[Effect of mitophagy related genes on the antioxidant properties of Saccharomyces cerevisiae].

Mitophagy is a process whereby cells selectively remove mitochondria through the mechanism of autophagy, which plays an important role in maintaining cellular homeostasis. In order to explore the effect of mitophagy genes on the antioxidant activities of Saccharomyces cerevisiae, mutants with deletion or overexpression of mitophagy genes ATG8, ATG11 and ATG32 were constructed respectively. The results indicated that overexpression of ATG8 and ATG11 genes significantly reduced the intracellular reactive oxygen species (ROS) content upon H2O2 stress for 6 h, which were 61.23% and 46.35% of the initial state, respectively. Notable, overexpression of ATG8 and ATG11 genes significantly increased the mitochondrial membrane potential (MMP) and ATP content, which were helpful to improve the antioxidant activities of the strains. On the other hand, deletion of ATG8, ATG11 and ATG32 caused mitochondrial damage and significantly decreased cell vitality, and caused the imbalance of intracellular ROS. The intracellular ROS content significantly increased to 174.27%, 128.68%, 200.92% of the initial state, respectively, upon H2O2 stress for 6 h. The results showed that ATG8, ATG11 and ATG32 might be potential targets for regulating the antioxidant properties of yeast, providing a new clue for further research.

Autophagy, a relevant process for metabolic health and type-2 diabetes / Autofagia, un proceso relevante para la salud y la diabetes tipo 2

Autophagy is a very active process that plays an important role in cell and organ differentiation and remodelling, being a crucial system to guarantee health. This physiological process is activated in starvation and inhibited in the presence of nutrients. This short review comments on the three types of autophagy: macroautophagy, microautophagy, and chaperone-mediated autophagy, as well as different aspects that control autophagy and its relationship with health and degenerative diseases. As autophagy is highly dependent on functional autophagy (ATG) proteins integrating the phagophore, the role of some key ATG genes and epigenes are briefly commented on. The manuscript deepens discussing some central aspects of type-2 diabetes mellitus and their relationship with the cell cleaning process and mitochondria homeostasis maintenance, as well as the mechanisms through which antidiabetic drugs affect autophagy. Well-designed studies are needed to elucidate whether autophagy plays a casual or causal role in T2DM. (AU)

La autofagia es un proceso muy activo que juega un papel importante en la diferenciación y remodelación de células y órganos, siendo un sistema crucial para garantizar la salud. Este proceso fisiológico se activa en la inanición y se inhibe en presencia de nutrientes. En esta breve revisión se definen los tres tipos de autofagia: macroautofagia, microautofagia y autofagia mediada por chaperonas, y los diferentes aspectos que controlan la autofagia y su relación con la salud y las enfermedades degenerativas. Como la autofagia depende en gran medida de las proteínas funcionales de autofagia (ATG) que integran el fagóforo, se comenta brevemente el papel clave de algunos genes y epigenes de las ATG. El manuscrito profundiza discutiendo algunos aspectos centrales de la diabetes mellitus tipo 2 (DMT2) y su relación con el proceso de limpieza celular y el mantenimiento de la homeostasis mitocondrial, así como los mecanismos a través de cuales los fármacos antidiabéticos afectan a la autofagia. Se necesitan estudios bien diseñados para dilucidar si la autofagia juega un papel de casualidad o causalidad en el desarrollo de la DMT2. (AU)

Vacuolar Processing Enzymes in Plant Programmed Cell Death and Autophagy.

Vacuolar processing enzymes (VPEs) are plant cysteine proteases that are subjected to autoactivation in an acidic pH. It is presumed that VPEs, by activating other vacuolar hydrolases, are in control of tonoplast rupture during programmed cell death (PCD). Involvement of VPEs has been indicated in various types of plant PCD related to development, senescence, and environmental stress responses. Another pathway induced during such processes is autophagy, which leads to the degradation of cellular components and metabolite salvage, and it is presumed that VPEs may be involved in the degradation of autophagic bodies during plant autophagy. As both PCD and autophagy occur under similar conditions, research on the relationship between them is needed, and VPEs, as key vacuolar proteases, seem to be an important factor to consider. They may even constitute a potential point of crosstalk between cell death and autophagy in plant cells. This review describes new insights into the role of VPEs in plant PCD, with an emphasis on evidence and hypotheses on the interconnections between autophagy and cell death, and indicates several new research opportunities.

Effect of mitophagy related genes on the antioxidant properties of Saccharomyces cerevisiae / 生物工程学报

Mitophagy is a process whereby cells selectively remove mitochondria through the mechanism of autophagy, which plays an important role in maintaining cellular homeostasis. In order to explore the effect of mitophagy genes on the antioxidant activities of Saccharomyces cerevisiae, mutants with deletion or overexpression of mitophagy genes ATG8, ATG11 and ATG32 were constructed respectively. The results indicated that overexpression of ATG8 and ATG11 genes significantly reduced the intracellular reactive oxygen species (ROS) content upon H2O2 stress for 6 h, which were 61.23% and 46.35% of the initial state, respectively. Notable, overexpression of ATG8 and ATG11 genes significantly increased the mitochondrial membrane potential (MMP) and ATP content, which were helpful to improve the antioxidant activities of the strains. On the other hand, deletion of ATG8, ATG11 and ATG32 caused mitochondrial damage and significantly decreased cell vitality, and caused the imbalance of intracellular ROS. The intracellular ROS content significantly increased to 174.27%, 128.68%, 200.92% of the initial state, respectively, upon H2O2 stress for 6 h. The results showed that ATG8, ATG11 and ATG32 might be potential targets for regulating the antioxidant properties of yeast, providing a new clue for further research.

Analysis of the Compositional Features and Codon Usage Pattern of Genes Involved in Human Autophagy.

Autophagy plays an intricate role in paradigmatic human pathologies such as cancer, and neurodegenerative, cardiovascular, and autoimmune disorders. Autophagy regulation is performed by a set of autophagy-related (ATG) genes, first recognized in yeast genome and subsequently identified in other species, including humans. Several other genes have been identified to be involved in the process of autophagy either directly or indirectly. Studying the codon usage bias (CUB) of genes is crucial for understanding their genome biology and molecular evolution. Here, we examined the usage pattern of nucleotide and synonymous codons and the influence of evolutionary forces in genes involved in human autophagy. The coding sequences (CDS) of the protein coding human autophagy genes were retrieved from the NCBI nucleotide database and analyzed using various web tools and software to understand their nucleotide composition and codon usage pattern. The effective number of codons (ENC) in all genes involved in human autophagy ranges between 33.26 and 54.6 with a mean value of 45.05, indicating an overall low CUB. The nucleotide composition analysis of the autophagy genes revealed that the genes were marginally rich in GC content that significantly influenced the codon usage pattern. The relative synonymous codon usage (RSCU) revealed 3 over-represented and 10 under-represented codons. Both natural selection and mutational pressure were the key forces influencing the codon usage pattern of the genes involved in human autophagy.

The Genetics of Autophagy in Multicellular Organisms.

Autophagy, a lysosome-mediated degradation process evolutionarily conserved from yeast to mammals, is essential for maintaining cellular homeostasis and combating diverse cellular stresses. Autophagy involves de novo synthesis of a double-membrane autophagosome, sequestration of selected cellular contents, and subsequent delivery of sequestrated contents to the vacuole (in yeasts and plants) or to lysosomes (in animal cells) for degradation and recycling. Genetic studies in unicellular and multicellular model organisms have systematically revealed the molecular machinery, regulation, and function of autophagy in physiological settings. I review genetic studies in model organisms-from yeast to worm to fly-that enable us to not only identify autophagy genes, including ATG genes and the metazoan-specific EPG genes, but also uncover variants of autophagy in developmental contexts, novel regulatory mechanisms, and signaling events involved in mediating systemic autophagy response. Genetic analysis also helps us understand the liquid-liquid phase separation and transition that control autophagic degradation of protein aggregates. The emerging role of autophagy in zebrafish tissue regeneration is also discussed.

Metabolism and autophagy in plants-a perfect match.

Autophagy is a eukaryotic cellular transport mechanism that delivers intracellular macromolecules, proteins, and even organelles to a lytic organelle (vacuole in yeast and plants/lysosome in animals) for degradation and nutrient recycling. The process is mediated by highly conserved autophagy-related (ATG) proteins. In plants, autophagy maintains cellular homeostasis under favorable conditions, guaranteeing normal plant growth and fitness. Severe stress such as nutrient starvation and plant senescence further induce it, thus ensuring plant survival under unfavorable conditions by providing nutrients through the removal of damaged or aged proteins, or organelles. In this article, we examine the interplay between metabolism and autophagy, focusing on the different aspects of this reciprocal relationship. We show that autophagy has a strong influence on a range of metabolic processes, whereas at the same time, even single metabolites can activate autophagy. We highlight the involvement of ATG genes in metabolism, examine the role of the macronutrients carbon and nitrogen, and various micronutrients, and take a closer look at how the interaction between autophagy and metabolism impacts on plant phenotypes and yield.

Interactions between autophagy and phytohormone signaling pathways in plants.

Autophagy is a conserved recycling process with important functions in plant growth, development, and stress responses. Phytohormones also play key roles in the regulation of some of the same processes. Increasing evidence indicates that a close relationship exists between autophagy and phytohormone signaling pathways, and the mechanisms of interaction between these pathways have begun to be revealed. Here, we review recent advances in our understanding of how autophagy regulates hormone signaling and, conversely, how hormones regulate the activity of autophagy, both in plant growth and development and in environmental stress responses. We highlight in particular recent mechanistic insights into the coordination between autophagy and signaling events controlled by the stress hormone abscisic acid and by the growth hormones brassinosteroid and cytokinin and briefly discuss potential connections between autophagy and other phytohormones.

Breakthroughs and bottlenecks in autophagy research.

The study of autophagy has grown exponentially over the past two decades, and significant progress has been made in our understanding of its mechanisms and physiological significance. However, its application to human diseases remains limited. Here, we summarize the current status of autophagy research, with a particular focus on human diseases.

Autophagy Dances with Phytohormones upon Multiple Stresses.

Autophagy is an evolutionarily conserved process for turning over unwanted cellular components, thus promoting nutrient recycling and maintaining cellular homeostasis, which eventually enables plants to survive unfavorable growth conditions. In addition to plant growth and development, previous studies have demonstrated that autophagy is involved in the responses to various environmental challenges through interplaying with multiple phytohormones, including abscisic acid (ABA), jasmonic acid (JA), and salicylic acid (SA). In this review, we summarize the advances made in their synergistic interactions in response to multiple abiotic and biotic stresses; we also discuss the remaining issues and perspectives regarding their crosstalk.

Transcriptional and Epigenetic Regulation of Autophagy in Plants.

Autophagy, a highly conserved quality control mechanism, is essential for maintaining cellular homeostasis and healthy growth of plants. Compared with extensive research in the cytoplasmic control of autophagy, studies regarding the nuclear events involved in the regulation of plant autophagy are just beginning to emerge. Accumulating evidence reveals a coordinated expression of plant autophagy genes in response to diverse developmental states and growth conditions. Here, we summarize recent progress in the identification of tightly controlled transcription factors and histone marks associated with the autophagic process in plants, and propose several modules, consisting of transcription regulators and epigenetic modifiers, as important nuclear players that could contribute to both short-term and long-term controls of plant autophagy at the transcriptional and post-transcriptional levels.

EZH2 regulates H2B phosphorylation and elevates colon cancer cell autophagy.

Epigenetic alterations, especially histone modification, play vital roles in the pathogenesis of colon cancer. Upregulation of the enhancer of zeste homolog 2 (EZH2) has been reported to contribute to the initiation and progression of colon cancer. This study analyzed the association between EZH2 and phosphorylation of H2B at tyrosine 37 (H2BY37ph ) in colon cancer tissues and cells, along with the influences of the EZH2-H2BY37ph axis on colon cancer cell autophagy. Immunohistochemistry was utilized to assess EZH2 and H2BY37ph expressions in clinical samples of colon cancer. Cell transfection was carried out to alter EZH2 and H2BY37ph expressions in colon cancer cells. Co-immunoprecipitation analysis and glutathione-S-transferase (GST) pull down assay were conducted to analyze the association between EZH2 and H2BY37ph . Western blotting was utilized to measure proteins expressions related to cell autophagy. We found that there was a positive association between EZH2 and H2BY37ph in colon cancer tissues and cells. EZH2 directly interacted with H2B and promoted H2BY37ph in colon cancer cells using ATP as a phosphate donor. Moreover, EZH2 levated colon cancer cell autophagy in starvation condition. H2BY37ph was required for EZH2-elevated colon cancer cell autophagy under starvation condition. The EZH2-H2BY37ph axis elevated colon cancer cell autophagy possibly via activating transcriptional regulation of ATG genes. In conclusion, EZH2-elevated colon cancer initiation and progression at least in part via inducing colon cancer cell autophagy. EZH2 could phosphorylate H2BY37 and then induce transcription activation of ATG genes in colon cancer cells under starvation condition.

Lawsone, a 2-hydroxy-1,4-naphthoquinone from Lawsonia inermis (henna), produces mitochondrial dysfunctions and triggers mitophagy in Saccharomyces cerevisiae.

Lawsone is a natural naphthoquinone present in the henna leaf extract with several cytotoxic activities and used as precursor for synthesis of various pharmaceutical compounds. Its biological activities are thought to be the result of oxidative stress generated, although the hydroxy group at position C-2 in its structure tends to reduce its electrophilic potential. In view of lack of knowledge on its activity, the present work aimed to elucidate the biological effect of lawsone using the yeast Saccharomyces cerevisiae. In the model strain BY4741 it was defined 229 mmol/L as the minimal inhibitory concentration (MIC). Using 172 mmol/L as sub-MIC value it was observed that yap1 deletion mutant was sensitive to lawsone independent the presence of oxygen. Lawsone affected yeast growth in glycerol, indicating interference in the respiratory metabolism. Intracellular content of thiol groups did not indicate intensive oxidative stress and the presence of the anti-oxidant N-acetylcysteine (NAC) exacerbated lawsone toxicity. By analysing the sensitivity of atg mutant strains and the localization of GFP-Atg8 fusion protein, it was concluded that lawsone primarily produces mitochondrial malfunctioning, leading to indirect oxidative stress. It triggers the autophagic response that ultimately induces mitophagy.

History and Current Status of Autophagy Research.

Autophagy is an evolutionarily conserved process in which eukaryotic bilayer membrane vesicles enclose intracellular contents and transport them to lysosomes for degradation. In the 1990s, Ohsumi et al. identified multiple autophagy-related genes in a yeast model. Functional homologues of almost all yeast autophagy-related genes were found in higher eukaryotes. In 2003, Klionsky et al. named these genes the Atg genes and studied the interactions between the proteins they encoded and their functions in autophagy. In April 2005, a new journal, Autophagy, was published that was edited by Klionsky. The number of autophagy research papers indexed by PubMed has increased each year. In 2016, Yoshinori Ohsumi won the Nobel Prize in Medicine or Physiology for his discovery of the autophagy mechanism. Autophagy has thus become a hot research area, which involves biology, medicine, botany and microbiology. Many researchers are actively exploring the relationship between non-selective and selective autophagy and various pathophysiological states in humans, and are studying the molecular mechanisms underlying autophagy regulation in various biological conditions, including cancer, neurodegenerative diseases, cardiovascular diseases, immune responses, development and ageing. This chapter focuses on the history and current status of autophagy research and highlights the milestones that contributed to the development of the field.

Sirt1 modulates H3 phosphorylation and facilitates osteosarcoma cell autophagy.

Abnormal histone modifications have been recognized as an important contributing factor to the initiation and progression of osteosarcoma. Sirtuin 1 (Sirt1) up-regulation has been discovered in osteosarcoma cells. This study tested the influence of Sirt1 on histone H3 phosphorylation at threonine 3 (H3T3ph) in osteosarcoma cells, along with Sirt1-H3T3ph axis on osteosarcoma cell autophagy. Plasmids or si-RNAs transfection was carried out to alter Sirt1 or H3T3ph expressions. Co-immunoprecipitation analysis and GST pull-down assay were done to probe the relationship between Sirt1 and H3T3ph. Phosphoryltransferase activity of Sirt1 was tested by in vitro kinase activity assay. Cell autophagy was measured by a number of autophagosome, conversion of LC3-I to LC3-II, degradation of long-lived protein and ATG protein expressions. We found that Sirt1 directly interacted with H3 and phosphorylate H3T3 at threonine 3 in osteosarcoma cells. Moreover, Sirt1 facilitated osteosarcoma cell autophagy under starvation condition. H3T3ph took part in the Sirt1-facilitated osteosarcoma cell autophagy under starvation condition. Besides, Sirt1-H3T3ph axis facilitated osteosarcoma cell autophagy might be achieved through transcriptional activation of ATG genes. Sirt1 promoted osteosarcoma initiation and progression might be via phosphorylate H3T3 and then facilitate osteosarcoma cell autophagy through activating ATG genes transcription under starvation condition.

Conserved Autophagy Pathway Contributes to Stress Tolerance and Virulence and Differentially Controls Autophagic Flux Upon Nutrient Starvation in Cryptococcus neoformans.

Autophagy is mainly a catabolic process, which is used to cope with nutrient deficiency and various stress conditions. Human environment often imposes various stresses on Cryptococcus neoformans, a major fungal pathogen of immunocompromised individuals; therefore, autophagic response of C. neoformans to these stresses often determines its survival in the host. However, a systematic study on how autophagy related (ATG) genes influence on autophagic flux, virulence, stress response and pathogenicity of C. neoformans is lacking. In this study, 22 ATG-deficient strains were constructed to investigate their roles in virulence, pathogenesis, stress response, starvation tolerance and autophagic flux in C. neoformans. Our results showed that Atg6 and Atg14-03 significantly affect the growth of C. neoformans at 37°C and laccase production. Additionally, atg2Δ and atg6Δ strains were sensitive to oxidative stress caused by hydrogen peroxide. Approximately half of the atgΔ strains displayed higher sensitivity to 1.5 M NaCl and remarkably lower virulence in the Galleria mellonella model than the wild type. Autophagic flux in C. neoformans was dependent on the Atg1-Atg13, Atg5-Atg12-Atg16, and Atg2-Atg18 complexes and Atg11. Cleavage of the green fluorescent protein (GFP) from Atg8 was difficult to detect in these autophagy defective mutants; however, it was detected in the atg3Δ, atg4Δ, atg6Δ and atg14Δ strains. Additionally, no homologs of Saccharomyces cerevisiae ATG10 were detected in C. neoformans. Our results indicate that these ATG genes contribute differentially to carbon and nitrogen starvation tolerance in C. neoformans compared with S. cerevisiae. Overall, this study advances our knowledge of the specific roles of ATG genes in C. neoformans.

The role of autophagy in morphogenesis and stem cell maintenance.

During embryonic development, cells need to undergo a number of morphological changes that are decisive for the shaping of the embryo's body, initiating organogenesis and differentiation into functional tissues. These remodeling processes are accompanied by profound changes in the cell membrane, the cytoskeleton, organelles, and extracellular matrix composition. While considerably detailed insight into the role of autophagy in stem cells biology has been gained in the recent years, information regarding the participation of autophagy in morphogenetic processes is only sparse. This review, therefore, focuses on the role of autophagy in cell morphogenesis through its regulatory activity in TGFß signaling, expression of adhesion molecules and cell cycle modification. It also discusses the role of autophagy in stem cell maintenance which is very fundamental for cell renewal and replacement during development, pathogenesis of certain diseases and development of therapies. We are thus addressing here perspectives for further potentially rewarding research topics.

Autophagy counteracts instantaneous cell death during seasonal senescence of the fine roots and leaves in Populus trichocarpa.

BACKGROUND: Senescence, despite its destructive character, is a process that is precisely-regulated. The control of senescence is required to achieve remobilization of resources, a principle aspect of senescence. Remobilization allows plants to recapture valuable resources that would otherwise be lost to the environment with the senescing organ. Autophagy is one of the critical processes that is switched on during senescence. This evolutionarily conserved process plays dual, antagonistic roles. On the one hand, it counteracts instantaneous cell death and allows the process of remobilization to be set in motion, while on the other hand, it participates in the degradation of cellular components. Autophagy has been demonstrated to occur in many plant species during the senescence of leaves and flower petals. Little is known, however, about the senescence process in other ephemeral organs, such as fine roots, whose lifespan is also relatively short. We hypothesized that, like the case of seasonal leaf senescence, autophagy also plays a role in the senescence of fine roots, and that both processes are synchronized in their timing. RESULTS: We evaluated which morphological and cytological symptoms are universal or unique in the senescence of fine roots and leaves. The results of our study confirmed that autophagy plays a key role in the senescence of fine roots, and is associated also with the process of cellular components degradation. In both organs, structures related to autophagy were observed, such as autophagic bodies and autophagosomes. The role of autophagy in the senescence of these plant organs was further confirmed by an analysis of ATG gene expression and protein detection. CONCLUSIONS: The present study is the first one to examine molecular mechanisms associated with the senescence of fine roots, and provide evidence that can be used to determine whether senescence of fine roots can be treated as another example of developmentally programmed cell death (dPCD). Our results indicate that there is a strong similarity between the senescence of fine roots and other ephemeral organs, suggesting that this process occurs by the same autophagy-related mechanisms in all plant ephemeral organs.

Autophagy participates in innate immune defense in lamprey.

Autophagy is a homeostatic process which degrades cytoplasmic constituents to maintain the balance of organs when they were challenged with nutrient stress. It also participates in cancer, neurodegenerative disorders, aging and innate immune defense. In order to reveal how autophagy participates in innate immune response when invertebrates evolved into vertebrates. Firstly, we performed a systematic analysis of Atg genes and found that they are highly conserved among lancelet, lamprey and zebrafish. Then, we observed autophagosomes upon starvation by TEM in lancelet, lamprey and zebrafish and found that the morphology of autophagosome is similar to that was observed in yeast and mammals. In addition, rapamycin can induce autophagy in lamprey leukocytes and the deficiency of human Beclin1 protein can be rescued by lancelet and lamprey Beclin1 proteins. When lamprey leukocytes were treated with polyI:C and LPS, autophagy was induced. Moreover, when lamprey leukocytes were challenged with live E. coli, phagocytosis along with autophagy was triggered to degrade pathogenic bacteria. In all, our study here indicated that autophagy is highly conserved during evolution and plays a key role in innate defense when invertebrates evolved into vertebrates.