库尔勒香梨火疫病危害症状及其病原菌生物学特性研究

研究库尔勒香梨火疫病危害症状及其病原菌生物学特性,为库尔勒香梨火疫病的防治提供一定的理论基础。2021—2022年,对梨火疫病危害症状进行田间观察,并分离出病原菌(TDXL),在NA和LB培养基上进行培养,利用扫描电镜和透射电镜进行形态特征观察,采用16S rDNA和pEA29质粒基因片段从分子水平解析病原菌致病性的调控机制,并对叶片和幼果选用针刺法进行致病性测定。结果表明:库尔勒香梨火疫病主要的症状有花序黑死、幼果黑死、枯梢、叶脉变黑、枯枝、短枝坏死、菌脓和溃疡斑;病原菌一般从花序侵入树体,逐步侵染其他健康的植物组织,树体带菌翌年从溃疡斑由内向外引起着生枝条发病;病原菌形态学观察发现,菌落呈白色、边缘整齐、圆形,菌体呈短杆状,以单生为主,大小为0.4~1.2μm×0.9~1.9μm;构建系统发育树发现,TDXL与解淀粉欧文氏菌(Erwinia amylovora)聚在同一支上;叶片和幼果接种病原菌均可致病并出现菌脓。通过对病原菌的形态学观察和系统发育树的构建,确定引起库尔勒香梨火疫病的病原菌为E.amylovora。

梨轮纹病原菌及生防菌对梨果实抗氧化酶体系的影响

[目的]了解梨果实接种梨轮纹病原菌后的防御机制和生防菌的酶活作用机理。[方法]采用不同处理在梨果实上接种梨轮纹病原菌和喷施生防菌,测定其对梨果实抗氧化酶体系的影响。[结果]丙二醛(MDA):生防菌处理对MDA含量变化影响不大,轮纹菌处理MDA含量48 h达到高峰值,为10.22 nmol/g,是对照的1.86倍,轮纹菌+生防菌处理MDA含量24 h达到高峰值,为8.92 nmol/g,是对照的1.62倍;超氧物歧化酶(SOD):生防菌处理的SOD酶活值48 h达到高峰,为126.69 U/[g(FW)·min],是对照的1.54倍,轮纹菌与轮纹菌+生防菌处理均在24 h出现活性高峰,酶活值分别为122.10和135.32 U/[g(FW)·min],是对照的1.48和1.65倍;过氧化物酶(POD):生防菌、轮纹菌、轮纹菌+生防菌处理的POD酶活均在24 h达到高峰值,分别为385.34、342.50、290.00 U/[g(FW)·min],为对照的1.83、1.62、1.38倍;过氧化氢酶(CAT):生防菌、轮纹菌、轮纹菌+生防菌处理的CAT酶活在6 h时均达到高峰值,分别为133.33、114.17和113.35 U/[g(FW)·min],为对照的1.33、1.14和1.13倍;多酚氧化酶(PPO):生防菌处理和对照差异不明显,轮纹菌处理酶活高峰出现在12 h,为81.86 U/[g(FW)·min],为对照的1.76倍,轮纹菌+生防菌处理酶活高峰出现在24 h,为70.00U/[g(FW)·min],为对照的1.50倍。[结论]轮纹菌和轮纹菌+生防菌对MDA含量影响较大;轮纹菌及生防菌都能激发SOD酶活性的升高;接种轮纹菌及喷施生防菌都能激发POD酶活性的升高;轮纹菌及生防菌都能激发CAT酶活的升高;单独施用生防菌效果不明显,轮纹菌更能激发PPO酶活性的升高。

大蒜素对库尔勒香梨梨火疫病的控害作用及安全性评价

为了明确5%大蒜素对梨火疫病病原菌有无抑制作用并对库尔勒香梨生长进行安全性评价,本试验采用抑菌圈法测定5%大蒜素对梨火疫病病原物的抑制效果,且在库尔勒香梨花期进行田间喷药安全性试验,结果表明:室内毒力测定5%大蒜素对梨火疫病有抑制作用,EC50为37.70 mg/L,温度较高时会产生药害,药害随药剂浓度降低而降低,500倍药害严重,1500倍药害中等,稀释至2500倍时无药害。建议5%大蒜素可作为梨火疫病的杀菌剂使用。但在库尔勒香梨花期使用时,5%大蒜素对其会产生药害,建议一定要严格按照药剂推荐的田间浓度,并要求在早晨或傍晚施药。

臭氧对砀山酥梨采后生理及腐烂效果的影响

研究了臭氧对冷藏条件下砀山酥梨采后生理以及贮期病害的影响。在冷藏(缓慢降温至(0±0.5℃)期间,每日用4 mg/m^3臭氧处理砀山酥梨3 h,定期测定了贮藏期相关生理指标和腐烂率,并进行了臭氧对砀山酥梨主要致腐菌梨青霉、梨褐腐、梨轮纹的离体和活体实验。臭氧处理可显著抑制砀山酥梨的呼吸强度,延缓可溶性固形物、可滴定酸以及丙二醛含量,有效降低果实的腐烂率,但对果实硬度没有显著影响;臭氧明显抑制引起砀山酥梨发生腐烂的青霉痛、褐腐病、以及轮纹病病原真菌孢子的萌发,抑制了接种病原菌在梨果实上的扩展。将臭氧用于砀山酥梨的贮藏,既可维持较高的贮藏品质,又可防治果实腐烂。

Effect of Botryosphaeria berengeriana f.sp.piricola and Biocontrol Bacteria on the System of Antioxidant Enzymes in Pears

[Objective] The aim was to understand defense mechanism of pear after inoculated Botryosphaeria berengeriana f. sp. piricolan and mechanism of antioxidant enzymes of biocontrol bacteria. [Method] Pears were treated by Botryosphaeria berengeriana f. sp. piricolan and bio control bacteria, and the change of antioxidant enzymes were determined. [Result] The biocontrol bacteria had little effect on MDA;the content of MDA treated by B. berengeriana reached high peak in 48 h, was 10.22nmol/g which was 1.86 times of CK; the content of MDA treated by B. berengeriana and biocontrol bacteria reached high peak in 24 h, was 8.92 nmol/g which was1.62 times of CK. The content of SOD treated by biocontrol bacteria reached high peak in 48 h, was 126.69 U/[g（FW）·min] which was 1.54 times of CK; the contents of SOD treated by B. berengeriana as well as B. berengeriana and biocontrol bacteria reached high peak in 24 h, were 122.10 and 135.32 U/[g（FW）·min] which were 1.48 and 1.65 times of CK respectively; the contents of POD on biocontrol bacteria treatment, B. ana treatment as well as B. berengeriana and biocontrol bacteria treatment reached high peak in 24 h, were 385.34, 342.50 and 290.00 U/[g（FW）·min] which were 1.83, 1.62 and 1.38 times of CK respectively. The contents of CAT on biocontrol bacteria treatment, B. rengeriana treatment as well as B. berengeriana and biocontrol bacteria treatment reached high peak in 6 h, were 133.33,114.17 and 113.35 U/[g（FW）·min] which were 1.33, 1.14 and 1.13 times of CK respectively. The biocontrol bacteria had little difference in CK; the content of PPO of B. berengeriana treatment reached high peak in 12 h, was 81.86 U/[g（FW）·min]which was 1.76 times of CK; B. berengeriana and biocontrol bacteria treatment reached high peak in 24 h, was 70.00 U/[g（FW）·min] which was 1.50 times of CK.[Conclusion] B. berengeriana and biocontrol bacteria had more effect on MDA; both B. berengeriana and biocontrol bacteria could increase the excitation of SOD enzyme activity; both B. berengeriana and biocontrol bacteria could increase the excitation of POD enzyme activity; both B. berengeriana and biocontrol bacteria could increase the excitation of CAT enzyme activity; using biocontrol bacteria alone had not obvious effect on PPO, B. berengeriana could increase the excitation of PPO enzyme activity.