樟芝固态发酵产物抗氧化性分析

本文对樟芝谷物固态发酵产物抗氧化性能及活性成分进行了研究.在所选谷物中,樟芝青稞固态发酵产物的乙醇提取物总抗氧化性最好,较未发酵青稞提高了4.02倍.通过无水乙醇50℃水浴振荡提取80 min,其总抗氧化性达到了769.60 U/g.对其抗氧化性能分析发现,樟芝青稞固态发酵乙醇提取物为6 mg/L时,对DP P H自由基、羟基自由基以及超氧阴离子的去除率分别为91.9%、51.2%、61.3%,对铁离子的螯合能力为79.5%.相对于未发酵谷物,大米、小米、玉米以及青稞的樟芝发酵产物中总酚含量均有显著的提升,其中青稞乙醇提取和水提取物中总酚含量分别提高了2.36倍和4.23倍.通过HP LC分析可知,樟芝固态发酵产物含有丰富的活性化合物,包括马来酸衍生物(Antrodin)以及泛醌类衍生物(Antroquinonol),且各组分含量较为均衡;而樟芝液态发酵菌丝体乙醇提取物中主要活性成分为马来酸衍生物,不含有泛醌类化合物.     

灰树花孔菌固体发酵基质抗氧化活性成分研究

选用燕麦、大豆、玉米、麸皮、大米、荞麦6种培养基质对灰树花孔菌进行固体发酵及抗氧化活性研究。结果表明：灰树花孔菌最佳抗氧化发酵基质为燕麦大豆培养基（燕麦16.25%,大豆83.75%）,最佳发酵时间为8d。灰树花孔菌燕麦大豆发酵基质抗氧化活性成分种类丰富,含量高。其中总黄酮物质40.86μg/g,总三萜5.94mg/g,多酚8.51mg/g,还原糖13.10mg/g,花色苷70.23μg/g,维生素C 24.57mg/g,维生素E 0.33mg/g,谷光甘肽（GSH）0.84g/g,SOD酶活性299.74U/g。     

响应面法优化芦荟中抗氧化活性成分的提取工艺

对芦荟中抗氧化活性物质提取工艺及其成分进行研究,通过单因素实验和响应面优化,以提取物对DPPH自由基的清除率为抗氧化的考察指标,得到芦荟中抗氧化活性成分的提取工艺条件:提取温度29 ℃、料液比(g/mL)1:33、提取时间107 s、微波功率500 W,微波辅助水提,此条件下得到的提取物对DPPH自由基的清除率达91.414%.提取物活性成分分析表明:提取物中芦荟甙含量为1.5 mg/g、黄酮为1.13 mg/g、多酚为4.33 mg/g、多糖为126.36 mg/g.     

灵芝-银杏双向液体发酵条件优化及抗氧化的研究

本研究采用双向液体发酵技术,以灵芝作为出发菌株,银杏叶为药性基质,以发酵产物的抗氧化活性为检测指标,通过单因素及正交实验,对双向发酵条件进行了优化,并进一步对发酵后的活性物质进行了检测。结果表明,灵芝‐银杏双向液体发酵的最佳条件为:银杏叶接种量为0.15g/100m L、初始p H 8.0、发酵时间9d、添加银杏叶的发酵时间为第2天,在此基础上,菌株的还原力达到0.731;活性物质多糖含量为245.20mg/g,三萜含量为70.96mg/g,总黄酮质含量为10.98mg/g,分别是对照的2.38倍、1.96倍和2.10倍。     

草菇子实体多肽提取工艺及其抗氧化活性

为了优化草菇子实体多肽的提取工艺和探究其抗氧化活性,以草菇子实体为原料,采用酶解法提取草菇子实体多肽,通过单因素试验得出最佳的酶解工艺,并使用Box-Behnken设计试验组合。结果表明：草菇子实体提取多肽的最佳工艺为料液比1:52 (g/mL)、加酶量7 200 U/g、酶解温度43 ℃,此工艺条件下的多肽得率为67.76%。从1,1-二苯基-2-三硝基苯肼(DPPH)自由基清除能力、铁离子还原能力、超氧阴离子自由基清除能力和羟自由基清除能力4个方面研究其体外抗氧化能力,结果表明,草菇子实体多肽对DPPH自由基清除率为74.11%,超氧阴离子自由基和羟自由基清除率分别在69.64%和91.83%达到稳定,草菇子实体多肽还具有一定的还原力,说明草菇子实体多肽可以作为优质抗氧化肽的良好来源。该研究为草菇多肽的高效制备和抗氧化肽等高附加值产品的研发提供理论依据。     

核桃内生真菌抗氧化菌株的筛选及其代谢产物活性研究

本试验以29株核桃内生真菌为研究对象,采用总还原力(FRAP法)及DPPH·清除试验评价其代谢产物的抗氧化能力,从中筛选出高活性菌株,并对该菌株发酵液进行浓缩萃取,研究各萃取物的抗氧化活性。结果表明,供试29株菌的代谢产物都表现出一定的抗氧化活性,其中菌株LTS-6-6(Pyrenochaeta)为高活性菌株。该菌株发酵液乙酸乙酯萃取物(EAE)显示了较强的抗氧化活性,对DPPH·的EC₅₀为7μg/mL,总还原力为527.59±10.66 mg V_C/g,总酚和总黄酮含量分别达到641.14±7.50 mg没食子酸/g、100.30±8.44 mg芦丁/g。该结果表明,核桃内生真菌代谢产物具有一定的抗氧化活性,是寻找天然抗氧化活性物质的良好资源。     

光照和pH对药用真菌二型附毛孔菌液体培养过程中抗氧化活性的影响

本文以多酚含量、总抗氧化能力(total antioxidant capacity,T-AOC)、1,1-二苯基-2-三硝基苯肼(1,1-diphenyl-2-picrylhydrazyl,DPPH)自由基清除能力和超氧化物歧化酶(superoxide dismutase,SOD)活性为测定指标,研究了不同光照和pH条件对药用真菌二型附毛孔菌Trichaptum biforme液体培养过程中抗氧化活性的影响。结果显示,二型附毛孔菌在液体培养过程中具有抗氧化活性。一定的光照可提高其分泌次级代谢产物的能力及抗氧化活性,14d光照条件下,多酚含量和T-AOC分别在第12天和第10天达到峰值,为1.85mg/m L和3.99U/m L;1d黑暗、1d光照交替的光照条件下,DPPH自由基清除率和SOD活性均于第2天达到最大值,分别为87.44%和0.63U/m L。不同pH条件对二型附毛孔菌液体培养过程中的抗氧化活性影响更大。当pH为9.0时,二型附毛孔菌在液体培养过程中分泌的多酚含量、T-AOC、SOD活性和DPPH自由基清除能力均最高,分别于第2天、第10天、第2天和第2天达到2.92mg/m L、5.22U/m L、0.70U/m L和95.07%。其次是pH 3.0,最后是pH 5.0和7.0,说明偏碱或偏酸条件更能刺激药用真菌二型附毛孔菌通过分泌大量次级代谢产物以抵抗来自微环境的氧化压力。     

混菌发酵芝麻粕制备芝麻多肽及其体外抗氧化活性研究

活性氧自由基(ROS)是细胞有氧代谢过程中产生的一类活性物,利用食源蛋白制备具有抗氧化能力的天然活性肽是当前的研究热点。本研究以机械冷榨芝麻粕为原料,比较了解淀粉芽孢杆菌、植物乳杆菌单菌及其混菌发酵芝麻粕制备芝麻多肽的过程,以DPPH·与·OH清除能力为评价指标,研究其体外抗氧化活性。数据表明,解淀粉芽孢杆菌、植物乳杆菌单菌及其混菌发酵芝麻粕36 h,芝麻多肽提取液中芝麻多肽的浓度分别达到9.841 mg/m L、11.620 mg/m L、14.412 mg/m L,DPPH·清除率分别是71.378%、77.013%、87.622%,·OH清除率分别是68.427%、82.507%、92.460%。因此,芝麻多肽具有较强的抗氧化活性,芝麻粕是制备抗氧化活性肽的良好原料;微生物发酵制备芝麻多肽时,解淀粉芽孢杆菌与植物乳杆菌混菌发酵显著优于单菌发酵,其多肽产量及DPPH·与·OH清除能力均优于相应单菌发酵。     

油酸促进灵芝三萜液态深层发酵的工艺研究及规模化验证

灵芝三萜是灵芝中主要的活性成分之一,前期研究发现油酸可以促进灵芝三萜液态深层发酵下的发酵合成。本研究主要对油酸促进灵芝三萜液态深层发酵的工艺进行优化,并进行3L发酵罐规模的验证。通过单因素实验考察油酸的添加方式、添加时间和添加浓度对灵芝三萜的影响,结合响应面实验,获得最优工艺条件并进行验证：在发酵第32h添加1.21%高温灭菌油酸,最高灵芝三萜含量为42.69mg/g;在发酵第7h添加1.35%过滤除菌油酸,最高三萜含量为43.38mg/g,分别比对照提高2.04倍和2.08倍。在1 000mL摇瓶中添加高温灭菌油酸和过滤除菌油酸,灵芝三萜含量分别为32.18和32.48mg/g,为对照的1.96倍和1.95倍;在3L发酵罐规模下灵芝三萜含量分别为28.66和25.13mg/g,为对照的1.62倍和1.42倍。本研究系统优化了油酸促进灵芝三萜液态深层发酵的工艺条件,并在与工业生产相对应的3L发酵罐上进行验证。该研究可为灵芝三萜的规模化发酵提供重要参考和借鉴。     

鸡油菌生物转化虾加工废弃物生产抗氧化胞外多糖的研究（英文）

利用响应面法研究了鸡油菌转化虾加工废弃物脱腥和抗氧化多糖的生产。生产菌丝体和胞外多糖的最优发酵条件为料液比9.016%,装液量120.292 m L,冰醋酸含量1.208%,验证实验结果表明该条件下菌丝体产量为28.407±0.842 g/L,多糖产量为7.009±0.517 g/L,分别较优化前提高了60.564%和114.737%,而且与回归方程预测值接近(RSD5%)。优化前去腥效果得分为3.056±0.115,优化后验证试验中得分为3.694±0.076。优化条件下获得的胞外多糖的总抗氧化能力为1.952±0.041 U/mg,抗超氧阴离子能力为93.223±1.174 U/g,抗羟自由基能力为60.291±0.638 U/mg。研究结果为利用鸡油菌转化虾加工废弃物生产抗氧化多糖提供了参考。     

大豆蛋白复合酶解产物在促微生物生长和发酵中的初步应用研究

为探讨大豆蛋白复合酶解产物在促微生物生长和发酵中的可行性,利用2709碱性蛋白酶和中性纤维素酶复合酶解大豆蛋白,酶解产物经干燥、粉碎后添加到培养基中,通过接种微生物观察其生长状况和发酵情况表征效果。研究发现,大豆蛋白复合酶解产物可以促进微生物生长和发酵产酶,试验结论为微生物培养提供了新的代谢资源。     

镉(Cd)与UV-B复合胁迫影响大豆胚轴生长的生理调节机制研究

通过研究大豆胚轴生长及内源吲哚乙酸(IAA)、赤霉素(GAs)、过氧化物酶(POD)和吲哚乙酸氧化酶(IAA oxidase)活性变化对Cd、UV-B辐射和Cd UV-B(复合胁迫)的响应。分析了激素水平、酶活性变化以及胚轴生长变化特性。结果表明,UV—B辐射引起大豆上胚轴伸长减小;但Cd对上胚轴伸长无明显影响;Cd UV—B使上胚轴长度比UV—B作用时明显增加。UVB辐射显著降低了胚轴IAA含量;而GAs含量却显著升高;Cd胁迫下IAA和GAs变化并不明显;但Cd UV—B使IAA含量显著升高,而对GAs无明显影响。UVB辐射使IAA氧化酶和POD活性显著增强,而Cd对这两种酶活性影响并不明显;但Cd UV—B复合胁迫下胚轴的IAA水平较高。尽管UVB辐射引起胚轴中GAs含量显著增加,但研究结果显示IAA含量变化是胁迫下引起胚轴生长改变的更直接原因。研究还表明Cd UV—B时,大大削弱了UV—B辐射下IAA氧化酶活性增强,加之Cd对POD活性的抑制,导致复合胁迫下胚轴的IAA水平较高。证明复合胁迫可以改变单一胁迫下植物激素的调控机制。     

用gfp基因标记法研究大豆根瘤菌在大豆根部定殖结瘤情况

采用三亲本杂交的方法,将绿色荧光蛋白基因(gfp)转入高效、抗逆、广适应性的快生大豆根瘤菌Sinorhizobium frediiCCBAU 01287中,获得含gfp基因的转基因菌株CBAU 01287(G);平板传代和共生检测表明:外源质粒在CCBAU 01287中能够自我复制,稳定遗传。进一步研究表明,gfp标记菌CCBAU 01287(G)可用于实时监测根瘤菌在大豆根部的早期定殖情况和定殖密度的测定;标记菌株对大豆的生长及生物量的积累与出发菌株的效果无显著差异。     

Identification of QTLs Underlying Water-Logging Tolerance in Soybean

Soil water-logging can cause severe damage to soybean [Glycine max (L.) Merr.] and results in significant yield reduction. The objective of this study was to identify quantitative trait loci (QTL) that condition water-logging tolerance (WLT) in soybean. Two populations with 103 and 67 F_6:11 recombinant inbred lines (RILs) from A5403 × Archer (Population 1) and P9641 × Archer (Population 2), respectively, were used as the mapping populations. The populations were evaluated for WLT in manually flooded fields in 2001, 2002, and 2003. Significant variation was observed for WLT among the lines in the two populations. No transgressive tolerant segregants were observed in either population. Broad-sense heritability of WLT for populations 1 and 2 were 0.59 and 0.43, respectively. The tolerant and sensitive RILs from each population were selected to create a tolerant bulk and a sensitive bulk, respectively. The two bulks and the parents of each population were tested with 912 simple sequence repeat (SSR) markers to select candidate regions on the linkage map that were associated with WLT. Markers from the candidate regions were used to genotype the RILs in both populations. Both single marker analysis (SMA) and composite interval mapping (CIM) were used to identify QTL for WLT. Seventeen markers in Population 1 and 15 markers in Population 2 were significantly (p <0.0001) associated with WLT in SMA. Many of these markers were linked to Rps genes or QTL conferring resistance to Phytophthora sojae Kaufmann and Gerdemann. Five markers, Satt599 on linkage group (LG) A1, Satt160, Satt269, and Satt252 on LG F, and Satt485 on LG N, were significant (p <0.0001) for WLT in both populations. With CIM, a WLT QTL was found close to the marker Satt385 on LG A1 in Population 1 in 2003. This QTL explained 10% of the phenotypic variation and the allele that increased WLT came from Archer. In Population 2 in 2002, a WLT QTL was located near the marker Satt269 on LG F. This QTL explained 16% of the phenotypic variation and the allele that increased WLT also came from Archer.     

Isolation of Human Renin Inhibitor from Soybean: Soyasaponin I Is the Novel Human Renin Inhibitor in Soybean

We found human renin inhibitory activity in soybean and isolated the active compound, soybean renin inhibitor (SRI). The physico-chemical data on the isolated SRI were identical with those of soyasaponin I. SRI showed significant inhibition against recombinant human renin, with an IC₅₀ value of 30 μg/ml. Kinetic studies with SRI indicated partial noncompetitive inhibition, with a K_i value of 37.5 μM. On the other hand, SRI weakly inhibited pepsin, papain, and bromeline activities, but did not inhibit other proteinases, such as trypsin, kallikrein, angiotensin converting enzyme, and aminopeptidase M. Moreover, a significant (p<0.05) decrease in the systolic blood pressure of spontaneously hypertensive rats was observed when partially purified SRI was orally administrated at 40 mg/kg/d for 7 weeks. This is the first demonstration of a renin inhibitor from soybean, soyasaponin I.     

大豆成熟种子萌发叶片体细胞胚的高频诱导和遗传转化（英文）

目的 虽然大豆遗传转化取得了较大进展,但其转化效率仍然偏低。因此,有必要建立一个更加简单和高效的大豆转化系统。本研究的目的是以大豆成熟种子萌发产生的叶片（MSDL）为靶外植体,高频诱导和转化大豆体细胞胚（somatic embryos,SEs）。方法 萌发7 d的大豆幼苗上摘取叶片,并将其切成1.2 cm×1.2 cm的外植体。将叶片外植体置于胚胎诱导培养基（EIM）上诱导体细胞胚发生。将叶片外植体浸入携带p CAMBIA1301植物表达载体的农杆菌EHA105菌液进行遗传转化。结果 MSDL （包括初生叶和次生叶）均能被诱导产生SEs。大多数SE发生在叶片切口处。所试的不同基因型均能诱导SEs。SEs的最高诱导率为95.0%。β葡糖醛酸糖苷酶（GUS）染色结果表明,平均转化效率达到75.4%。DNA印迹（Southern blot）结果表明,目的基因稳定整合在大豆基因组中,拷贝数为1～3个。结论 本研究建立了以大豆MSDL为靶组织的体细胞胚高频诱导和遗传转化。该系统有望在大豆基因组编辑技术的开发上得到应用。     

Effect of chitin hexamer and thuricin 17 on lignification-related and antioxidative enzymes in Soybean Plants

Inducers of disease resistance in crop plants have a role in sustainable agriculture. We describe a set of bacteriocins that can potentially improve plant growth by controlling specific pathogens and inducing generalized resistance. Solutions of the bacteriocin thuricin 17 and/or a chitin hexamer (a known inducer and positive control) were applied to leaves of two-week-old soybean plants, and levels of lignification-related and antioxidative enzymes were monitored. Phenyl ammonia lyase (PAL) activity in thuricin 17-treated leaves was highest at 60 h after treatment, being 61.8% greater than the control. PAL activity also was increased 18.1% at 72 h after treatment with the chitin hexamer. Tyrosine ammonia lyase (TAL) activity in leaves was 57.0% higher than the control at 48 h after treatment with thuricin 17, while such activity in chitin hexamer-treated leaves was increased by 23.8% at 72 h. At 36 h after treatment with the chitin hexamer or chitin hexamer + thuricin 17, the total concentration of phenolic compounds was 15.3 or 19.3%, respectively, greater than the control. At 72 h, total phenolic concentrations increased by 23.2 and 19%, respectively, in response to thuricin 17 and chitin hexamer + thuricin 17. POD activity in thuricin 17-treated leaves increased by 74.6 and 81.2% at 48 and 72 h, respectively, whereas SOD activity increased by 24.9 and 79.9%, respectively, in chitin hexamer- and thuricin 17-treated leaves at 48 h. A peroxidase isozyme (31 kDa isomer) was induced in thuricin 17-treated leaves at 60 h, while catalase (59 kDa isomer) was induced in chitin hexamer-treated leaves. PAGE showed that two major SOD bands (Fe-SODs) were produced by both types of treatment. Collectively, these results indicate that the bacteriocin thuricin 17 can act as an inducer of plant disease defenses (i.e., activated lignification-related enzymes, antioxidative enzymes, and related isozymes) and that this induction is similar, but not identical, to that of the chitin hexamer elicitor. Although treatment with thuricin 17 + chitin hexamer also induced those responses, it did not present a clear pattern of additivity or synergy.     

Phosphorus and Nitrogen Interactions in Field-Grown Soybean as Related to Genetic Attributes of Root Morphological and Nodular Traits

Two field experiments with different soybean (Glycine max L.) materials were conducted to investigate the interactions between phosphorus (P) and nitrogen (N) as related to the genetic attributes of root morphological and nodular traits. In experiment one, 13 cultivated soybean varieties were grown in a field with relatively low soil P and N availability. P application with 160 kg P/hm2 as triple superphosphate produced a significant simultaneous increase in the content of both P and N in shoot, demonstrating positive P and N interactions. The addition of P also increased root dry weight, root nodule number, nodule mass, nodule size, and nodulation index, but decreased root length and root surface area, indicating that P may affect N nutrition in soybean through a number of root morphological and nodular traits. Interestingly,like P content, N content appeared to be more correlated with root morphological traits (root weight, root length, and root surface area) than with root nodular traits (nodule number, nodule size, nodule mass, and nodulation index) at both P levels, implying that N taken up by the roots may contribute more to the plant N status than biological N2 fixation under the present experimental conditions. In experiment two, 57 soybean lines of a recombinant inbred line (RIL) population derived from a cross between a cultivated variety and a wild genotype were grown on another field site with moderately sufficient P and N levels to further characterize the genetic attributes of root morphological and nodular traits and their relationships with P and N interactions. The results indicated that all morphological and nodular traits measured continually segregated in the RIL population with a normal distribution of the phenotypic values, indicating that these traits are possibly controlled by quantitative trait loci (QTLs). Genetic analysis revealed that all these root traits had relatively low heritabilities (h2b=74.12, 70.65, 73.76, 56.34, 52.59, and 52.24 for root weight, root length,root surface area, nodule number, nodule mass, and nodule size, respectively), suggesting that root morphology and nodule formation are influenced greatly by environmental factors. Correlation analysis of the RILs showed that shoot N content was significantly correlated with P content, confirming positive P×N interactions. Similar to experiment one, shoot N content was only significantly correlated with root morpho logical traits, but not with root nodular traits, again denoting the fact that the N status in soybean could be attributed more to N uptake from the soil than to biological N2 fixation under the present experimental conditions.     

大豆异黄酮合酶基因的克隆及序列分析

目的:大豆异黄酮是多酚类混合物,有防治肿瘤发生,提高机体免疫力等多种保健功能。异黄酮合酶(isoflavone synthase,IFS)是合成异黄酮的关键酶。本文为了利用异黄酮的特有生物学功能,从大豆中克隆了该基因。方法:采用PCR扩增从大豆[Glycine max(Linn.)Merr.]总RNA中分离了异黄酮合酶基因,并将其克隆到pUCm-T载体并测序。结果:得到全长1583bp的片段。以期用于构建诱导表达基因敲除系统,并用于无性繁殖植物的无标记基因转化。结论:序列分析表明,异黄酮合酶基因(IFS1)含1583个核苷酸,与已报道的序列比较,核苷酸的同源性为92%。     

Investigation on Emission of Nitrous Oxide by Aseptic Soybean Plant

The emission of nitrous oxide is not only a way of nitrogen loss in ecological system of agriculture, it is also a contamination source of increasing nitrogen oxide concentration in the atmosphere. This paper reports the analysis of gas chromatographic determination of N2O on the soybean plant and its different four organs-root, stem, leaf and cotyledon under strict aseptic condition. The results showed ,hat they all are able to emit nitrous oxide.