2020年底各地新玉米霉菌毒素风险分析

为了解呕吐毒素（DON）、玉米赤霉烯酮（ZEN）和黄曲霉毒素B1（AFB1）在2020年底新玉米中的污染情况,指导饲料生产企业和养殖场（户）开展霉菌毒素防控,降低霉菌毒素对饲料质量安全及养殖动物的影响,避免经济受损的风险。2020年12月在市场上采集新玉米样本225份,采用胶体金免疫层析法或上转发光免疫分析法对其霉菌毒素污染情况进行检测,依据安佑集团相关企业标准标和GB 13078-2017《饲料卫生标准》进行判定分析。结果表明：新玉米中霉菌毒素检出率为96.0%,其中DON、ZEN和AFB1的检出率分别为85.8%、87.1%和86.7%|DON、ZEN和AFB1在新玉米中的污染状况差别较大,按《饲料卫生标准》判定的超标率分别为0.0%、0.4%和11.6%|最大检测值分别为2500、534 μg/kg和＞100 μg/kg。就产地而言,山西、内蒙古、东北、安徽、山东、河南、云南、陕西等地霉菌毒素污染较重。综上,与2019年及2020年玉米霉菌毒素污染调查数据相比,2020年底新玉米污染程度较重。 [关键词] 玉米|霉菌毒素|胶体金免疫层析法|上转发光免疫分析法|污染规律     

棉花枯萎病菌毒素对种子发芽和组织生长的毒害作用

用改良理查德液体产毒培养基培养棉花枯萎病菌,取其培养滤液作为毒素液。测试了毒素液对抗病、感病品种种子发芽、愈伤组织的诱导和生长的毒害作用和对幼苗的致萎作用以及对叶片电导率的影响。为毒素液应用于抗病资源的快速筛选与鉴定、体细胞抗性突变体的筛选等研究提供了可靠的参考资料。     

蓖麻毒素基本生物学特性分析

[目的]对蓖麻毒素分子量、等电点和氨基酸序列等基本生物学特性进行分析。[方法]以内蒙古通辽地区所产蓖麻哲蓖2号为对象,利用毛细管电泳技术、分子生物学技术、毒性检测等免疫学技术对其毒素基本生物学特性进行检测分析。[结果]试验中所用蓖麻毒素的等电点为6.49,分子量为61.9kD,其氨基酸序列与网上公布序列相比,A链有22个位点发生变异,B链无变异;小鼠口服LD50为5.0mg/kg,腹腔注射LD50为4.6μg/kg,淋巴细胞IC50为3μg/ml。[结论]该研究为深入了解蓖麻毒素生物学性质提供依据,同时为不同产地蓖麻毒素毒性及其他性质的差异比较奠定基础。     

马铃薯疮痂病菌毒素及其致病性的研究

 本文对分离自我国不同地区的马铃薯疮痂病菌产生的毒素进行了研究。通过对不同菌株进行毒素提取、纯化和产毒分析发现各致病菌株均能产生同一类毒素,而非致病菌株均未见毒素产生。毒素的活性检测结果表明,毒素能使马铃薯薯片和萝卜幼苗产生与病菌作用相同的症状,说明毒素是疮痂病菌侵染过程中的主要致病因子。     

Comparative Studies on Corynebacter1Um Pyogenes Toxin Formation in Monocultures and Mixed Cultures: The Demonstration of a Stimulating Effect of Peptococcus Indolicus and Stuart-Schwan Cocci

The growth and the toxin (i.e. hemolysin) producing capacity of Corynebacterium pyogenes were studied in monocultures and in co-cultures with 1 or more of the organisms frequently accompanying it in summer mastitis in cattle (Peptococcus indolicus, Stuart-Schwan cocci, Bacteroides melaninogenicus subsp. levii, Fusobacterium necrophorum and Streptococcus dysgalactiae) or with organisms seldom associated with summer mastitis (Streptococcus uberis, Streptococcus agalactiae, non-toxic staphylococci and Escherichia coli).Pc. indolicus, and to some extent also Stuart-Schwan cocci, stimulated the growth as well as the hemolysin producing capacity of Gb. pyogenes (Table 1) while Str. dysgalactiae, Str. uberis, Str. agalactiae, E. coli and the majority of the staphylococci reduced these activities. Most F. necrophorum strains stimulated the growth, but not the hemolytic activity. With B. melaninogenicus the results were inconclusive.The effect of Pc. indolicus appeared to be associated with the production of a filterable factor (Tables 2 and 3).Mouse toxicity and hemolytic activity of culture filtrates were closely correlated (Table 4).     

虎纹捕鸟蛛毒素提取的研究

为探索提取广西产虎纹捕鸟蛛(Selenocosmia huwena)毒素的新方法,选取雌性虎纹捕鸟蛛225只,根据提取方法(直接咬软管法、直接咬瓶法、激怒咬渐法激怒咬瓶冲洗法)分为4组,结果表明,采用直接咬软管法提取虎纹捕鸟蛛毒素,平均每只蜘蛛可以获得冻干毒素2.28 mg,与采用直接咬瓶法所获得的2.19 mg没有显著差异(P>0.05)。采用激怒咬瓶冲洗法提取虎纹捕鸟蛛毒素,平均每只蜘蛛可以获得冻干毒素重量明显高于激怒咬瓶法[(3.41±0.40)mg,(2.99±0.35)mg,P<0.05],亦明显高于直接咬软管法和直接咬瓶法。该试验结果表明,激怒咬瓶冲洗法是一种提取虎纹捕鸟蛛毒素的有效方法。     

霍乱弧菌封闭带毒素功能片段△G的原核表达及其免疫增强活性

用PCR扩增了MBP—ZOT质粒上的ZOT基因，该基因编码264～399位氨基酸残基C末端的15ku △G片段，并与经改造后的质粒P^BCX、连接。将重组后的质粒PMLAG在大肠杆菌BL21中表达，将表达的目的蛋白纯化，再将p^BCX-△G片段与传染性腔上囊炎病毒VP2包涵体蛋白通过滴鼻免疫途径对14日龄SPF鸡进行联合免疫试验，分别于免疫后第10、20d采集血清样品，进行ELISA试验，检测免疫后IBD抗体效价。动物免疫试验发现：融合蛋白P^BCX △G起到了明显免疫增强效果，与VP2重组蛋白联合免疫2次后，血清IBD的VP2 IgG抗体效价是单独用VP2免疫组的3倍，明显高于空白免疫组。     

D型魏氏梭菌毒素研究进展

魏氏梭菌病是由魏氏梭菌引起的一种重要的人兽共患传染病。可导致各种动物的肠毒血症或坏死性肠炎,D型魏氏梭菌病包括牛、羔羊、绵羊、山羊以及灰鼠的肠毒血症等。D型魏氏梭菌所产的毒素是引起动物死亡的重要因素之一,本文综述了D型魏氏梭菌毒素的结构、功能以及检测方法的研究进展。     

Identification of Alternaria spp. on wheat by pathogenicity assays and sequencing

The pathogenicity of Alternaria spp. isolated from wheat leaves collected in regions where alternaria leaf blight has been reported was compared with that of IMI reference isolates of A. triticina and A. alternata using two durum and two bread wheat genotypes. To identify isolates putatively corresponding to A. triticina , morphological and DNA sequence analyses based on ribosomal DNA from the internal transcribed spacer (ITS) region (ITS1, 5·8S rRNA gene, ITS2) and toxicity bioassays of culture filtrate were combined. Glasshouse inoculations provided reliable information to assess the pathogenicity of A. triticina isolates on wheat. Alternaria leaf blight symptoms were produced by the A. triticina isolates only on durum wheat cv. Bansi, while A. alternata , A. tenuissima and A. arborescens isolates were found to be nonpathogenic on the wheat cultivars tested. Alternaria triticina isolates were distinguished from other Alternaria species by Simmons and Roberts' sporulation pattern 6 and two to three conidia per sporulation unit associated with primary conidia bearing long (> 7  µ m) apical secondary conidiophores. Phylogenetic analysis also proved effective at discriminating wheat-pathogenic A. triticina from other nonpathogenic Alternaria species. Alternaria triticina isolates yielded longer ITS sequences than A. alternata , A. tenuissima and A. arborescens isolates, leading to clear-cut differences as visualized with agarose gel electrophoresis. Additionally, only culture filtrates of A. triticina isolates caused nonspecific necrotic lesions on leaves of 3-week-old wheat plants.     

Detoxification of α-tomatine by tomato pathogens Alternaria alternata tomato pathotype and Corynespora cassiicola and its role in infection

In tomato plants, α-tomatine, a steroidal glycoalkaloid saponin, inhibits fungal growth. Tomato pathogens that produce host-specific toxins, Alternaria alternata tomato pathotype causing Alternaria stem canker and Corynespora cassiicola causing Corynespora target spot, were investigated for sensitivity to α-tomatine. Although spore germination of A. alternata pathogenic and nonpathogenic to tomato and of C. cassiicola pathogenic to tomato was not affected by 0.1 mM α-tomatine, spore germination of C. cassiicola nonpathogenic to tomato was significantly inhibited. This result showed that A. alternata, regardless of its pathogenicity, and only the C. cassiicola pathogenic to tomato are resistant to α-tomatine. Germinating spores of A. alternata and C. cassiicola resistant to α-tomatine detoxified α-tomatine by degrading it to a less polar product. After inoculation of tomato leaves, spores of A. alternata and C. cassiicola nonpathogenic to tomato germinated and formed appressoria, but did not form infection hyphae in host tissues. When a host-specific toxin (CCT-toxin) produced by C. cassiicola pathogenic to tomato was added to nonpathogenic spores, colonization within leaves was observed in A. alternata, but not in C. cassiicola. On the other hand, when spores of C. cassiicola nonpathogenic to tomato were suspended in spore germination fluid of nonpathogenic A. alternata with α-tomatine detoxification activity, the fungus could be induced to colonize leaves in the presence of CCT-toxin. These results indicate that A. alternata tomato pathotype and C. cassiicola pathogenic to tomato detoxify α-tomatine during infection and that this detoxification is essential for host colonization by pathogens that produce host-specific toxins.