Mechanisms associated with tiller suppression under stagnant flooding in rice

Stagnant flooding (SF) during vegetative growth triggers stem elongation usually at the cost of tiller production in rice, reducing grain yield. To explore physiological mechanisms associated with tillering suppression under SF, three contrasting genotypes (Swarna and Swarna‐Sub1, both sensitive and IRRI154, tolerant) were evaluated under standing water depths of 0, 5, 30 and 50 cm. SF significantly suppressed tiller formation but increased plant height, root biomass, shoot elongation (ratio of plant height before and after flooding), leaf emergency and non‐structural carbohydrate (NSC) concentration (in root–shoot junction) in all genotypes at the early stage of development. Chlorophyll concentration in the upper leaves (upper most fully expanded leaf at top) was higher than in lower leaves (lowest green leaf at base), but decreased under SF in both. SF increased hydrogen peroxide (H₂O₂) at the early stage of treatment, with concomitant increase in malondialdehyde (MDA) production by stems and leaves. MDA concentration in root–shoot junction increased but delayed. Tiller number correlated negatively with plant height, shoot elongation, leaf emergency, MDA concentration in leaves and root–shoot junction, root biomass, and NSC concentration in the root–shoot junction. The results suggested existence of compensatory mechanisms between tiller growth and shoot elongation in rice for resilience under SF, where energy is mainly diverted for shoot elongation to escape flooding. The SF‐tolerant genotype produced less H₂O₂ and maintained energy balance for higher survival and better growth under stagnant flooding.     

Repeated annual drought has minor long‐term influence on δ13C and alkane composition of plant and soil in model grassland and heathland ecosystems

As a result of global climate change the incidence of drought conditions in Europe is predicted to increase in the future, which also influences plant resistance. Lipids are important plant constituents that protect plants against drought stress and contribute to the intermediate stable carbon (C) pool in soil. However, the extent to which drought influences lipid cycling in the plant–soil system is unknown and, therefore, it remains questionable how the ecosystem recovers after drought. We focused on plant and soil samples from two different plant communities (temperate grassland and heathland) that had been exposed to 5 years of 4.5–6.0 weeks repeated annual drought. They were sampled one year after the last drought to check the recovery of the plant–soil system. Samples were analyzed for their bulk C, stable C and nitrogen (N) isotope (δ¹³C, δ¹⁵N) and lipid composition. Contrary to our expectation, no strong influence of five years of repeated annual drought was observed for above‐ground biomass, roots and soils in the model ecosystems with respect to elemental (C and N concentrations, C : N ratio) bulk isotope (δ¹³C, δ¹⁵N) composition and the total extractable lipid concentration. Thus, plants did not sustain a significant change in their C and lipid concentration as well as their composition after five years of repeated annual drought. This might be related to the comparatively short drought period related to the overall growth season and provides evidence for recovery of the C and lipid dynamics in temperate grassland and heathland model ecosystems exposed to annual drought.     

Mineralization of “non‐metabolizable” glucose analogues in soil: potential chemosensory mimics of glucose

Glucose is widely used to study the dynamics of easily available organics in soil. Pure culture studies have revealed that many microorganisms can sense and respond to glucose through chemosensory mechanisms that are not directly reliant on energy catabolism. However, the rapid mineralization of glucose by microorganisms makes it difficult to disentangle its energy effects from such non‐catabolic interactions. “Non‐metabolizable” glucose analogues have proven useful in mechanistic studies of glucose in pure culture, but have never been applied to complex microbial communities in soil. We sought to determine how their mineralization in soil differs from that of glucose, and whether they have potential as a new approach for investigating chemosensory mechanisms in soil microbiology. We incubated soil from an agricultural Haplic Luvisol under controlled conditions for 24 d and monitored CO₂ efflux after addition of (1) glucose, and three “non‐metabolizable” glucose analogues: (2) 2‐deoxyglucose (DG), (3) α‐methylglucoside (αMG), and (4) 3‐O‐methyl‐glucose (OMG), at three concentration levels, along with a control. All three analogues did in fact produce a large increase in soil CO₂ efflux, but the dynamics of their mineralization differed from the rapid degradation seen for glucose. At medium and high concentrations, CO₂ efflux peaked between 2.5 and 4 d after amendment with DG and αMG, and was delayed by about one week for OMG. The markedly different patterns of mineralization between glucose and OMG offer a new tool for investigating the behavior of glucose in soil. By using OMG as a glucose model, chemosensory mechanisms could be studied with limited interference from energy catabolism.     

涝渍对Bt棉棉蕾杀虫蛋白表达含量及氮代谢影响

以Bt棉常规种泗抗1号和杂交种泗抗3号为材料,于盛蕾期设计不同程度涝渍(土壤持水量为最大持水量的90%、100%,渍水2 cm)胁迫4 d以及土壤持水量为最大持水量90%逆境下持续胁迫24~120 h的试验,探讨棉蕾中Bt杀虫蛋白表达量变化及相关氮代谢生理机制。结果表明,土壤不同涝渍程度影响棉蕾Bt蛋白含量。土壤持水量为最大持水量的90%、100%和渍水2 cm处理胁迫后,常规种泗抗1号棉蕾中Bt蛋白含量分别下降36.5%、42.1%和51.4%,杂交种泗抗3号分别下降19.2%、57.2%和64.5%。90%的土壤持水量持续胁迫96 h使棉蕾Bt蛋白含量开始显著下降,泗抗1号和泗抗3号分别下降20.8%和17.6%。随着胁迫时间延长下降幅度增大。不同涝渍程度或水渍持续胁迫条件下,棉蕾中可溶性蛋白含量,硝酸还原酶(NR)、谷氨酸草酰乙酸转氨酶(GOT)、谷氨酸丙酮酸转氨酶(GPT)、谷氨酰胺合成酶(GS)和谷氨酸合成酶(GOGAT)活性下降,游离性氨基酸含量,肽酶、蛋白酶活性增加。说明涝渍逆境下,棉蕾中蛋白质合成能力下降、分解能力增强,引起可溶性蛋白包括Bt杀虫蛋白含量下降,导致棉蕾抗虫性下降。     

Effect of GYY4137 on cytosolic lipid decomposition in mouse primary hepatocytes

AIM: To evaluate the effect of GYY4137, a novel hydrogen sulfide (H₂S) donor, on cytosolic lipid decomposition in mouse primary steatosis hepatocytes. METHODS: Oleic acid (OA) was used to induce hepatic steatosis model in vitro. The C57BL/6 mouse primary hepatocytes isolated and cultured by 2-step in situ perfusion were divided into 4 groups:the cells in control group were incubated with normal medium for 54 h; the cells in model group were incubated with OA at 1.2 mmol/L for 48 h followed by serum-free phenol red-free RPMI-1640 for 6 h; the cells in H₂S group or DL-propar-gylglycine (PAG; an inhibitor of cystathione γ-lysase, inhibiting H₂S synthesis) group were incubated with OA at 1.2 mmol/L for 48 h followed by serum-free phenol red-free RPMI-1640 which contained 1 mmol/L GYY4137 or 200 μmol/L PAG for 6 h. The glycerin release and the protein expression of hormone-sensitive lipase (HSL) in the cells were mea-sured. RESULTS: Compared with model group, the glycerin release and the protein expression of phosphorylated HSL (p-HSL) in H₂S group decreased significantly, while those increased significantly in PAG group. CONCLUSION: In steatosis hepatocytes, exogenous H₂S possibly decreases cytosolic lipid decomposition by decreasing the protein level of p-HSL.     

不同包膜肥用量对油菜碳氮代谢产物和产量的影响

为研究包膜肥在直播早熟油菜上的应用效果,采用田间小区试验,探究不同用量包膜肥对‘湘杂油1613’碳氮代谢和籽粒产量的影响。结果表明,施肥量相同条件下,施用包膜肥油菜碳氮代谢活跃,叶绿素含量(SPAD)升高,可溶性糖和游离氨基酸总量增加,含量差异不明显;单株有效分枝数和角果数明显增加,每角果粒数和千粒重小幅提高。施用包膜肥增产效果明显,包膜肥施肥量为1500 kg/hm~2时产量最高,达到2066.9 kg/hm~2。通过拟合建模,包膜肥用量为1611.0 kg/hm~2时,产量达到最高为2164.9 kg/hm~2;而普通肥的用量为1870.5 kg/hm~2时,最高产量为1904.8 kg/hm~2,包膜肥产量增加13.6%,同时用量减少13.9%。     

茉莉酸甲酯诱导辣椒抗青枯病与活性氧代谢的关系

为探究茉莉酸甲酯(Methyl Jasmonate,Me JA)诱导辣椒抗青枯病效应与活性氧代谢相关酶的关系,以辣椒易感青枯病品种‘粤红1号’和抗青枯病品种‘辛香8号’幼苗为试验材料,在0.1mmol·L-1 Me JA喷雾处理后12、24、48、72和96 h接种青枯劳尔氏菌(Ralstonia solanacearum),对其进行青枯病病情指数与活性氧代谢相关酶——超氧化酶歧化酶(Superoxide Dismutase,SOD)、过氧化氢酶(Catalase,CAT)、过氧化物酶(Peroxidase,POD)和抗坏血酸过氧化物酶(Ascorbate Peroxidase,APX)活性以及丙二醛(Malondialdehyde,MDA)含量测定及相互关系的分析。结果表明:‘粤红1号’和‘辛香8号’的病情指数随喷Me JA处理时间的推移表现为先降后升,但都低于对照;而诱导效果则相反,Me JA处理对两个辣椒品种幼苗抗性的最适诱导时间均为接种前48 h。接种后0~96 h,Me JA喷雾处理的辣椒幼苗叶片SOD、CAT、POD和APX酶活性均显示先升后降的趋势,且明显高于对照,接种后24~48 h达到最高,而MDA含量则明显低于对照。因此,Me JA可诱导辣椒幼苗抗青枯病,其实现途径可能与提高活性氧代谢相关酶活性和缓解膜脂过氧化有关。     

铅和（或）镉对体外培养肾细胞的毒性损伤

在培养液中加入不同浓度的Cd（10、20、40μmol／L）、Pb（10、20、40μmol／L）和Pb-Cd联合（分别为5、10、20μmol／L），来探讨铅镉对肾细胞的作用及可能机制。在显微镜下观察细胞形态、测定细胞凋亡率和细胞周期及上清液脂质过氧化指标。结果表明：20μmol／L以上染毒组细胞皱缩、体积变小，表面有细胞碎片，甚至呈泡沫状或树枝状；铅、镉单独和联合染毒组GSH—Px、SOD活性随染毒剂量的增加，呈逐渐下降趋势（P〈0．05）．而MDA含量和凋亡率则呈升高趋势（P〈0．05），并存在剂量和时间效应。镉和铅也能使细胞周期停滞。Pb、Cd联合可加剧细胞损伤。     

肉鸭常见维生素营养代谢病研究进展

维生素是维持肉鸭正常代谢及保持高的生产性能所必需的一类营养物质。在肉鸭养殖过程中,维生素的缺乏或过量都会造成机体产生营养代谢病。文章就肉鸭养殖过程中常见的维生素营养代谢病进行分析,并提出相应的防治措施,从而保障肉鸭的健康养殖。     

热处理对低温胁迫下黄瓜活性氧代谢和膜脂组分的影响

为探讨热处理减轻黄瓜果实低温冷害的作用机理,本试验研究了47℃热水浸泡5 min处理对黄瓜果实在4℃贮藏期间活性氧代谢和膜脂组分的影响。结果表明,47℃热水5 min处理可显著抑制黄瓜果实冷害的发生,贮藏15 d后果实冷害指数较对照(CK)低20.87%。此外,热处理还可抑制黄瓜相对电导率及丙二醛(MDA)含量的上升,提高黄瓜果实超氧化物歧化酶(SOD)、过氧化物酶(DOD)、过氧化氢酶(CAT)和抗坏血酸过氧化物酶(APX)的活性,抑制超氧阴离子($\mathop{{O}}_{2}^{{\mathop{}_{\ ·}^{-}}}$)及过氧化氢(H₂O₂)的产生,同时降低脂氧合酶的活性,保持较低的饱和脂肪酸含量、较高的不饱和脂肪酸含量和膜脂不饱和度。综上,热处理可维持黄瓜果实活性氧代谢的平衡,抑制膜脂的过氧化作用,从而提高黄瓜果实的抗冷性,减轻果实冷害损伤。