一株广谱抑菌活性乳酸菌的筛选及特性研究

【目的】从贵州剑河采集的传统自然发酵豆酱中分离筛选具有广谱抑菌效果的乳酸菌,并进行肠道益生特性的研究。【方法】通过抑菌试验分离筛选得到菌株DJ-04,对其进行人工胃肠液耐受性、胆盐耐受性和渗透压耐受性的研究,并对其进行生理生化鉴定和16S r RNA鉴定。【结果】菌株DJ-04对大肠杆菌、沙门氏菌、金黄色葡萄球菌、志贺氏菌和铜绿假单胞菌的生长有很好的抑制作用;在p H值为2.5的人工胃液中处理3 h活菌数达到107 CFU/m L以上;在人工肠液中处理3 h活菌数达到108 CFU/m L以上,对人工胃肠液表现出良好的耐受性。能耐受一定浓度的牛胆盐,在质量浓度0.2 g/100 m L的牛胆盐环境中活菌数可达到107 CFU/m L;具有较高的渗透压耐受能力,在Na Cl质量浓度为10 g/100 m L的液体MRS中培养24 h后,活菌数仍在107 CFU/m L以上。经鉴定,DJ-04为植物乳杆菌。【结论】植物乳杆菌DJ-04具有良好的人工胃肠液耐受性以及耐胆盐和耐渗透压能力,具有肠道益生菌的潜能。     

3株罗伊氏乳杆菌生物学特性的分析比较

【目的】对3株罗伊氏乳杆菌的生物学特性进行分析比较,为后期生产应用提供一定的参考。【方法】对实验室保藏的3株罗伊氏乳杆菌的生长曲线、pH曲线、耐受人工胃液能力、耐受猪胆盐能力、黏附能力、抑菌能力和对抗生素的耐药性等特性进行了分析比较。【结果】3株菌生长趋势大致相同;3株菌对人工胃液均具有良好的耐受性,且可以有效地抑制大肠杆菌和金黄色葡萄球菌的生长;菌株L0和L2对高胆盐的环境耐受性较差,菌株L1则对高胆盐环境具有极强的耐受性;菌株L1和L2具有很强的黏附能力;3株菌对20种抗生素表现出不同的耐受性。【结论】菌株L1的生物学特性明显优于其他两株菌株,有利于后期的生产应用。     

模拟人体胃肠道环境筛选益生乳杆菌

【目的】筛选具有益生特性的乳杆菌作为保健型酸奶的候选菌株。【方法】从健康人肠道和奶豆腐中分离筛选出耐受人工胃液的乳杆菌,对其进行体外益生特性(人工胃肠液耐受性、胆盐耐受性、抑菌活性及胆固醇降解能力)研究。【结果】从在乳杆菌分离培养基上有溶钙圈的41株菌株中筛选出5株耐酸、耐人工胃液较强的菌株,经16S rR NA基因测序鉴定,其中3株为乳杆菌,分别命名为植物乳杆菌Lp MT-3、植物乳杆菌Lp MT-5和唾液乳杆菌LsA F-7。在人工胃液中3株菌的耐受力均强于商品化的对照菌株LGG(鼠李糖乳杆菌GG);转入肠液4 h后直至26 h,Lp MT-5存活率基本稳定在45%左右,仅次于LGG。胆盐浓度为0.10%时,3株乳杆菌的耐胆盐能力均强于LGG;胆盐浓度为0.20%时,Lp MT-3和LsA F-7仍能存活。3株乳杆菌均具有抑菌活性,对粪肠球菌的抑制最明显,其次是金黄色葡萄球菌,对大肠杆菌、沙门氏菌的抑制作用较差。3株乳杆菌对胆固醇的清除效力依次为Lp MT-3LpM T-5Ls AF-7;清除率依次为Ls AF-7Lp MT-3LpM T-5。【结论】筛选出3株适应人体胃肠液环境、耐胆盐、抑菌及降胆固醇活力强的乳杆菌,可作为进一步开发新的益生菌产品和保健型酸奶的菌株。     

多轮次胁迫驯化及多因子复合筛选丁醇高产菌

【目的】从陕西省石泉县玉米地土壤中分离获得一株产丁醇菌株并提高其丁醇耐受性和丁醇产量。【方法】采用自行设计的多因子复合筛选方法和丁醇胁迫驯化处理,在获得丁醇高产菌株的同时提高菌株的丁醇耐受性。【结果】野生菌株D64经多轮次丁醇胁迫驯化处理和多因子复合筛选,分离获得突变株T64,其丁醇耐受性明显提高,能在丁醇浓度为20 g/L的复合筛选培养基上正常生长,发酵7%玉米醪丁醇产量由13.35 g/L提高到15.18 g/L,总溶剂(丙酮、丁醇、乙醇)达到21.8 g/L。【结论】采用长时间且丁醇浓度呈梯度渐进增加的胁迫驯化方式,可使菌种在丁醇的环境中不断进化并有效地提高菌株对丁醇的耐受性。多因子复合筛选方法较其他单一因子筛选方法更为有效,能较快获得丁醇高产菌。     

副干酪乳杆菌HD1.7群体感应行为

【目的】Paracin1.7是从副干酪乳杆菌(Lactobacillus paracasei)HD1.7发酵液中提取的一种细菌素,本文主要研究菌株HD1.7在发酵过程中调控Paracin1.7代谢的群体感应机制。【方法】利用杯碟法检测不同生长条件下菌株HD1.7培养液的抑菌活性,通过调整培养基营养成分的多寡,控制培养液中细胞密度。【结果】菌株HD1.7的抑菌活性与其细胞密度密切相关,只有当细胞密度达到一定的阈值(OD600为0.8,菌体干重为0.331 1 g/L)时,菌株才能表现抑菌活性;以发酵上清液作为信号分子,当添加不同浓度信号分子至低于阈值浓度培养液后,菌株抑菌活性受到不同程度的影响,并且在去除信号分子后,菌株的抑菌活性明显降低。【结论】细菌素Paracin1.7是存在于HD1.7发酵液中的特殊的群体感应信号分子,可进行自我诱导。细菌素Paracin1.7的抑菌活性受到HD1.7群体感应系统的调控。     

泡菜、传统腊肠中降胆固醇乳酸菌的筛选及鉴定

摘要：【目的】筛选具有降胆固醇功能的乳酸菌菌株,为乳酸菌体外、体内的降胆固醇生理特性和机理研究奠定基础。【方法】以碳酸钙-MRS选择性培养基(Calcium Carbonate-Man Rogosa and Sharp Medium)从中国传统食品泡菜、腊肠中筛选乳酸菌,应用改良的胆固醇筛选培养基筛选具有较高降胆固醇能力的乳酸菌菌株,并研究其耐酸性,耐胆盐活性,生长曲线及产酸特性;结合菌落形态学、接触酶反应、革兰氏染色、碳水化合物微量鉴定管及16SrRNA寡核苷酸碱基序列分析鉴定菌株。【结果】筛选得到的两     

一株红假单胞菌的分离及对Cu2+的去除

【背景】重金属污染对环境和人类的健康构成了重大威胁,因此,重金属污染的治理迫在眉睫。生物治理因成本低、处理效果好和无二次污染等优点,在处理重金属污染时被优先选择。【目的】从辽河入海口深13 m的水体中,利用紫色非硫细菌富集培养基筛选产色素能力强并对高浓度Cu~(2+)有高效去除能力的菌株。【方法】采用形态学、生理生化特性和分子生物学方法鉴定菌种;采用二乙基二硫代氨基甲酸钠分光光度法测定Cu~(2+)的含量。【结果】鉴定菌株为红假单胞菌属,将其命名为Rhodopseudomonas sp. gh32。菌株gh32的最适生长温度和最适pH分别为30°C和7.0,其在pH 5.0-10.0范围内可正常生长,在3 mmol/L的CuSO4溶液中能够正常生长,能利用葡萄糖、甘露糖和果糖等单糖和硫化氢。菌株gh32在24h内对Cu~(2+)的去除率均在99%以上,处理能力为1 331 g/g干菌重或167.6 g/g湿菌重。【结论】菌株gh32对Cu~(2+)具有较强的耐受性和很好的去除效果,是治理含Cu~(2+)废水的潜力菌株。本研究为生物治理重金属废水提供了支持。     

北疆传统发酵生奶酪中乳酸菌的耐受性及益生特性测定

【背景】北疆乳制品中生奶酪作为发酵乳制品,其中有多种微生物的参与,是优质食品级微生物的宝贵来源,然而其中蕴含的丰富的微生物资源也面临着流失。【目的】研究已筛选出的41株乳酸菌的生长曲线变化规律,并对其在低pH环境的耐酸特性及益生特性进行分析。【方法】通过人工模拟胃肠液和含0.3%、0.5%、1.0%浓度牛胆盐溶液培养,对从生奶酪中分离鉴定的41株乳酸菌菌株进行人工胃肠液、牛胆盐耐受性试验。【结果】41株乳酸菌中有6株乳酸菌(编号为QM-5、QM-27、UM-12、UM-18、NM-11和NM-14)均能在pH值分别为2.0、2.5、3.0、3.5、4.0时生长较好,在pH 2.0的环境下也保持一定程度的生长。菌株存活率大于50%,乳酸菌含量为108 CFU/mL以上。从生奶酪分离的乳酸菌有极强的耐酸、耐胆盐特性,可以预测在胃肠道环境生存。41株菌对大肠杆菌(Escherichia coli)、金黄色葡萄球菌(Staphylococcus aureus)和枯草芽孢杆菌(Bacillus subtilis)均有抑制作用。【结论】通过比较耐酸性、胃肠道模拟、胆盐耐受性和抑菌特性等实验结果,初...     

谷氨酸棒杆菌S9114中amn基因缺失对生理代谢的影响

摘要:【目的】为了研究腺苷单磷酸核苷酶基因(amn)缺失对谷氨酸棒杆菌S9114生理代谢的影响。【方法】本文构建了amn基因缺失菌株△amn,并对谷氨酸发酵性能以及酸耐受性进行了比对分析。【结果】与野生菌株WT相比,amn基因缺失菌株:(1)细胞干重提高了16.2%,谷氨酸产量降低了58.8%;(2)发酵10 h、25 h和40 h,胞内ATP分别提高了3.0、3.7和2.2倍,异柠檬酸裂合酶活性提高17.1%、4.9%和44.5%,异柠檬酸脱氢酶活性降低76.9%、74.6%和5.0%,谷氨酸脱氢酶活性降低42.4%、50.8%和42.4%;(3)pH4.0条件下存活率降低了64.9%,而胞内ROS和蛋白质羰基化水平提高了31.5%和22.5%。【讨论】amn基因的缺失提高了菌株的胞内ATP水平和生物量,但是对谷氨酸发酵和酸性条件的耐受性却产生不利影响。     

甲基营养菌MB200中mutS的缺失及高浓度甲醇和甲醛诱变

【背景】甲基营养菌(Methylobacterium)是一类能够以单碳或非C-C键低碳化合物(如甲烷、甲醇、甲醛等)为底物生长,并可生产多种代谢产物如氨基酸、工业酶和辅助因子、多羟基烷酸酯(polyhydroxyalkanoates,PHA)、多糖和类胡萝卜素等的革兰氏阴性细菌。【目的】通过突变甲基营养菌MB200的mutS基因,在胁迫条件下定向诱导,以获得可以耐受高浓度甲醇和甲醛的生产菌株。【方法】利用三亲本结合构建mutS基因缺失的高突变菌株MB200sTB,逐步提升培养液中甲醇、甲醛的浓度进行定向诱导突变,对获得的高耐受性突变株进行回补,分析菌株的生长情况。【结果】构建了mutS基因的缺失突变体MB200sTB,并且得到了高耐受甲醇和甲醛的菌株MB200sHBc和MB200sHBq。MB200sHBc与野生株MB200相比其甲醇耐受性得到了极显著的提高,甲醇耐受浓度从8g/L提升到44g/L,但生长量不受影响。MB200sHBq在以甲醛为0.45g/L的碳源条件下,生长量相较于野生型MB200提高了1.69倍。【结论】通过定向诱导缺失mutS基因的突变体,可获得具有生产应用潜力的...     

Nickel tolerance and copper - nickel co - tolerance in Mimulus guttatus from copper mine and serpentine habitats

Previous work on M. guttatus suggested that nickel tolerance in copper mine populations may also be given by the genes for copper tolerance. It has been shown that copper tolerance in M. guttatus is controlled by a single major gene, plus a number of minor genes (or modifiers) which elevate copper tolerance. Crosses between nickel tolerant individuals from three families and non - tolerants showed that nickel tolerance in M. guttatus is heritable. In order to study the effects of the major copper tolerance gene on copper - nickel co - tolerance in M. guttatus, homozygous copper tolerant and non - tolerant lines were screened against nickel. Significant differences occur between these lines for copper, but were not found when analysed for nickel, indicating that copper - nickel tolerance is not governed by the major gene for copper tolerance. To test whether the minor genes for copper have a pleiotropic effect on nickel tolerance, five selection lines derived from three copper mines (Copperopolis, Penn and Quail) in Calaveras county, California, which vary in degree of tolerance to copper, by the presence or absence of minor copper genes, were also screened against nickel. Two out of three of the lines from Copperopolis showed elevated tolerance to nickel, but two further selection lines derived from Penn and Quail copper mines gave no indication of increased nickel tolerance. These results suggest that the minor genes for copper do not give tolerance to nickel. This was confirmed by the screening of modifier lines, in which modifiers for differing degrees of copper tolerance were inserted into a non - tolerant background. Genotypes possessing fewer copper modifiers yielded higher nickel tolerance than those genotypes which have a greater number of modifiers. Thus nickel tolerance in this species is heritable and under the control of different genes to those producing copper tolerance.     

Cloning of heat shock protein genes (hsp70, hsc70 and hsp90) and their expression in response to larval diapause and thermal stress in the wheat blossom midge,Sitodiplosis mosellana

Sitodiplosis mosellana Géhin, one of the most important pests of wheat, undergoes obligatory diapause as a larva to survive unfavorable temperature extremes during hot summers and cold winters. To explore the potential roles of heat shock proteins (hsp) in this process, we cloned full-length cDNAs of hsp70, hsc70 and hsp90 from S. mosellana larvae, and examined their expression in response to diapause and short-term temperature stresses. Three hsps included all signature sequences of corresponding protein family and EEVD motifs. They showed high homology to their counterparts in other species, and the phylogenetic analysis of hsp90 was consistent with the known classification of insects. Expression of hsp70 and hsp90 were highly induced by diapause, particularly pronounced during summer and winter. Interestingly, hsp70 was more strongly expressed in summer than in winter whereas hsp90 displayed the opposite pattern. Abundance of hsc70 mRNA was comparable prior to and during diapauses and was highly up-regulated when insects began to enter the stage of post-diapause quiescence. Heat-stressed over-summering larvae (⩾30 °C) or cold-stressed over-wintering larvae (⩽0 °C) could further elevate expression of these three genes, but temperature extremes i.e. as high as 45 °C or as low as −15 °C failed to trigger such expression patterns. Notably, hsp70 was most sensitive to heat stress and hsp90 was most sensitive to cold stress. These results suggested that hsp70 and hsp90 play key roles in diapause maintenance and thermal stress; the former may be more prominent contributor to heat tolerance and the latter for cold tolerance. In contrast, hsc70 most likely is involved in developmental transition from diapause to post-diapause quiescence, and thus may serve as a molecular marker to predict diapause termination.     

温度和渗透应激对植物乳杆菌稳定性的影响

在植物乳杆菌对数期后期,高温（43—47℃）、低温（15—25℃）及10-30g/L NaCl等应激处理60min均可使植物乳杆菌耐热性和耐酸性得到较大的提高。其中,尤以高温应激45℃应激处理效果最好,细胞耐热残存率和耐酸残存率较对照分别提高124％和56．8％。     

一株耐受低pH、高浓度乳酸及琥珀酸菌株的筛选与鉴定

【目的】通过构建的人工耐酸系统,筛选耐受低pH值、乳酸及琥珀酸的菌株。【方法】构建人工耐酸系统长期驯化菌株,利用不同p H的酸性平板进行筛选,从环境中筛选出一株对低p H值、高浓度乳酸以及琥珀酸有很好耐受性的菌株。通过形态学特征、生理生化特征研究,并结合18S rDNA基因序列分析及分子系统发育树的构建结果,确定菌株的种类。【结果】经过酸性人工系统的长期驯化,筛选分离出一株耐受低pH值、高浓度乳酸以及琥珀酸的菌株WJ-2,经鉴定该菌株为酿酒酵母(Saccharomyces cerevisiae),其最适生长温度为30°C。酸性平板实验显示该菌株能够耐受pH2.5的酸性环境,同时对9%的乳酸及8%的琥珀酸也有很好的耐受性。另外,耐酸菌株WJ-2在pH 2.5、9%乳酸和8%琥珀酸的培养环境中仍能保持相对中性的细胞内pH值。【结论】通过构建人工酸性系统,成功筛选出一株对低pH值、高浓度乳酸以及琥珀酸具有耐受性的菌株——酿酒酵母菌WJ-2,该方法可为筛选具有特定耐受能力菌株提供一个新思路。     

Hydroponic screening of poplar for trace element tolerance and accumulation

Using the nutrient film technique, we screened 21 clones of poplar for growth in the presence of a mix of trace elements (TE) and for TE accumulation capacities. Poplar cuttings were exposed for four weeks to a multipollution solution consisting in 10 microM Cd, Cu, Ni, and Pb, and 200 microM Zn. Plant biomass and TE accumulation patterns in leaves varied greatly between clones. The highest Cd and Zn concentrations in leaves were detected in P. trichocarpa and P. trichocarpa hybrids, with the clone Skado (P. trichocarpa x P. maximowiczii) accumulating up to 108 mg Cd kg(-1) DW and 1510 mg Zn kg(-1) DW when exposed to a multipollution context. Our data also confirm the importance of pH and multipollution, as these factors greatly affect TE accumulation in above ground biomass. The NFT technique applied here to a large range of poplar clones also revealed the potential of the Rochester, AFO662 and AFO678 poplar clones for use in phytostabilization programs and bioenergy production, where production of less contaminated above ground biomass is suitable.     

小麦地上部和根系生长的相关性及其在耐Al性筛选中的作用

1　引　　言以往的研究中 ,测定植物根系长度或重量通常以相对根长或相对根系干重作为耐性指标进行耐Ａｌ性的筛选[2 ,4 ,5,8] .但是根系性状在土培或田间试验中不仅取样和测定困难 ,而且易造成根系损伤 ,影响测定的精度 .因此 ,有必要建立简便、可靠且易于测定的筛选指标 .能否采用植株地上部耐性指标来衡量不同小麦基因型的耐Ａｌ性 ?以往涉及植物在铝毒胁迫下地上部和根系生长的耐性指标间的相关性 ,以及地上部耐性指标用于耐Ａｌ性筛选方面的研究甚少 .本研究采用两种筛选方法探讨了 2 4个小麦基因型地上部和根系耐性指标间的相关性 ,旨…     

Heterologous production and biochemical characterization of a new highly glucose tolerant GH1 β-glucosidase from Anoxybacillus thermarum

The enzymatic lignocellulosic biomass conversion into value-added products requires the use of enzyme-rich cocktails, including β-glucosidases that hydrolyze cellobiose and cellooligosaccharides to glucose. During hydrolysis occurs accumulation of monomers causing inhibition of some enzymes; thus, glucose/xylose tolerant β-glucosidases could overcome this drawback. The search of new tolerant enzymes showing additional properties, such as high activity, wide-pH range, and thermal stability is very relevant to improve the bioprocess. We describe a novel β-glucosidase GH1 from the thermophilic Anoxybacillus thermarum (BgAt), which stood out by the robustness combination of great glucose/xylose tolerance, thermal stability, and high Vmax. The recombinant his-tagged-BgAt was overexpressed in Escherichia coli, was purified in one step, showed a high glucose/xylose tolerance, and activity stimulation (presence of 0.4 M glucose/1.0 M xylose). The optimal activity was at 65 °C - pH 7.0. BgAt presented an extraordinary temperature stability (48 h – 50 °C), and pH stability (5.5–8.0). The novel enzyme showed outstanding Vmax values compared to other β-glucosidases. Using p-nitrophenyl-β-d-glucopyranoside as substrate the values were Vmax (7614 U/mg), and K_M (0.360 mM). These values suffer a displacement in Vmax to 14,026 U/mg (glucose), 14,886 U/mg (xylose), and K_M 0.877 mM (glucose), and 1.410 mM (xylose).     

植物抗寒性与抗寒基因的表达和调控

综合概述了国内外有关植物抗寒机理的研究动态,主要讨论了抗寒基因的表达与调控在植物抗寒性中的反应。此外,亦提出了有关植物抗寒机制研究领域值得深入研讨的问题。     

The microfilament cytoskeleton plays a vital role in salt and osmotic stress tolerance in Arabidopsis

Although recent studies have suggested that the microfilament (MF) cytoskeleton of plant cells participates in the response to salt stress, it remains unclear as to whether the MF cytoskeleton actually plays an active role in a plant's ability to withstand salt stress. In the present study, we report for the first time the role of MFs in salt tolerance of Arabidopsis thaliana . Our experiments revealed that Arabidopsis seedlings treated with 150 m m NaCl maintained MF assembly and bundle formation, whereas treatment with 250 m m NaCl initially induced MF assembly but subsequently caused MF disassembly. A corresponding change in the fluorescence intensity of MFs was also observed; that is, a sustained rise in fluorescence intensity in seedlings exposed to 150 m m NaCl and an initial rise and subsequent fall in seedlings exposed to 250 m m NaCl. These results suggest that MF assembly and bundles are induced early after salt stress treatment, while MF polymerization disappears after high salt stress. Facilitation of MF assembly with phalloidin rescued wild-type seedlings from death, whereas blocking MFs assembly with latrunculin A and cytochalasin D resulted in few survivors under salt stress. Pre-treatment of seedlings with phalloidin also clearly increased plant ability to withstand salt stress. MF assembly increased survival of Arabidopsis salt-sensitive sos2 mutants under salt stress and rescued defective sos2 mutants. Polymerization of MFs and its role in promoting survival was also found in plants exposed to osmotic stress. These findings suggest that the MF cytoskeleton participates and plays a vital role in responses to salt and osmotic stress in Arabidopsis .