酵母菌中谷胱甘肽的主要生理功能及其代谢调控

谷胱甘肽是生物体内一种重要的三肽小分子 ,具有广泛的生理功能。对谷胱甘肽在酵母细胞中的作用及其代谢调控机制 ,做了较为详细的介绍。这一带有基础性研究的内容 ,对于以酵母为生产菌的谷胱甘肽的生产 ,或是酵母的其他工业化生产 ,具有重要的启示。     

酵母细胞甘油代谢与生理功能研究进展

甘油是酵母细胞生长代谢过程中常见的多元醇物质。尽管甘油的结构简单,代谢途径并不复杂,但是其在细胞内的生理功能十分重要。甘油代谢过程主要参与细胞的高渗透压生理调节和厌氧条件下的胞内氧化还原平衡调节。近年来许多学者在酵母细胞的甘油代谢及生理功能方面开展了深入的研究。在扼要介绍甘油生理代谢的基础上,重点阐述甘油代谢参与细胞高渗压甘油应答信号途径和氧化还原平衡调节的生理机制,同时就酵母细胞甘油合成的代谢工程进行归纳和评述。     

Autophagy: Insights from DEspR-deficiency and haploinsufficiency

We recently showed that DEspR-haploinsufficiency resulted in increased neuronal autophagy and spongiform changes in the adult brain especially the hippocampus, cerebral cortex and basal ganglia, causing cognitive performance deficits. This model demonstrates a causal link between increased autophagy and neurodegenerative changes. This is in contrast with recent observations that decreased autophagy from null mutations of autophagy genes, Atg5 and Atg7, resulted in early neurodegenerative changes. With the observed autophagy phenotype, we then compared the neural tube phenotype of DEspR-deficient mice with knockout mice of genes established to underlie or regulate autophagy. Intriguingly, the hyperproliferative neuroepithelium observed in DEspR-deficient embryos is also detected in null mutants of Ambra1, an autophagy modulator, and two apoptosis genes, Apaf1 and Caspase 9. While all four knockout models exhibited hyperproliferative neuroepithelium, DEspR-deficient mice differed by having greater neural tube cavitation. Additionally, observed DEspR roles in angiogenesis and autophagy recapitulate the association of angiogenesis inhibition and increased autophagy as observed for endostatin and kringle5, thus elucidating an expanding complex network of autophagy, apoptosis and angiogenesis in neuroepithelial development, and an emerging complex spectrum of autophagy effects on neurodegeneration. Nevertheless, DEspR provides a ligand-activated receptor system to modulate autophagy – be it to increase autophagy by inhibition of DEspR-function, or to decrease autophagy by agonist stimulation of DEspR-function.     

Mechanistic Insights into Recognitions of Ubiquitin and Myosin VI by Autophagy Receptor TAX1BP1

TAX1BP1, a ubiquitin-binding adaptor, plays critical roles in the innate immunity and selective autophagy. During autophagy, TAX1BP1 may not only function as an autophagy receptor to recruit ubiquitylated substrates for autophagic degradation, but also serve as a Myosin VI cargo adaptor protein for mediating the maturation of autophagosome. However, the mechanistic basis underlying the specific interactions of TAX1BP1 with ubiquitin and Myosin VI remains elusive. Here, using biochemical, NMR and structural analyses, we elucidate the detailed binding mechanism and uncover the key determinants for the interaction between TAX1BP1 and ubiquitin. In addition, we reveal that both tandem zinc-fingers of TAX1BP1 and the conformational rigidity between them are required for the Myosin VI binding of TAX1BP1, and ubiquitin and Myosin VI are mutually exclusive in binding to TAX1BP1. Collectively, our findings provide mechanistic insights into the dual functions of TAX1BP1 in selective autophagy.     

Acyclovir-Polyethylene Glycol 6000 Binary Dispersions: Mechanistic Insights

The dissolution and subsequent oral bioavailability of acyclovir (ACY) is limited by its poor aqueous solubility. An attempt has been made in this work to provide mechanistic insights into the solubility enhancement and dissolution of ACY by using the water-soluble carrier polyethylene glycol 6000 (PEG6000). Solid dispersions with varying ratios of the drug (ACY) and carrier (PEG6000) were prepared and evaluated by phase solubility, in vitro release studies, kinetic analysis, in situ perfusion, and in vitro permeation studies. Solid state characterization was done by powder X-ray diffraction (XRD), differential scanning calorimetry (DSC), and Fourier transform infrared (FTIR) analysis, and surface morphology was assessed by polarizing microscopic image analysis, scanning electron microscopy, atomic force microscopy, and nuclear magnetic resonance analysis. Thermodynamic parameters indicated the solubilization effect of the carrier. The aqueous solubility and dissolution of ACY was found to be higher in all samples. The findings of XRD, DSC, FTIR and NMR analysis confirmed the formation of solid solution, crystallinity reduction, and the absence of interaction between the drug and carrier. SEM and AFM analysis reports ratified the particle size reduction and change in the surface morphology in samples. The permeation coefficient and amount of ACY diffused were higher in samples in comparison to pure ACY. Stability was found to be higher in dispersions. The results suggest that the study findings provided clear mechanical insights into the solubility and dissolution enhancement of ACY in PEG6000, and such findings could lay the platform for resolving the poor aqueous solubility issues in formulation development.     

High-Altitude Adaptation: Mechanistic Insights from Integrated Genomics and Physiology

Population genomic analyses of high-altitude humans and other vertebrates have identified numerous candidate genes for hypoxia adaptation, and the physiological pathways implicated by such analyses suggest testable hypotheses about underlying mechanisms. Studies of highland natives that integrate genomic data with experimental measures of physiological performance capacities and subordinate traits are revealing associations between genotypes (e.g., hypoxia-inducible factor gene variants) and hypoxia-responsive phenotypes. The subsequent search for causal mechanisms is complicated by the fact that observed genotypic associations with hypoxia-induced phenotypes may reflect second-order consequences of selection-mediated changes in other (unmeasured) traits that are coupled with the focal trait via feedback regulation. Manipulative experiments to decipher circuits of feedback control and patterns of phenotypic integration can help identify causal relationships that underlie observed genotype–phenotype associations. Such experiments are critical for correct inferences about phenotypic targets of selection and mechanisms of adaptation.     

Autophagy and Related processes in Trypanosomatids: Insights from Genomic and Bioinformatic Analyses

The targeting in eukaryotic cells of cellular components to the lysosome or vacuole for degradation is called autophagy. Not only cytoplasmic macromolecules and bulk cytoplasm are subject to this process; entire organelles such as peroxisomes can be processed. Autophagy of peroxisomes is called pexophagy. Unpublished evidence suggests that the analogous processing of glycosomes in the protozoan kinetoplastidsoccurs. Taking advantage of the (near-) complete status of three trypanosomatid genomes, a census of components of autophagy and related processes has been undertaken in these organisms. Simple database searches were supplemented by more advanced analyses where necessary. At most, only half of the components characterized in yeasts are present in trypanosomatids suggesting an unexpectedly streamlined version of autophagy occurs in these organisms. The cytosol-to-vacuole transport (CVT) system for delivery of proteins to the vacuole seems entirely absent in trypanosomatids. The accuracy of the census is supported by the coordinated absence of functionally linked components such as the conjugation system involving ATG12, ATG5, ATG10 and ATG16 that acts at the step of vesicle expansion and completion. Overall, the results areconsistent with a scenario of taxon-specific addition of components to a minimal core, a hypothesis that should be readily testable by further genomic surveys allied to laboratory experiments. A bioinformatics analysis of the trypanosomatidal proteins was carried out, highlighting the paucity of information available regarding their structures and enabling prioritization of targets for future structural biology work.     

Autophagy in plants: Physiological roles and post‐translational regulation

In eukaryotes, autophagy helps maintain cellular homeostasis by degrading and recycling cytoplasmic materials via a tightly regulated pathway.Over the past few decades, significant progress has been made towards understanding the physiological functions and molecular regulation of autophagy in plant cells. Increasing evidence indicates that autophagy is essential for plant responses to several developmental and environmental cues, functioning in diverse processes such as senescence, male fertility, root meristem maintenance, responses to nutrient starvation,and biotic and abiotic stress. Recent studies have demonstrated that, similar to nonplant systems,the modulation of core proteins in the plant autophagy machinery by posttranslational modifications such as phosphorylation, ubiquitination,lipidation, S-sulfhydration, S-nitrosylation, and acetylation is widely involved in the initiation and progression of autophagy. Here, we provide an overview of the physiological roles and posttranslational regulation of autophagy in plants.     

Regulation of Neuronal Autophagy in Axon: Implication of Autophagy in Axonal Function and Dysfunction/Degeneration

Autophagy has recently emerged as potential drug target for prevention of neurodegeneration. However, the details of the autophagy process and regulation in the central nervous system (CNS) are unclear. By using a neuronal excitotoxicity model in mice, we engineered expression of a fluorescent autophagic marker and systematically investigated autophagic activity under neurodegenerative conditions. The study reveals an early response of Purkinje cells to excitotoxic insult by induction of autophagy in axon terminals, and that axonal autophagy is particularly robust in comparison to the cell body and dendrites. The accessibility of axons to rapid autophagy induction suggests local biogenesis of autophagosomes in axons. Characterization of functional interaction between autophagosome protein LC3 and microtubule-associated protein 1B (MAP1B), which is involved in axonal growth, injury and transport provides evidence for neuron- or axon-specific regulation of autophagosomes. Furthermore, we propose that p62/SQSTM1, a putative autophagic substrate, can serve as a marker for evaluating impairment of autophagic degradation, which helps resolve the controversy over autophagy levels under various pathological conditions. Future study of the relationship between autophagy and axonal function (e.g., transport) will provide insight into the mechanism underlying axonopathy which is directly linked to neurodegeneration.

Addendum to:

Induction of Autophagy in Axonal Dystrophy and Degeneration

Q.J. Wang, Y. Ding, Y. Zhong, D.S. Kohtz, N. Mizushima, I.M. Cristea, M.P. Rout, B.T. Chait, N. Heintz and Z. Yue

J Neurosci 2006; 26:8057-68     

Methods for Monitoring Autophagy from Yeast to Human

The increasing interest in autophagy in a wide range of organisms, accompanied by an ever-growing influx of researchers into this field, necessitates a good understanding of the methodologies available to monitor this process. In this review we discuss current approaches that can be used to follow the overall process of autophagy, as well as individual steps, from yeast to human. The majority of the review considers methods that apply to macroautophagy; however, we also consider alternative types of degradation including chaperone-mediated autophagy and microautophagy. This information is meant to provide a resource for newcomers as well as a stimulus for experienced researchers who may be prompted to develop additional assays to examine autophagy-related pathways.     

Cdc14 Phosphatase Promotes TORC1-Regulated Autophagy in Yeast

Cdc14 protein phosphatase is critical for late mitosis progression in budding yeast, although its orthologs in other organisms, including mammalian cells, function as stress-responsive phosphatases. We found herein unexpected roles of Cdc14 in autophagy induction after nutrient starvation and target of rapamycin complex 1 (TORC1) kinase inactivation. TORC1 kinase phosphorylates Atg13 to repress autophagy under nutrient-rich conditions, but if TORC1 becomes inactive upon nutrient starvation or rapamycin treatment, Atg13 is rapidly dephosphorylated and autophagy is induced. Cdc14 phosphatase was required for optimal Atg13 dephosphorylation, pre-autophagosomal structure formation, and autophagy induction after TORC1 inactivation. In addition, Cdc14 was required for sufficient induction of ATG8 and ATG13 expression. Moreover, Cdc14 activation provoked autophagy even under normal conditions. This study identified a novel role of Cdc14 as the stress-responsive phosphatase for autophagy induction in budding yeast.     

Applicability of Yeast Extracellular Proteinases in Brewing: Physiological and Biochemical Aspects

A general screening survey for expression of extracellular acid proteinase production was performed on over 100 cultures belonging to the genus Saccharomyces. Although two strains of Saccharomyces cerevisiae showed positive extracellular proteinase phenotypes in plate tests, it was not possible to demonstrate proteolytic activities in cell-free culture supernatants in assays performed at beer pH values. Of several yeasts from other genera examined, Saccharomycopsis fibuligera and Torulopsis magnoliae produced extracellular proteinases with desirable properties. Proteolytic activities were detected in assays performed at beer pH values and at lower temperature. Brewer's wort served as a highly inducing medium for extracellular proteinase production, with T. magnoliae yielding enzyme of highest specific activity. In fact, commencement of enzyme production was detected shortly after the onset of exponential growth in brewer's wort. Inclusion of crude enzyme preparations in brewer's wort inoculated simultaneously with brewer's yeast reduced final ethanol yields slightly and was found to be effective in reducing chill haze formation in bottled beer.