Reduction of superoxide production by mitochondria oxidizing NADH in the presence of organic acids

Effects of multiple substrates on oxygen uptake and superoxide production by mitochondria isolated from the pericarp tissue of green bell pepper (Capsicum annuum L.) were studied. Mitochondria isolated from peppers stored at 4 °C for 5 and 6 days had higher rates of oxygen uptake and were less sensitive to cyanide than mitochondria isolated from freshly harvested peppers. Succinate enhanced state 2 and state 4 rates of oxygen uptake with exogenous NADH in the absence of cytochrome path inhibitors, but not state 3 rates by mitochondria isolated from either freshly harvested or cold-stored bell peppers. The sensitivity of NADH oxidation to cyanide was reduced by both malate and succinate in mitochondria from cold-stored bell peppers, whereas only succinate was effective in mitochondria from freshly harvested peppers.Mitochondria isolated from both freshly harvested peppers and those stored at 4 °C for 5 and 6 days produced superoxide in the absence of exogenous substrates. Superoxide production by mitochondria from freshly harvested bell peppers increased when the mitochondria were supplied with malate, succinate or NADH, but only NADH enhanced superoxide production by mitochondria from cold-stored peppers. Both succinate and malate reduced the production of superoxide by mitochondria isolated from cold-stored bell peppers. Succinate and malate as second substrates also reduced the production of superoxide with NADH by mitochondria from both freshly harvested and cold-stored bell peppers. Malonate, a competitive inhibitor of succinate dehydrogenase, was inhibitory to oxygen uptake and to superoxide production.Mitochondria isolated from cold-stored bell peppers converted succinate to pyruvate at 25 °C at considerably higher rates than those of mitochondria from freshly harvested bell peppers. Since pyruvate has been shown to activate the alternative oxidase and the presence of pyruvate is essential for continued alternative oxidase activity, we suggest that pyruvate limits superoxide production by enhancing the flow of electrons through the alternative path. A direct scavenging of superoxide by succinate, malate and pyruvate, however, cannot be ruled out.     

赤霞珠葡萄果实苹果酸生物合成关键转录因子的筛选与鉴定

该研究以宁夏贺兰山东麓酿酒葡萄种植区栽培面积最大的‘赤霞珠’为材料,在前期完成从果实形成至成熟不同发育时期的转录组测序以及关键有机酸含量测定基础上,进一步通过转录因子结合位点预测、差异表达基因分析、加权基因共表达网络关联分析(WGCNA),逐步筛选出与‘赤霞珠’果实苹果酸生物合成相关功能基因特异结合的、影响苹果酸生物合成的相应转录因子,并对其进行qRT PCR验证,以揭示这些关键功能基因及其关键转录因子在葡萄不同种植区、果实不同发育时期存在的相互调控作用机制,为以后培育优质酿酒葡萄提供新的理论依据与思路。结果表明：(1)GC/MS分析发现, ‘赤霞珠’果实在4个发育时期的延胡索酸和苹果酸含量变化趋势基本一致,两种酸含量均从果实硬果期到绿果期逐步升至最高(3.63和626.53 μg/g),之后缓慢下降,经转色期到成熟期后逐渐降至最低(2.14和244.26 μg/g),而草酰乙酸的变化趋势却相反,在硬果期含量最高(315.54 μg/g),经绿果期、转色期到成熟期逐渐降至最低值(126.11 μg/g)。(2)‘赤霞珠’果实发育时期样本转录组测序共获得可能与苹果酸生物合成途径12种功能基因结合的转录因子6 411个,其中延胡索酸水化酶(FH)的3个功能基因有86个转录因子,苹果酸脱氢酶(MDH)的10个功能基因有717个转录因子。(3)转录组测序数据及其与有机酸含量WGCNA关联结果的Veen分析确定了‘赤霞珠’果实成熟过程中与苹果酸生物合成相关度最高的3个FH基因(VIT_14s0060g01700、VIT_13s0019g03330、VIT_07s0005g00880)、2个MDH基因(VIT_10s0003g01000、VIT_13s0019g05250)及相应的18个关键转录因子。(4)qRT PCR验证及相关性分析表明, FH基因VIT_13s0019g03330与其转录因子VIT_01s0011g06200、VIT_08s0056g01230以及MDH基因VIT_13s0019g05250与其转录因子VIT_06s0004g04960、VIT_10s0003g02070的表达水平与苹果酸的积累存在显著正相关关系,推测这4个关键转录因子可能通过调控功能基因的转录,综合影响‘赤霞珠’果实苹果酸的生物合成。     

草酰乙酸和苹果酸对菠菜叶片和完整叶绿体光合作用的影响

观测了OAA和MA对菠菜叶片和完整叶绿体光合作用的影响.结果显示,当叶片切块在20μmol/L的OAA存在时,其叶片的光合放氧速率增加了89%,经OAA处理的离体完整叶绿体的光合放氧速率增加了72%;当反应体系中存在有较高浓度的NaHCO3时,OAA的作用不明显.叶片经20 μmol/L的MA处理后,叶片光合放氧速率比对照高127%.用CO2分析仪观测了处理后叶片的净光合速率(Pn),结果显示,OAA和MA处理后的叶片Pn值分别是对照的117%和111%.对在C3植物中建立C4微循环系统来提高光合作用效率的可能性进行了讨论.     

耐铝的和对铝敏感的玉米自交系根系的有机酸分泌

对玉米不同耐铝自交系在含A1^3 (0.1mmol/L)的完全营养液和A1C13 14．3μmol/L CaCl2 227．5μmol/L溶液等两种溶液中根系有机酸的分泌特征进行了研究。铝胁迫下,耐铝自交系Z1的生长与正常偏离不大,表现出较强的耐铝性,而铝敏感自交系Z2的生长则受到明显抑制。2种自交系根系分泌的有机酸种类包括苹果酸、柠檬酸、琥珀酸、马米酸、乙酸和草酸等,以苹果酸为主;其分泌量随铝处理时间而异。在两种溶液中,铝胁迫均可显著增加Z1苹果酸分泌量,且根系内苹果酸含量也显著增加。铝胁迫下,Z1根系NADP—苹果酸脱氢酶活性显著增加。从对试验结果分析得出：根系分泌苹果酸可能是玉米耐铝自交系适应酸性土壤逆境的生理特性之一,而分泌的苹果酸可能是在根系中通过PEP→4OAA→苹果酸途径合成的。     

In-depth Profiling and Quantification of the Lysine Acetylome in Hepatocellular Carcinoma with a Trapped Ion Mobility Mass Spectrometer

Hepatocellular carcinoma (HCC) is the third most common cause of cancer-related death worldwide with limited therapeutic options. Comprehensive investigation of protein posttranslational modifications in HCC is still limited. Lysine acetylation is one of the most common types of posttranslational modification involved in many cellular processes and plays crucial roles in the regulation of cancer. In this study, we analyzed the proteome and K-acetylome in eight pairs of HCC tumors and normal adjacent tissues using a timsTOF Pro instrument. As a result, we identified 9219 K-acetylation sites in 2625 proteins, of which 1003 sites exhibited differential acetylation levels between tumors and normal adjacent tissues. Interestingly, many novel tumor-specific K-acetylation sites were characterized, for example, filamin A (K865), filamin B (K697), and cofilin (K19), suggesting altered activities of these cytoskeleton-modulating molecules, which may contribute to tumor metastasis. In addition, we observed an overall suppression of protein K-acetylation in HCC tumors, especially for enzymes from various metabolic pathways, for example, glycolysis, tricarboxylic acid cycle, and fatty acid metabolism. Moreover, the expression of deacetylase sirtuin 2 (SIRT2) was upregulated in HCC tumors, and its role of deacetylation in HCC cells was further explored by examining the impact of SIRT2 overexpression on the proteome and K-acetylome in Huh7 HCC cells. SIRT2 overexpression reduced K-acetylation of proteins involved in a wide range of cellular processes, including energy metabolism. Furthermore, cellular assays showed that overexpression of SIRT2 in HCC cells inhibited both glycolysis and oxidative phosphorylation. Taken together, our findings provide valuable information to better understand the roles of K-acetylation in HCC and to treat this disease by correcting the aberrant acetylation patterns.     

Integrated Application of Multiomics Strategies Provides Insights Into the Environmental Hypoxia Response in Pelteobagrus vachelli Muscle

Increasing pressures on aquatic ecosystems because of pollutants, nutrient enrichment, and global warming have severely depleted oxygen concentrations. This sudden and significant lack of oxygen has resulted in persistent increases in fish mortality rates. Revealing the molecular mechanism of fish hypoxia adaptation will help researchers to find markers for hypoxia induced by environmental stress. Here, we used a multiomics approach to identify several hypoxia-associated miRNAs, mRNAs, proteins, and metabolites involved in diverse biological pathways in the muscles of Pelteobagrus vachelli. Our findings revealed significant hypoxia-associated changes in muscles over 4 h of hypoxia exposure and discrete tissue-specific patterns. We have previously reported that P. vachelli livers exhibit increased anaerobic glycolysis, heme synthesis, erythropoiesis, and inhibit apoptosis when exposed to hypoxia for 4 h. However, the opposite was observed in muscles. According to our comprehensive analysis, fishes show an acute response to hypoxia, including activation of catabolic pathways to generate more energy, reduction of biosynthesis to decrease energy consumption, and shifting from aerobic to anaerobic metabolic contributions. Also, we found that hypoxia induced muscle dysfunction by impairing mitochondrial function, activating inflammasomes, and apoptosis. The hypoxia-induced mitochondrial dysfunction enhanced oxidative stress, apoptosis, and further triggered interleukin-1β production via inflammasome activation. In turn, interleukin-1β further impaired mitochondrial function or apoptosis by suppressing downstream mitochondrial biosynthesis–related proteins, thus resulting in a vicious cycle of inflammasome activation and mitochondrial dysfunction. Our findings contribute meaningful insights into the molecular mechanisms of hypoxia, and the methods and study design can be utilized across different fish species.     

Isoenzyme Patterns of Solanum Nigrum and the Cybrid Plant containing S. Nigrum Genome and S. Tuberosum Plastome

Transfer of chloroplasts from Solanum tuberosum into S. nigrum cell resulted in an atrazine sensitive cybrid plant. The shoots of this cybrid were bleached under atrazine stress. The cybrid displayed identical isoenzyme patterns that have been found in S. nigrum, and thus nuclei of the cybrid plant cells did not integrate any chromosomes or chromosome fragments from S. tuberosum nuclei. Under atrazine stress, differences in the isoenzyme expression were found in both the cybrid and original plants. In the peroxidase patterns, POX-4 was detected while POX-1 disappeared. Esterase patterns were less influenced, EST-4 was expressed in both plants under the influence of atrazine. Atrazine treatment of both cybrid and original plant shoots had specific effects on carbonic anhydrase, malate dehydrogenase, and glutamate oxaloacetate transaminase. The number and/or the staining intensity of bands corresponding to these isoenzymes decreased under atrazine stress more in cybrid plants (atrazine sensitive) than in S. nigrum (atrazine resistant).     

Analogs of nitrofuran antibiotics are potent GroEL/ES inhibitor pro-drugs

In two previous studies, we identified compound 1 as a moderate GroEL/ES inhibitor with weak to moderate antibacterial activity against Gram-positive and Gram-negative bacteria including Bacillus subtilis, methicillin-resistant Staphylococcus aureus, Klebsiella pneumonia, Acinetobacter baumannii, and SM101 Escherichia coli (which has a compromised lipopolysaccharide biosynthetic pathway making bacteria more permeable to drugs). Extending from those studies, we developed two series of analogs with key substructures resembling those of known antibacterials, nitroxoline (hydroxyquinoline moiety) and nifuroxazide/nitrofurantoin (bis-cyclic-N-acylhydrazone scaffolds). Through biochemical and cell-based assays, we identified potent GroEL/ES inhibitors that selectively blocked E. faecium, S. aureus, and E. coli proliferation with low cytotoxicity to human colon and intestine cells in vitro. Initially, only the hydroxyquinoline-bearing analogs were found to be potent inhibitors in our GroEL/ES-mediated substrate refolding assays; however, subsequent testing in the presence of an E. coli nitroreductase (NfsB) in situ indicated that metabolites of the nitrofuran-bearing analogs were potent GroEL/ES inhibitor pro-drugs. Consequently, this study has identified a new target of nitrofuran-containing drugs, and is the first reported instance of such a unique class of GroEL/ES chaperonin inhibitors. The intriguing results presented herein provide impetus for expanded studies to validate inhibitor mechanisms and optimize this antibacterial class using the respective GroEL/ES chaperonin systems and nitroreductases from E. coli and the ESKAPE bacteria.     

Bundle-sheath thylakoids from NADP-malic enzyme-type C4 plants require an exogenous electron donor for enzyme light activation

Light activation of either NADP-malate dehydrogenase (EC 1.1.1.82) or fructose-1,6-bisphosphate phosphatase (EC 3.1.3.11) was assayed in a reconstituted chloroplastic, system comprising the isolated proteins of the ferredoxin-thioredoxin light-activation system and thylakoids from either mesophyll or bundle-sheath tissues of different C₄ plants. While C₄-plant thylakoids functionned almost equally well with C₃-or C₄-plant proteins, the photosyntem-II-deficient bundle-sheath thylakoids from the NADP-malic enzyme type, were unable to perform enzyme photoactivation unless supplemented with an electron donor to photosystem I. Bundle-sheath thylakoids isolated from plants showing no photosystem-II deficiency did not require such an addition. The results are discussed with respect to a possible requirement for a physiological reductant of ferredoxin for enzyme light activation in bundle-sheath, tissues.Abbreviations Chl chlorophyll - DCMU 3-(3, 4-dichlorophenyl)-1,1-dimethylurea - DPIP dichlorophenolindophenol - FBPase fructose-1,6-bisphosphatase - FTR ferredoxin-thioredoxin reductase - NADP-MDH NADP-dependent malate dehydrogenase - PSI, II photosystems I, II