表达广谱抗真菌蛋白转基因水稻秸秆的化学成分与纤维素结构

为了给表达广谱抗真菌蛋白转基因水稻的安全性评估提供基础数据,本文以表达广谱抗真菌蛋白转基因水稻转品1和转品8及非转基因七丝软粘（对照）为试材,对其秸秆化学成分进行分析,同时,采用傅立叶变换红外光谱（FTIR）和X 射线衍射（XRD）方法观察秸秆中不同部位纤维素结构的变化情况。研究结果显示：（1）转基因水稻转品1和转品8与对照在秸秆相同部位的化学成分含量不存在显著差异;（2）转基因水稻转品1和转品8及对照在秸秆相同部位纤维素的红外吸收峰形状基本一致,且品种间的吸收峰强度和结晶指数(O′KI和N〖KG-*2〗·〖KG-*4〗O′KI)也无显著差异;（3）转品1和转品8秸秆的X 射线衍射图与对照相似,且结晶度(CrI)与对照无显著差异。综上所述,广谱抗真菌基因的导入不会对水稻的化学成分、纤维素结构及晶体结构产生明显影响。     

广谱抗真菌转基因水稻植株化学成分与结构动态变化

【背景】种植广谱抗真菌水稻可能会带来一定的环境生物安全问题,对其植株的化学成分进行实质等同性分析是转基因水稻安全性评价的重要内容之一。【方法】以表达广谱抗真菌蛋白转基因水稻转品1和转品8及其相应非转基因水稻七丝软粘的秸秆为研究材料,采用化学法和扫描电镜技术分析外源基因的导入对水稻秸秆化学成分以及组织显微结构的影响。【结果】（1）在整个生长发育过程中,广谱抗真菌转基因水稻转品1和转品8与其非转基因水稻七丝软粘叶片、叶鞘和茎的纤维素、半纤维素、木质素以及粗蛋白含量的变化趋势基本一致,且品种间化学成分的含量不存在显著差异。（2）广谱抗真菌转基因水稻叶片表皮的硅质瘤状结构以及气孔的形状和致密程度与其非转基因水稻七丝软粘相似;茎壁、厚壁组织、薄壁组织以及大小维管束的形态和分布情况未发生明显变化。【结论与意义】表达广谱抗真菌蛋白转基因水稻秸秆的化学成分和组织显微结构与非转基因水稻基本一致。这为广谱抗真菌转基因水稻的环境安全性评估提供了依据。     

广谱抗真菌转基因水稻植株化学成分与结构动态变化

【背景】种植广谱抗真菌水稻可能会带来一定的环境生物安全问题,对其植株的化学成分进行实质等同性分析是转基因水稻安全性评价的重要内容之一。【方法】以表达广谱抗真菌蛋白转基因水稻转品1和转品8及其相应非转基因水稻七丝软粘的秸秆为研究材料,采用化学法和扫描电镜技术分析外源基因的导入对水稻秸秆化学成分以及组织显微结构的影响。【结果】（1）在整个生长发育过程中,广谱抗真菌转基因水稻转品1和转品8与其非转基因水稻七丝软粘叶片、叶鞘和茎的纤维素、半纤维素、木质素以及粗蛋白含量的变化趋势基本一致,且品种间化学成分的含量不存在显著差异。（2）广谱抗真菌转基因水稻叶片表皮的硅质瘤状结构以及气孔的形状和致密程度与其非转基因水稻七丝软粘相似;茎壁、厚壁组织、薄壁组织以及大小维管束的形态和分布情况未发生明显变化。【结论与意义】表达广谱抗真菌蛋白转基因水稻秸秆的化学成分和组织显微结构与非转基因水稻基本一致。这为广谱抗真菌转基因水稻的环境安全性评估提供了依据。     

转Bt基因水稻秸秆降解对土壤微生物可培养类群的影响

以高抗螟虫、已释放应用的 Bt水稻 (克螟稻 1号 )及其亲本 (非 Bt水稻 )为材料 ,在实验室条件下研究了转 Bt基因水稻及其亲本秸秆在降解过程中对土壤微生物主要类群的影响 ,这些类群包括细菌、真菌、放线菌、反硝化细菌、解磷微生物。结果表明 :(1)降解过程中 Bt蛋白浓度在前两周内迅速下降 ,随后降解速度变慢 ,17d以后至 5 3d,Bt蛋白浓度基本上保持在 6 .72 8～6 .196 ng/ g的水平。 (2 )秸秆降解过程中 ,不同处理细菌数量的变化趋势相似 ,转基因水稻与其亲本之间差异显著 ,非转基因细菌数量高于转基因细菌数量。(3)除降解初期第 3天、第 6天之外 ,其他取样时期的转基因水稻真菌数量要显著高于非转基因和对照。(4)放线菌数量没有明显变化规律 ,除第 6、9、2 6、35天外 ,非转基因数量显著高于转基因。(5 )非转基因秸秆降解反硝化细菌活性高于转基因 ,而解磷微生物活性处理之间无明显差异。     

抗真菌转基因水稻秸秆降解对土壤细菌数量及多样性的影响

【背景】随着转基因作物的大面积种植,其潜在的环境安全性问题备受关注。转基因作物收获后,大部分残留物会重返土壤,可能对土壤微生物造成影响。【方法】通过室内模拟田间秸秆降解试验,采用平板计数法、表面荧光显微镜直接计数法（FDC）以及变性梯度凝胶电泳（DGGE）技术,分析了抗真菌转基因水稻秸秆降解对土壤细菌数量及多样性的影响。【结果】平板计数表明,在整个降解过程中,转基因与非转基因处理土壤可培养细菌数量的变化趋势有所差别,但差异不显著。FDC结果表明,转基因与非转基因处理土壤细菌总数差异不显著。DGGE指纹图谱显示,转基因与非转基因处理土壤样品之间的多样性指数、均匀度和丰富度均无显著差异。【结论与意义】抗真菌转基因水稻秸秆降解并未对土壤细菌数量和多样性产生显著影响。本研究为抗真菌转基因水稻的环境安全性评估提供了依据。     

Bt玉米秸秆还田对小麦幼苗生长发育的影响

以已进入中间试验阶段的Bt玉米及其亲本(非Bt玉米)秸秆为材料,与营养土及蛭石混合后培养小麦幼苗,同时以未使用秸秆的相应土为空白对照,在室内条件下研究了Bt玉米与亲本秸秆还田对后茬小麦的影响。结果表明:(1)不同秸秆还田对小麦幼苗出苗率、株高没有显著影响;(2)非转基因玉米与转Bt玉米秸秆拌土后地上部鲜重仅为对照鲜重的51%和65%,干重仅为对照的62%和72%,均达到差异显著水平;(3)Bt玉米秸秆还田降低小麦幼苗生长素(IAA)含量,郑58秸秆拌土增加了幼苗脱落酸(ABA)含量;(4)两种处理均提高了幼苗的超氧化物歧化酶(SOD)总活性。因此,秸秆拌土对小麦幼苗的处理效应一致,与秸秆类型无关,该研究可为评价转Bt玉米环境安全提供一定的理论依据。     

不同品种水稻秸秆的理化特性及酶解产糖的研究

本研究以不同品种水稻秸秆为原料,测定分析了三大主要组分纤维素、半纤维素和木质素含量及理化特性的差异,并分析对比了经碱预处理后酶解及直接酶解的产糖率差异。利用X-射线衍射仪测定分析了结晶度和晶粒尺寸的异同,红外光谱仪定性评估了特定基团的差异,扫描电镜观察分析了表面形态结构的差异。综合考虑理化特性和酶解产糖率结果,与a(常规水稻黄华占)相比,5种不同品种的超级杂交水稻秸秆中,b(杂交水稻Y两优1)、c(杂交水稻隆两优2010)和f(杂交水稻Y两优143)三个品种的秸秆材料比较适合作为酶解产糖的原材料。     

广西兴安转Bt水稻大田两迁害虫发生动态

以转Bt水稻华恢1号(Cry1Ac/ CryAb融合基因型,简称HH1)及其对照亲本明恢63(简称MH63)稻田两迁害虫稻纵卷叶螟和白背飞虱为研究对象,系统研究转基因抗虫水稻种植下两迁害虫的发生规律及其致害力差异.结果表明:转Bt水稻及其对照亲本上稻纵卷叶螟的落卵量和幼虫发生量无显著差异,但转Bt水稻的卷叶株率和卷叶率都显著低于对照亲本.表明转Bt水稻对靶标害虫稻纵卷叶螟具有较高抗性.转Bt水稻及对照亲本上白背飞虱若虫、成虫及整个种群的发生动态差异不显著,且转Bt水稻对长翅型和短翅型成虫的种群发生影响也不显著.白背飞虱发生高峰期,转Bt水稻上若虫及短翅型成虫发生量均明显高于对照亲本;相反,转Bt水稻上长翅型成虫发生量明显低于对照亲本,且水稻生育后期长翅型成虫雌性比明显低于对照亲本.转Bt水稻大面积商业化种植下其非靶标害虫白背飞虱的发生危害变得更为复杂.     

Cry1Ab蛋白对稻纵卷叶螟幼虫体内三种保护酶活性的影响

室内采用酶活力测定方法研究转B t基因水稻表达的Cry1Ab蛋白对稻纵卷叶螟幼虫体内3种保护酶(AChE、SOD和CAT)活性的影响。结果表明,用转B t基因水稻处理稻纵卷叶螟幼虫,饲喂4 h、36 h后,其体内AChE活力分别比对照增加了52.09%、128.51%,并且都极显著(P<0.01)高于对照组;取食转基因水稻叶片4 h后,幼虫体内SOD酶活性比对照提高了91.5%,与对照有显著差异;36 h后活性达到最大值,但与对照差异不显著。取食转基因水稻叶片24 h后,幼虫体内CAT酶活性达到最大值且高于对照,但与对照差异不显著;48 h后酶活性受到显著抑制,与对照差异显著。同时,测定了幼虫体内及其粪便中Cry1Ab蛋白含量的变化,结果表明,取食转基因水稻叶片12 h后,进入体内的Cry1Ab蛋白随粪便排出,幼虫体内的Cry1Ab蛋白含量一直低于粪便中的含量,且在24 h时两者差异达到最大。由于Cry1Ab蛋白在幼虫体内的积累,扰乱了稻纵卷叶螟幼虫体内AChE、SOD和C AT保护酶的动态平衡,使虫体内自由基的清除遇到障碍,从而对其产生毒害作用。     

抗真菌转基因水稻生态适合度评价

在田间自然条件下,通过两年两季单独种植(非竞争)和混合种植(竞争)试验,分析比较抗真菌转基因水稻E121-2-1和E122-2-9与其非转基因受体亲本E32和常规稻粤香占在农艺性状、繁殖能力、花粉活力、种子活力、种子库持久力和自生性等适合度成分上的差异,评价抗真菌转基因水稻的生态适合度。结果表明,在竞争情形下,E121-2-1和E122-2-9的株高、千粒重和每穗总粒数在两年均显著降低或在其中一年显著降低,E121-2-1和E122-2-9农艺性状的竞争能力总体上低于E32和粤香占。E121-2-1和E122-2-9的净替代率在竞争态势下两年均呈下降趋势,其中E121-2-1在其中一年下降显著,而E32和粤香占的净替代率随不同年份升高或下降,但变化不显著。E121-2-1和E122-2-9的花粉萌发率、种子发芽势两年均显著低于E32和粤香占,种子发芽率和田间自生苗率在其中一年显著低于E32和粤香占,种子库持久力与E32和粤香占相比两年均无显著差异。只有E121-2-1和E122-2-9种子的休眠期两年均显著高于对照E32和粤香占。结果说明转四价抗真菌基因水稻E121-2-1和E122-2-9的生态适合度优势不强,其种群在自然界中的生存竞争和延续能力不会超越非转基因水稻。     

Studies on untreated and urea-treated rice straw from three cultivation seasons: 2. Evaluation of straw quality through in vitro gas production and in sacco degradation measurements

Untreated and urea-treated straw and straw fractions of seven rice varieties from three cultivation seasons have been evaluated on their DM, OM loss and degradation characteristics from in sacco disappearance and in vitro gas production measurements. Drying temperatures from 45°C to 100°C did not seem to influence the degradability of urea-treated rice straw, whereas urea-treated straw dried at freezing temperatures (−35°C) gave slightly higher degradability than higher temperatures. Untreated early season rice straw showed higher degradability than straw of middle and later season rice. There was a significant increase in the degradation of straw after urea treatment, and greatest for late and middle season rice straw. On average, urea-treatment of rice straw increased the DM and OM in sacco losses after 48 h of incubation (48 h) by 24.0% and 30.7%, respectively. In order to study the kinetics of the degradation of fibre fractions, the disappearance in sacco was also estimated for the loss of hemicellulose, cellulose and extractable biogenic silica (EBSi). There was a great variation in the content of silica between varieties. Rice straw degradation seemed to be related to the biogenic silica content (acid detergent insoluble silica (ADISi)). Urea treatment increased the extraction of biogenic silica and hence increased the degradation of hemicellulose and cellulose. The improvement in sacco disappearance of cellulose due to urea treatment was 36.8%, 19.5% and 5.3% for late, middle, and early rice straw, respectively. The degradability was higher for the stem than for the leaf blades and leaf sheaths. The response to urea treatment, however, was higher for leaf sheaths and leaf blades than for the stems, evening out differences in degradability. Urea treatment tended to increase the production of acetic acid whereas there was no effect on propionic and butyric acid production.     

Enhanced cellulase production from Trichoderma reesei QM 9414 on physically treated wheat straw

Summary Trichoderma reesei QM 9414 was grown on wheat straw as the sole carbon source. The straw was pretreated by physical and chemical methods. The particle size of straw was less than 0.177 mm. Growth of T. reesei QM 9414 was maximal with alkali-pretreated straw whereas cellulase production was optimal when physically pretreated straw was used as substrate. Cellulase yields expressed as IU enzyme activity/g cellulose present in the cultures were considerably higher when alkali pretreatment of wheat straw was omitted. Cellulase yields of 666 IU/g cellulose for filter paper activity (FPA) are the highest described for cultures of T. reesei QM 9414 carried out in analogous conditions. Crystallinity index of the cellulose contained in wheat straw increased slightly after alkali pretreatment. This increase did not decrease cellulose accessibility to the fungus. Delignification of wheat straw was not necessary to achieve the best cellulase production.     

Degradation and utilization of cellulose and straw by three different anaerobic fungi from the ovine rumen

Three different ruminal fungi, a Neocallimastix sp. (strain LM-1), a Piromonas sp. (strain SM-1), and a Sphaeromonas sp. (strain NM-1), were grown anaerobically in liquid media which contained a suspension of either 1% (wt/vol) purified cellulose or finely milled wheat straw as the source of fermentable carbon. Fungal biomass was estimated by using cell wall chitin or cellular protein in cellulose cultures and chitin in straw cultures. Both strains LM-1 and SM-1 degraded cellulose with a concomitant increase in fungal biomass. Maximum growth of both fungi occurred after incubation for 4 days, and the final yield of protein was the same for both fungi. Cellulose degradation continued after growth ceased. Strain NM-1 failed to grow in the cellulose medium. All three anaerobic fungi grew in the straw-containing medium, and loss of dry weight from the cultures indicated degradation of straw to various degrees (LM-1 greater than SM-1 greater than NM-1). The total fiber component and the cellulose component of the straw were degraded in similar proportions, but the lignin component remained undegraded by any of the fungi. Maximum growth yield on straw occurred after 4 days for strain LM-1 and after 5 days for strains SM-1 and NM-1. The calculated yield of cellular protein for strain LM-1 was twice that of both strains SM-1 and NM-1. The cellular protein yield of strain SM-1 was the same in both cellulose and straw cultures. In contrast to cellulose, straw degradation ceased after the end of the growth phase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Degradation and utilization of cellulose and straw by three different anaerobic fungi from the ovine rumen.

Three different ruminal fungi, a Neocallimastix sp. (strain LM-1), a Piromonas sp. (strain SM-1), and a Sphaeromonas sp. (strain NM-1), were grown anaerobically in liquid media which contained a suspension of either 1% (wt/vol) purified cellulose or finely milled wheat straw as the source of fermentable carbon. Fungal biomass was estimated by using cell wall chitin or cellular protein in cellulose cultures and chitin in straw cultures. Both strains LM-1 and SM-1 degraded cellulose with a concomitant increase in fungal biomass. Maximum growth of both fungi occurred after incubation for 4 days, and the final yield of protein was the same for both fungi. Cellulose degradation continued after growth ceased. Strain NM-1 failed to grow in the cellulose medium. All three anaerobic fungi grew in the straw-containing medium, and loss of dry weight from the cultures indicated degradation of straw to various degrees (LM-1 greater than SM-1 greater than NM-1). The total fiber component and the cellulose component of the straw were degraded in similar proportions, but the lignin component remained undegraded by any of the fungi. Maximum growth yield on straw occurred after 4 days for strain LM-1 and after 5 days for strains SM-1 and NM-1. The calculated yield of cellular protein for strain LM-1 was twice that of both strains SM-1 and NM-1. The cellular protein yield of strain SM-1 was the same in both cellulose and straw cultures. In contrast to cellulose, straw degradation ceased after the end of the growth phase.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of PopCel1 and PopCel2 in poplar leaf growth and cellulose biosynthesis

Poplar calli transcribed two cellulase (endo-1,4-beta-glucanase) genes, PopCel1 and PopCel2, whose mRNAs were differentially located in the growing leaves of poplar during cell wall synthesis. Histochemical and RT-PCR analyses of promoter-GUS fusion gene activities in transgenic poplar demonstrated that PopCel1 promoter-derived GUS activity was localized in the petiole and leaf veins, whereas PopCel2 was confined to mesophyll cells and disappeared from the tip during the development of leaves. Autoradiography of the leaf showed that the radioactivity of [14C]sucrose incorporated into cellulose corresponded to the combination of the sucrose-induced tissue-specific patterns of PopCel1 and PopCel2. Interestingly, 2,6-dichlorobenzonitrile (DCB) not only inhibited the incorporation of the radioactivity into cellulose, but also repressed the induction of both cellulase genes. Suppression of cellulases by expression of PopCel1 antisense cDNA or co-suppression of PopCel1 mRNA by overexpression of PopCel1 sense cDNA reduced leaf growth. Therefore, we came to the conclusion that PopCel1 and PopCel2 probably function to promote leaf growth in poplar by the endohydrolysis of 1,4-beta-glucan.     

Cellulase production from the corn stover fraction based on the organ and tissue

In this study, the biodegradation of fractionated corn stover in solid-state fermentation by Trichoderma reesei YG3 was investigated. Fractions of miscellaneous cells (MC) and fasciculi (FC) tissue from leaf, shell or core were separated using the combined pretreatment method of carding classification after steam explosion. The highest enzyme activities including the filter paper activity, endoglucanase, exoglucanase and β-glucosidase activities, weight loss rate of dry material and biodegradation rate were all observed in the MC tissue fraction from the leaf, which was more nutritious, while lowest activity was observed in the FC tissue fraction from the shell. The maximum filter paper activity and weight loss rate of the dry material were 4.56 and 1.89 times the minimum and the cellulose and hemicellulose biodegradation rates were 51.22 and 39.38% versus 23.85 and 26.51%, respectively. These variances maybe attributed to the heterogeneity of the component in the fractions. A higher weight loss rate corresponded to higher enzymatic activities, whereas cellulose biodegradation was not proportional to cellulase activities. Hemicellulose biodegradation was much slower than cellulose degradation. Here, we demonstrated the importance of fractionation in component biodegradation and utilization of straw.     

Natural cellulose fibers from soybean straw

This paper reports the development of natural cellulose technical fibers from soybean straw with properties similar to the natural cellulose fibers in current use. About 220 million tons of soybean straw available in the world every year could complement the byproducts of other major food crops as inexpensive, abundant and annually renewable sources for natural cellulose fibers. Using the agricultural byproducts as sources for fibers could help to address the concerns on the future price and availability of both the natural and synthetic fibers in current use and also help to add value to the food crops. A simple alkaline extraction was used to obtain technical fibers from soybean straw and the composition, structure and properties of the fibers was studied. Technical fibers obtained from soybean straw have high cellulose content (85%) but low% crystallinity (47%). The technical fibers have breaking tenacity (2.7 g/den) and breaking elongation (3.9%) higher than those of fibers obtained from wheat straw and sorghum stalk and leaves but lower than that of cotton. Overall, the structure and properties of the technical fibers obtained from soybean straw indicates that the fibers could be suitable for use in textile, composite and other industrial applications.