κappaB in various cell lines. Here, we further report that GA inhibition of Hsp90 also led to IKK autophagic degradation and NF-κappaB inhibition in both HTLV-transformed T cells and ATL-derived cell lines. Importantly, GA treatment led to efficient apoptosis of these malignant cells, whereas inhibition of autophagic degradation of IKK significantly ameliorated the cytotoxic effect of GA. These findings thus not only provide mechanistic insights into the tumor suppression function of autophagy and the anti-tumor activity of GA, but also suggest an immediate therapeutic strategy for ATL and other diseases associated with NF-κappaB activation by targeting autophagic degradation of the central NF-kappaB activating kinases.

Addendum to:

Hsp90 Inhibition Results in Autophagy-Mediated Proteasome-Independent Degradation of IκappaB Kinase (IKK)

G. Qing, P. Yan and G. Xiao

Cell Res 2006; 16:895-901

and

Hsp90 Regulates Processing of NF-κappaB2 p100 Involving Protection of NF-κappaB-Inducing Kinase (NIK) from Autophagy-Mediated Degradation

G. Qing, P. Yan, Z. Qu, H. Liu and G. Xiao

Cell Res 2007; 17:520-30     

Cytoplasmic pH Regulation in Acer pseudoplatanus Cells: II. Possible Mechanisms Involved in pH Regulation during Acid-Load

Qualitative and quantitative aspects of the mechanisms involved in the regulation of cytoplasmic pH during an acid-load have been studied in Acer pseudoplatanus cells. Two main processes, with about the same relative importance, account for the removal of H⁺ from the cytoplasm, namely a `metabolic consumption' of protons and the excretion of protons or proton-equivalents out of the cells. The metabolic component corresponds to a change in the equilibrium between malate synthesis and degradation leading to a 30% decrease of the malate content of the cells during the period of cytoplasmic pH regulation. Various conditions which severely inhibit the activity of the plasmalemma proton pump ATPase reduce, at most by 50%, the excretion of H⁺. This suggests that, besides the plasmalemma proton-pump, other systems are involved in the excretion of proton-equivalents. Indirect information on qualitative and quantitative features of these systems is described, which suggests the involvement of Na⁺ and HCO₃⁻ exchanges in the regulation of cytoplasmic pH of acid-loaded cells.     

To Find and Destroy: Identification and Elimination of Senescent Cells

“Our oldness is a disease that has to be treated like any other one,”—this statement formulated about a hundred years ago seems to be of current interest in the context of modern investigations. Recently, it has been established that accumulation of senescent cells in various organs and tissues is one of the main causes for the organismal aging, as well as for the progression of multiple age-related pathologies. On the one hand, this observation brings us one step closer to the desired goal—reversal or slowing down of aging. On the other hand, this raises a number of complicated questions: in what essentially lies the difference between senescent and normal cells and how they can be identified; whether senescent cells can be eliminated from the body and can this elimination stop/reverse aging; can such a targeted removal of senescent cells be accompanied by negative consequences, in particular, by an increase in the cancer incidence? This review summarizes the main features of senescent cells, surveys the existing approaches of targeted elimination of senescent cells in vivo, and highlights their advantages and disadvantages.     

Phenotypic Alterations in Senescent Large-Vessel and Microvascular Endothelial Cells

Endothelial cell senescence likely plays a key role in age-associated vascular diseases. A close relationship between in vitro and in vivo senescence of endothelial cells has been established. Therefore, elucidating the structural and functional changes occurring during long-term cultures of endothelial cells would contribute to clarifying the pathogenesis of vascular disorders in the elderly. We investigated the effects of replicative senescence on the architecture of bovine aortic vs microvascular endothelial cells. A marked increase in cell area was observed in both cell types, whereas dramatic morphological alterations were detected in microvascular endothelial cells only. The latter also showed age-associated reorganization of the actin cytoskeleton. Finally, both aortic and microvascular endothelial cells lost their migratory response to basic fibroblast growth factor with age. Our results highlight dramatic structural and functional alterations in senescent endothelial cells. Such rearrangements might account for in vivo endothelial cell alterations involved in age-associated vascular dysfunction.     

Mechanisms of Redox Regulation of Chemoresistance in Tumor Cells by Phenolic Antioxidants

Effects of water-soluble sulfur-containing phenolic antioxidants sodium 3-(3′-tert-butyl-4′- hydroxyphenyl)propyl thiosulfonate and potassium 3,5-dimethyl-4-hydroxybenzyl thioethanoate on chemoresistance in tumor cells have been studied. The studied phenolic antioxidants cause oppositely directed changes in the redox properties and chemoresistance in tumor cells. Potassium 3,5-dimethyl-4-hydroxybenzyl thioethanoate increases redox buffering capacity and doxorubicin resistance in tumor cells. Sodium 3-(3′- tert-butyl-4′-hydroxyphenyl)propyl thiosulfonate reduces the redox buffering capacity, which leads to a decrease in the chemoresistance of tumor cells. These observations suggest that one of the key mechanisms responsible for the formation of tumor cell resistance to antitumor compounds is the attenuation of apoptosis through increase of redox buffering capacity. The dependence of protein sensor redox state on oxidant concentrations and on redox buffering capacity in cells has been determined based on the proposed biophysical model of redox-dependent mechanism of apoptosis activation.     

Resveratrol Modulates Mitochondria Dynamics in Replicative Senescent Yeast Cells

Mitochondria form a reticulum network dynamically fuse and divide in the cell. The balance between mitochondria fusion and fission is correlated to the shape, activity and integrity of these pivotal organelles. Resveratrol is a polyphenol antioxidant that can extend life span in yeast and worm. This study examined mitochondria dynamics in replicative senescent yeast cells as well as the effects of resveratrol on mitochondria fusion and fission. Collecting cells by biotin-streptavidin sorting method revealed that majority of the replicative senescent cells bear fragmented mitochondrial network, indicating mitochondria dynamics favors fission. Resveratrol treatment resulted in a reduction in the ratio of senescent yeast cells with fragmented mitochondria. The readjustment of mitochondria dynamics induced by resveratrol likely derives from altered expression profiles of fusion and fission genes. Our results demonstrate that resveratrol serves not only as an antioxidant, but also a compound that can mitigate mitochondria fragmentation in replicative senescent yeast cells.     

高渗透压环境下OREBP 调控机制的研究进展

渗透压反应元件结合蛋白(OREBP)是Rel家族的最新成员,是迄今为止唯一已知的哺乳动物细胞渗透压反应调节因子。它最初是作为一种促进渗透压保护基因表达的蛋白在肾髓质细胞中被发现的。最近研究表明,它在胚胎发育、炎症反应、肌生成、HIV复制以及肿瘤细胞的增殖转移等过程中也发挥了十分重要的作用。然而有关高渗环境下OREBP调控机制的认识还很不完整。许多因素参与了OREBP的调控,这些因素都是高渗环境下激活OREBP所必需的,但又都不能独立完成对OREBP的调控。本文对上述因素在高渗环境下OREBP调控中的作用以及它们之间的相互关系进行了综述。     

Phospholipase D2 Mediates Survival Signaling through Direct Regulation of Akt in Glioblastoma Cells

The lack of innovative drug targets for glioblastoma multiforme (GBM) limits patient survival to approximately 1 year following diagnosis. The pro-survival kinase Akt provides an ideal target for the treatment of GBM as Akt signaling is frequently activated in this cancer type. However, the central role of Akt in physiological processes limits its potential as a therapeutic target. In this report, we show that the lipid-metabolizing enzyme phospholipase D (PLD) is a novel regulator of Akt in GBM. Studies using a combination of small molecule PLD inhibitors and siRNA knockdowns establish phosphatidic acid, the product of the PLD reaction, as an essential component for the membrane recruitment and activation of Akt. Inhibition of PLD enzymatic activity and subsequent Akt activation decreases GBM cell viability by specifically inhibiting autophagic flux. We propose a mechanism whereby phosphorylation of beclin1 by Akt prevents binding of Rubicon (RUN domain cysteine-rich domain containing beclin1-interacting protein), an interaction known to inhibit autophagic flux. These findings provide a novel framework through which Akt inhibition can be achieved without directly targeting the kinase.     

清除衰老细胞在衰老与老龄化相关疾病中的研究进展

衰老是一个新兴的重要研究领域,随着该领域相关知识的积累和技术的进步,人们逐渐意识到衰老本身可以被针对性地干预,实现延长寿命并且延缓衰老相关疾病的发生发展,具有重要的科学和现实意义.引起个体衰老的众多因素中,衰老细胞的积累被认为是导致器官衰老发生退行性变,最终引起衰老相关疾病的重要原因.近年来,多项研究表明,清除体内衰老细胞可以延缓多种衰老相关疾病的发生,直接证明了衰老细胞是导致衰老相关疾病的重要原因之一,为治疗衰老相关疾病提供了新靶点.细胞衰老是由于损伤积累诱发了细胞周期抑制通路的激活,细胞永久地退出细胞增殖周期.衰老细胞会发生细胞形态、转录谱、蛋白质稳态、表观遗传以及代谢等系列特征的改变,同时衰老细胞对凋亡发生抵抗从而在体内多器官组织积累.衰老细胞会激活炎症因子分泌通路,导致组织局部非感染性炎症微环境,进而导致器官退行性变及多种衰老相关疾病的发生发展.因此针对衰老细胞对凋亡抵抗的特性,多个研究小组通过筛选小分子化合物库,发现某些化合物能够选择性清除衰老细胞,这些小分子化合物被称为"senolytics",意为"衰老细胞杀伤性化合物".衰老细胞杀伤性化合物在多种衰老相关疾病动物模型中能够延缓疾病的发展并延长哺乳动物寿命.因此,靶向杀伤衰老细胞对多种衰老相关疾病的治疗从而提高健康寿命具有重要的临床应用前景.除靶向杀伤衰老细胞策略以外,干细胞移植、基因编辑、异体共生等策略在抗衰老研究发展中也具有重要意义,具有启发性.本文通过汇总近期衰老细胞清除领域的重要进展和多种抗衰老策略,将细胞衰老研究发展史做简要梳理,就细胞衰老与衰老相关疾病的关系作一综述,重点讨论衰老细胞在多种衰老相关疾病中作为治疗靶点的应用潜力,并就其局限性和进一步的研究方向进行探讨.     

Different Mechanisms of Regulation of the Warburg Effect in Lymphoblastoid and Burkitt Lymphoma Cells

Background

The Warburg effect is one of the hallmarks of cancer and rapidly proliferating cells. It is known that the hypoxia-inducible factor 1-alpha (HIF1A) and MYC proteins cooperatively regulate expression of the HK2 and PDK1 genes, respectively, in the Burkitt lymphoma (BL) cell line P493-6, carrying an inducible MYC gene repression system. However, the mechanism of aerobic glycolysis in BL cells has not yet been fully understood.

Methods and Findings

Western blot analysis showed that the HIF1A protein was highly expressed in Epstein–Barr virus (EBV)-positive BL cell lines. Using biochemical assays and quantitative PCR (Q-PCR), we found that—unlike in lymphoblastoid cell lines (LCLs)—the MYC protein was the master regulator of the Warburg effect in these BL cell lines. Inhibition of the transactivation ability of MYC had no influence on aerobic glycolysis in LCLs, but it led to decreased expression of MYC-dependent genes and lactate dehydrogenase A (LDHA) activity in BL cells.

Conclusions

Our data suggest that aerobic glycolysis, or the Warburg effect, in BL cells is regulated by MYC expressed at high levels, whereas in LCLs, HIF1A is responsible for this phenomenon.