The amplified cancer gene LAPTM4B promotes tumor growth and tolerance to stress through the induction of autophagy

Autophagy is a fundamental salvage pathway that encapsulates damaged cellular components and delivers them to the lysosome for degradation and recycling. This pathway usually conducts a protective cellular response to nutrient deprivation and various stresses. Tumor cells live with metabolic stress and use autophagy for their survival during tumor progression and metastasis. Genomic instability in tumor cells may result in amplification of crucial gene(s) for autophagy and upregulate the autophagic pathway. We demonstrate that a cancer-associated gene, LAPTM4B, plays an important role in lysosomal functions and is critical for autophagic maturation. Its amplification and overexpression promote autophagy, which renders tumor cells resistant to metabolic and genotoxic stress and results in more rapid tumor growth.     

MAPKs regulate mitophagy in Saccharomyces cerevisiae

The autophagy-dependent selective degradation of mitochondria (mitophagy) plays an important role in removing excessive, damaged and dysfunctional mitochondria to maintain a proper cellular homeostasis. Relative to its significance in cell physiology, very little is known about the molecular machinery and regulatory mechanism of mitophagy in mammalian cells or yeast. We found that two mitogen-activated protein kinases (MAPKs), Slt2 and Hog1, are required for mitophagy in Saccharomyces cerevisiae. Slt2 is involved in both mitophagy and pexophagy (the selective degradation of peroxisomes through autophagy), whereas Hog1 functions specifically in mitophagy.     

MAPKs regulate mitophagy in Saccharomyces cerevisiae

The autophagy-dependent selective degradation of mitochondria (mitophagy) plays an important role in removing excessive, damaged and dysfunctional mitochondria to maintain a proper cellular homeostasis. Relative to its significance in cell physiology, very little is known about the molecular machinery and regulatory mechanism of mitophagy in mammalian cells or yeast. We found that two mitogen-activated protein kinases (MAPKs), Slt2 and Hog1, are required for mitophagy in Saccharomyces cerevisiae. Slt2 is involved in both mitophagy and pexophagy (the selective degradation of peroxisomes through autophagy), whereas Hog1 functions specifically in mitophagy.     

Development by self-digestion: molecular mechanisms and biological functions of autophagy

Autophagy is the major cellular pathway for the degradation of long-lived proteins and cytoplasmic organelles. It involves the rearrangement of subcellular membranes to sequester cargo for delivery to the lysosome where the sequestered material is degraded and recycled. For many decades, it has been known that autophagy occurs in a wide range of eukaryotic organisms and in multiple different cell types during starvation, cellular and tissue remodeling, and cell death. However, until recently, the functions of autophagy in normal development were largely unknown. The identification of a set of evolutionarily conserved genes that are essential for autophagy has opened up new frontiers for deciphering the role of autophagy in diverse biological processes. In this review, we summarize our current knowledge about the molecular machinery of autophagy and the role of the autophagic machinery in eukaryotic development.     

Why just eat in,when you can also eat out?

The current working definition of autophagy is the following: all processes in which intracellular material is degraded within the lysosome/vacuole and where the macromolecular constituents are recycled. There are several ways to classify the different types of autophagy. For example, we can separate autophagy into two primary types, based on the initial site of cargo sequestration. In particular, during microautophagy and chaperone-mediated autophagy, uptake occurs directly at the limiting membrane of the lysosome or vacuole. In contrast, macroautophagy—whether selective or nonselective—and endosomal microautophagy involve sequestration within an autophagosome or an omegasome, or late endosomes/multivesicular bodies, respectively; the key point being that in these types of autophagy the initial sequestration event does not occur at the limiting membrane of the degradative organelle. In any case, the cargo is ultimately delivered into the lysosome or vacuole lumen for subsequent degradation. Thus, I think most autophagy researchers view the degradative organelle as the ultimate destination of the pathway. Indeed, this fits with the general concept that organelles allow reactions to be compartmentalized. With regard to the lysosome or vacuole, this also confers a level of safety by keeping the lytic contents away from the remainder of the cell. If we are willing to slightly modify our definition of autophagy, with a focus on “degradation of a cell’s own components through the lysosomal/vacuolar machinery,” we can include a newly documented process, programmed nuclear destruction (PND).     

Autophagy pathway intersects with HIV-1 biosynthesis and regulates viral yields in macrophages

Autophagy is a cytoplasmic degradative pathway that can participate in biosynthetic processes, as in the yeast Cvt pathway, but is more commonly known for its functions in removing damaged or surplus organelles and macromolecular complexes. Here, we find that autophagy intersects with human immunodeficiency virus (HIV) biogenesis, mirroring the above dichotomy. Early, nondegradative stages of autophagy promoted HIV yields. HIV Gag-derived proteins colocalized and interacted with the autophagy factor LC3, and autophagy promoted productive Gag processing. Nevertheless, when autophagy progressed through maturation stages, HIV was degraded. This, however, does not occur, as the HIV protein Nef acts as an antiautophagic maturation factor through interactions with the autophagy regulatory factor Beclin 1, thus protecting HIV from degradation. The dual interaction of HIV with the autophagy pathway enhances viral yields by using the early stages while inhibiting the late stages of autophagy. The role of Nef in the latter process enhances yields of infectious HIV and may be of significance for progression to clinical AIDS.     

Glucose Deprivation Triggers Protein Kinase C-dependent β-Catenin Proteasomal Degradation

Autophagy is a conserved process that contributes to cell homeostasis. It is well known that induction mainly occurs in response to nutrient starvation, such as starvation of amino acids and insulin, and its mechanisms have been extensively characterized. However, the mechanisms behind cellular glucose deprivation-induced autophagy are as of now poorly understood. In the present study, we determined a mechanism by which glucose deprivation induced the PKC-dependent proteasomal degradation of β-catenin, leading to autophagy. Glucose deprivation was shown to cause a sub-G₁ transition and enhancement of the LC3-II protein levels, whereas β-catenin protein underwent degradation in a proteasome-dependent manner. Moreover, the inhibition of GSK3β was unable to abolish the glucose deprivation-mediated β-catenin degradation or up-regulation of LC3-II protein levels, which suggested GSK3β-independent protein degradation. Intriguingly, the inhibition of PKCα using a pharmacological inhibitor and transfection of siRNA for PKCα was observed to effectively block glucose deprivation-induced β-catenin degradation as well as the increase in LC3-II levels and the accumulation of a sub-G₁ population. Together, our results demonstrated a molecular mechanism by which glucose deprivation can induce the GSK3β-independent protein degradation of β-catenin, leading to autophagy.     

High fluence low‐power laser irradiation induces apoptosis via inactivation of Akt/GSK3β signaling pathway

High fluence low‐power laser irradiation (HF‐LPLI) is a newly discovered stimulus through generating reactive oxygen species (ROS) to trigger cell apoptosis. Activation of glycogen synthase kinase 3β (GSK3β) is proved to be involved in intrinsic apoptotic pathways under various stimuli. However, whether the proapoptotic factor GSK3β participates in HF‐LPLI‐induced apoptosis has not been elucidated. Therefore, in the present study, we investigated the involvement of GSK3β in apoptosis under HF‐LPLI treatment (120 J/cm², 633 nm). We found that GSK3β activation could promote HF‐LPLI‐induced apoptosis, which could be prevented by lithium chloride (a selective inhibitor of GSK3β) exposure or by GSK3β‐KD (a dominant‐negative GSK3β) overexpression. We also found that the activation of GSK3β by HF‐LPLI was due to the inactivation of protein kinase B (Akt), a widely reported and important upstream negative regulator of GSK3β, indicating the existence and inactivation of Akt/GSK3β signaling pathway. Moreover, the inactivation of Akt/GSK3β pathway depended on the fluence of HF‐LPLI treatment. Furthermore, vitamin c, a ROS scavenger, completely prevented the inactivation of Akt/GSK3β pathway, indicating ROS generation was crucial for the inactivation. In addition, GSK3β promoted Bax activation by down‐regulating Mcl‐1 upon HF‐LPLI treatment. Taken together, we have identified a new and important proapoptotic signaling pathway that is consisted of Akt/GSK3β inactivation for HF‐LPLI stimulation. Our research will extend the knowledge into the biological mechanisms induced by LPLI. J. Cell. Physiol. 226: 588–601, 2011. © 2010 Wiley‐Liss, Inc.     

自噬和泛素-蛋白酶体系统之间的交联

自噬和泛素-蛋白酶体系统作为细胞内最重要的两大降解途径,对细胞稳态及细胞正常生理功能的维持都具有十分重要的作用。目前,越来越多的证据显示,这两大降解途径之间存在多种交联方式。首先,自噬和泛素-蛋白酶体系统都能以泛素作为共同标签,从而将泛素化底物降解;其次,泛素化的蛋白酶体可以通过自噬被清除,自噬相关蛋白质也可以通过蛋白酶体系统被降解;再次,这两条途径在细胞内能协同降解同一种底物;最后,它们之间可以相互调节活性,任一条途径被干扰都将影响另一条途径的活性。自噬和泛素-蛋白酶体系统之间的交联对细胞稳态的维持至关重要。交联失调不仅导致细胞功能异常,还可引起多种疾病的发生。本文主要对自噬和泛素-蛋白酶体系统之间的交联方式及其分子机制进行阐述,有助于深入了解细胞的分解代谢过程,进一步理解细胞稳态的维持机制,继而加深对相关疾病病理机制的认识。     

Distinct mechanisms of ferritin delivery to lysosomes in iron-depleted and iron-replete cells

Ferritin is a cytosolic protein that stores excess iron, thereby protecting cells from iron toxicity. Ferritin-stored iron is believed to be utilized when cells become iron deficient; however, the mechanisms underlying the extraction of iron from ferritin have yet to be fully elucidated. Here, we demonstrate that ferritin is degraded in the lysosome under iron-depleted conditions and that the acidic environment of the lysosome is crucial for iron extraction from ferritin and utilization by cells. Ferritin was targeted for degradation in the lysosome even under iron-replete conditions in primary cells; however, the mechanisms underlying lysosomal targeting of ferritin were distinct under depleted and replete conditions. In iron-depleted cells, ferritin was targeted to the lysosome via a mechanism that involved autophagy. In contrast, lysosomal targeting of ferritin in iron-replete cells did not involve autophagy. The autophagy-independent pathway of ferritin delivery to lysosomes was deficient in several cancer-derived cells, and cancer-derived cell lines are more resistant to iron toxicity than primary cells. Collectively, these results suggest that ferritin trafficking may be differentially regulated by cell type and that loss of ferritin delivery to the lysosome under iron-replete conditions may be related to oncogenic cellular transformation.     

Protein phosphorylation-acetylation cascade connects growth factor deprivation to autophagy

Different from unicellular organisms, metazoan cells require the presence of extracellular growth factors to utilize environmental nutrients. However, the underlying mechanism was unclear. We have delineated a pathway, in which glycogen synthase kinase 3 (GSK3) in cells deprived of growth factors phosphorylates and activates the acetyltransferase KAT5/TIP60, which in turn stimulates the protein kinase ULK1 to elicit autophagy. Cells with the Kat5/Tip60 gene replaced with Kat5 (S86A) that cannot be phosphorylated by GSK3 are resistant to serum starvation-induced autophagy. Acetylation sites on ULK1 were mapped to K162 and K606, and the acetylation-defective mutant ULK1 (K162,606R) displays reduced kinase activity and fails to rescue autophagy in Ulk1 (-/-) mouse embryonic fibroblasts, indicating that acetylation is vital to the activation of ULK1. The GSK3-KAT5-ULK1 cascade seems to be specific for cells to sense growth factors, as KAT5 phosphorylation is not enhanced under glucose deprivation. Distinct from the glucose starvation-autophagy pathway that is conserved in all eukaryotic organisms, the growth factor deprivation response pathway is perhaps unique to metazoan organisms.     

Suppression of Lysosome Function Induces Autophagy via a Feedback Down-regulation of MTOR Complex 1 (MTORC1) Activity

Autophagy can be activated via MTORC1 down-regulation by amino acid deprivation and by certain chemicals such as rapamycin, torin, and niclosamide. Lysosome is the degrading machine for autophagy but has also been linked to MTORC1 activation through the Rag/RRAG GTPase pathway. This association raises the question of whether lysosome can be involved in the initiation of autophagy. Toward this end, we found that niclosamide, an MTORC1 inhibitor, was able to inhibit lysosome degradation and increase lysosomal permeability. Niclosamide was ineffective in inhibiting MTORC1 in cells expressing constitutively activated Rag proteins, suggesting that its inhibitory effects were targeted to the Rag-MTORC1 signaling system. This places niclosamide in the same category of bafilomycin A₁ and concanamycin A, inhibitors of the vacuolar H⁺-ATPase, for its dependence on Rag GTPase in suppression of MTORC1. Surprisingly, classical lysosome inhibitors such as chloroquine, E64D, and pepstatin A were also able to inhibit MTORC1 in a Rag-dependent manner. These lysosome inhibitors were able to activate early autophagy events represented by ATG16L1 and ATG12 puncta formation. Our work established a link between the functional status of the lysosome in general to the Rag-MTORC1 signaling axis and autophagy activation. Thus, the lysosome is not only required for autophagic degradation but also affects autophagy activation. Lysosome inhibitors can have a dual effect in suppressing autophagy degradation and in initiating autophagy.     

Clathrin and phosphatidylinositol-4,5-bisphosphate regulate autophagic lysosome reformation

Autophagy is a lysosome-based degradation pathway. During autophagy, lysosomes fuse with autophagosomes to form autolysosomes. Following starvation-induced autophagy, nascent lysosomes are formed from autolysosomal membranes through an evolutionarily conserved cellular process, autophagic lysosome reformation (ALR), which is critical for maintaining lysosome homeostasis. Here we report that clathrin and phosphatidylinositol-4,5-bisphosphate (PtdIns(4,5)P(2)) regulate ALR. Combining a screen of candidates identified through proteomic analysis of purified ALR tubules, and large-scale RNAi knockdown, we unveiled a tightly regulated molecular pathway that controls lysosome homeostasis, in which clathrin and PtdIns(4,5)P(2) are the central components. Our functional study demonstrates the central role of clathrin and its associated proteins in cargo sorting, phospholipid conversion, initiation of autolysosome tubulation, and proto-lysosome budding during ALR. Our data not only uncover a molecular pathway by which lysosome homeostasis is maintained through the ALR process, but also reveal unexpected functions of clathrin and PtdIns(4,5)P(2) in lysosome homeostasis.