山西省番茄早疫病菌对苯醚甲环唑的敏感性及抗性突变体的适合度

为了解山西省番茄早疫病菌Alternaria solani对苯醚甲环唑的抗性,采用菌丝生长速率法检测了该病菌对苯醚甲环唑的敏感性,分析了抗性水平和抗性指数;同时通过室内诱导获得了苯醚甲环唑抗性突变体,检测了突变体的抗性遗传稳定性、交互抗性和适合度。结果表明:分离自大同、忻州、长治、晋中和运城5市的101株菌株的EC50范围为0.005～3.315 mg/L,均值为0.428 mg/L,其中敏感菌株占97.03%,低抗菌株占2.97%;抗性指数范围为0.295～0.447,均值为0.343。10株中抗突变体抗性均不能稳定遗传、生长速率减慢、产孢量降低、孢子萌发能力减弱、致病力下降;但在药剂压力下,突变体的致病力强于敏感菌株。苯醚甲环唑与代森锰锌、多抗霉素、啶酰菌胺无交互抗性,而与啶菌噁唑存在交互抗性。因此,今后需加强番茄早疫病菌对苯醚甲环唑的田间抗性监测,在生产过程中轮用或混用不同作用机制的药剂以延缓该病菌对苯醚甲环唑抗性的发展。     

禾谷镰孢菌对戊唑醇抗药性的诱导及抗性菌株特性研究

通过紫外线诱导获得了8株对戊唑醇具有不同抗性水平的禾谷镰孢菌Fusarium graminearum抗药突变体,其抗性倍数均≥30倍,最高达到186.03倍。将抗药突变体在无药培养基上继代培养9代后,其抗性倍数逐渐下降,抗药性可能不能稳定遗传。与亲本菌株相比,抗药突变体在菌落生长速率、菌丝干重、对温度和pH值的敏感性方面均有所下降,推测禾谷镰孢菌对戊唑醇可能具有中等或高抗药性风险。室内交互抗性测定结果表明,戊唑醇对苯醚甲环唑、多菌灵、异菌脲、百菌清及福美双均无交互抗性。     

山东省玉米纹枯病菌对噻呋酰胺的敏感性及其抗性突变体的生物学性状

为明确山东省玉米纹枯病菌对噻呋酰胺的敏感性及其抗药性风险,采用菌丝生长速率法分别测定了采自山东泰安、临沂、潍坊、莱芜、日照及青岛6个地区的102株玉米纹枯病菌对噻呋酰胺的敏感性。结果表明:其EC₅₀值分布范围为0.010～0.194 μg/mL,平均EC₅₀ 值为 (0.086 ± 0.004) μg/mL,且敏感性呈连续单峰曲线分布。通过紫外诱导与药剂驯化的方法各获得5株耐药性菌株 (TA3-X2、TA17-X6、LY8-3、QD14-Y7和WF6-A2) 和1株抗性突变体 (QD2-Y4),其抗性水平在6.46～20.08倍之间,突变频率分别为0.87%和0.52%。对抗性突变体生物学性状的研究表明,紫外诱导获得的5株耐药性菌株其耐药性不能稳定遗传,而经药剂驯化获得的1株抗性突变体QD2-Y4的抗药性可稳定遗传;耐药性菌株TA3-X2的菌丝生长速率高于亲本菌株,其余菌株与亲本菌株差异不明显;5株耐药性菌株和1株抗性突变体的菌丝干重和菌核干重均低于亲本菌株;TA3-X2、WF6-A2及QD2-Y4的致病力低于亲本菌株,TA17-X6、LY8-3及QD14-Y7的致病力与亲本菌株无明显差异。交互抗性测定表明,噻呋酰胺抗性突变体与戊唑醇、丙环唑、咯菌腈、井冈霉素、苯醚甲环唑和多菌灵之间均无交互抗性,与啶酰菌胺和氟唑菌苯胺之间则存在交互抗性。研究表明,山东省6个地区的玉米纹枯病菌对噻呋酰胺比较敏感,推测噻呋酰胺可作为防治玉米纹枯病的理想候选药剂。     

番茄叶霉病菌异菌脲抗药性突变体的诱导与生物学性状

测定了苯并咪唑类杀菌剂敏感-乙霉威抗性(BenS-DieR)、苯并咪唑类杀菌剂抗性-乙霉威敏感(BenR-DieS)和苯并咪唑类杀菌剂抗性-乙霉威抗性(BenR-DieR)3种类型的番茄叶霉病菌Cladosporium fulvum菌株对不同类型药剂的敏感性。结果表明,蕃茄叶霉病菌对供试药剂的敏感性与其对苯并咪唑类杀菌剂及乙霉威的敏感性无关。根据药剂对3类菌株EC50值的平均值, 16种杀菌剂抑制菌丝生长的活性依次为腐霉利＞乙烯菌核利＞异菌脲＞戊唑醇＞百菌清＞嘧霉胺＞醚菌酯＞代森锰锌＞8-羟基喹啉铜＞丙环唑＞苯醚甲环唑＞嘧菌酯＞灭锈胺＞烯酰吗啉＞烟酰胺＞三唑酮;抑制孢子萌发的活性依次为醚菌酯＞腐霉利＞百菌清＞乙烯菌核利＞灭锈胺＞8-羟基喹啉铜＞异菌脲＞代森锰锌＞嘧菌酯＞烟酰胺＞嘧霉胺＞戊唑醇＞丙环唑＞苯醚甲环唑＞三唑酮＞烯酰吗啉。通过紫外诱变共获得17株抗异菌脲突变体,突变频率为4.5×10-7。其中低抗、中抗和高抗菌株分别占 17.65%、70.59%和11.75%。这些突变体对腐霉利和乙烯菌核利表现交互抗性,对苯并咪唑类、脱甲基抑制剂(DMIs)、QoIs等药剂的敏感性与亲本菌株之间没有显著性差异,与亲本菌株在生长、产孢、致病能力等方面也无显著差异,但对渗透胁迫的敏感性要显著高于亲本。     

滇黄精炭疽病菌的初步鉴定及其对3种杀菌剂的敏感性

对2019年采集自云南省3个滇黄精产区的炭疽病菌进行形态学及ITS序列分子鉴定，并采用菌丝生长速率法，测定了40株黄精炭疽病菌对氟啶胺、咪鲜胺和苯醚甲环唑的敏感性。结果表明:从滇黄精炭疽病病叶上分离得到的40株炭疽病菌可能分别属于炭疽菌属中的胶孢炭疽菌Colletotrichum gloeosporioides、果生炭疽菌C. fructicola、博宁炭疽菌C. boninense和尖孢炭疽菌C. acutatum，其中果生炭疽菌29株，占总分离菌株的72.5%，为优势病原菌。3种杀菌剂对 40 株供试菌株的菌丝生长有明显的抑制作用，氟啶胺、咪鲜胺和苯醚甲环唑的EC₅₀ 值分别介于0.028~0.53 mg/L、0.018~2.69 mg/L 和 0.158~2.57 mg/L 之间，即供试菌株对氟啶胺的敏感性高于其对咪鲜胺和苯醚甲环唑的敏感性。目前，3个滇黄精产区的炭疽病菌尚未对氟啶胺、咪鲜胺和苯醚甲环唑产生抗药性。     

抗咯菌腈禾谷镰刀菌的紫外诱导及其生物学特性

为评估玉米茎腐病病原菌禾谷镰刀菌(Fusarium graminearum)对咯菌腈的室内抗药性风险,本研究通过室内紫外照射获得抗咯菌腈突变体,分析抗性突变体对咯菌腈的抗药性、遗传稳定性和生物学特性,及其对咯菌腈、戊唑醇、苯醚甲环唑、嘧菌酯的交互抗性。结果表明,经紫外照射5min,获得17株抗咯菌腈突变体,其对咯菌腈的EC50为72.78~290.09μg/mL,是亲本菌株的4 000~17 000倍;抗性突变频率为1.7×10-6,可稳定遗传;最适生长温度均为25℃,最适pH均为8,与亲本菌株相同;菌落生长速度低于亲本菌株;在含有0.9mmol/L NaCl的PDA培养基中培养的菌落形态与不含NaCl的PDA培养基中的相比,亲本菌株和4号抗性菌株色素沉积减少,而1号和16号抗性菌株色素沉积增加。推测禾谷镰刀菌对咯菌腈存在中等或高等的室内抗药性风险。室内抗药性测定表明抗性突变体对咯菌腈和苯醚甲环唑均产生了抗性。     

中国南方主要梨产区果生炭疽菌对苯醚甲环唑的敏感性

为明确苯醚甲环唑对果生炭疽菌Colletotrichum fructicola不同发育阶段的毒力,并建立中国南方主要梨产区(湖北、安徽、江西、江苏、浙江和福建)果生炭疽菌对苯醚甲环唑的敏感基线,采用孢子萌发法测定了苯醚甲环唑对6个代表性菌株孢子萌发和芽管伸长的影响,采用离体叶片接种法评价了苯醚甲环唑对该病菌的防治效果,采用菌丝生长速率法测定了120株果生炭疽菌对苯醚甲环唑的敏感性。结果表明:苯醚甲环唑对果生炭疽菌菌丝生长和芽管伸长的抑制效果较强,而对分生孢子萌发的抑制效果较弱,其平均EC50值分别为(0.33±0.03)、(2.61±0.26)和(29.87±1.31)μg/mL。160μg/mL的苯醚甲环唑对梨果生炭疽病的保护作用和治疗作用防效分别为92%和79%,而1000μg/mL的多菌灵则分别为51%和23%。来源于中国南方主要梨产区的120株果生炭疽菌对苯醚甲环唑均表现为敏感,EC50值范围0.27~1.12μg/mL,敏感性频率分布呈连续单峰曲线,符合正偏态分布,其平均EC50值(0.59±0.02)μg/mL可以作为我国南方主要梨产区果生炭疽菌对苯醚甲环唑的敏感基线。本研究结果为监测梨果生炭疽菌对苯醚甲环唑的田间抗药性发展奠定了基础,并为梨产区应用该药剂防治炭疽病提供了依据。     

杨树炭疽病菌对多菌灵及3种DMIs杀菌剂的敏感性

采用菌丝生长速率法,测定了可引起杨树炭疽病的59株胶孢炭疽菌和4株炭疽菌对多菌灵、苯醚甲环唑、戊唑醇和三唑酮4种杀菌剂的敏感性。结果表明:59株胶孢炭疽菌对多菌灵、苯醚甲环唑、戊唑醇和三唑酮的EC50值范围分别在0.037 1~0.130 1、0.102 5~1.680、0.069 1~1.917及3.053~38.59 μg/mL之间,平均EC50值分别为（0.066 4±0.013 1）、（0.374 1±0.254 8）、（0.681 2±0.442 1）和（19.82±6.200）μg/mL。胶孢炭疽菌对多菌灵的敏感性频率分布呈连续单峰曲线,表明尚未出现敏感性下降的群体;而对苯醚甲环唑和戊唑醇的敏感性频率分布呈现双峰,表明已出现敏感性下降的群体。4株炭疽菌对多菌灵、苯醚甲环唑、戊唑醇和三唑酮的最小EC50值和最大EC50值分别相差1.33、13.19、13.66和2.14倍,其中菌株Ca-4对苯醚甲环唑和戊唑醇的EC50值均大于4 μg/mL。不同寄主来源的胶孢炭疽菌对同种杀菌剂的敏感性之间无显著差异（P>0.05）。Spearman’s秩相关分析表明,胶孢炭疽菌对苯醚甲环唑和戊唑醇的敏感性之间呈显著正相关性（ρ=0.665 5,Pρ=0.489 6,PP>0.05）。研究结果对合理使用杀菌剂防治杨树炭疽病具有借鉴意义和参考价值。     

烟草赤星病菌对嘧菌酯抗性突变体的诱导及其生物学特性

为评价烟草赤星病致病菌链格孢Alternaria alternata对嘧菌酯的抗性风险，以敏感菌株J6为试材，通过菌丝药剂驯化和分生孢子紫外诱变诱导抗性突变体，并对抗性突变体的生物学特性进行了研究，同时对抗性突变体与敏感菌株线粒体的细胞色素b基因 (cyt b) cDNA序列全长进行了测序分析。结果表明:经药剂驯化未获得抗性突变体，而紫外诱变共获得7株抗性突变体，突变频率约为0.007%，抗性水平分别为5.27、8.28、25.28、12.82、6.14、9.28和52.91倍。适合度研究表明，抗性突变体与敏感菌株的分生孢子萌发能力及致病力相当，但分生孢子产生量均高于敏感菌株，菌丝生长速率除突变体6-1外均快于敏感菌株。cyt b基因cDNA序列分析表明:有4株抗性突变体在不同位点上发生了核苷酸突变，其中突变体6-7 cyt b的249位和871位碱基由T突变为C，但其编码的氨基酸未发生突变；突变体6-8 cyt b的734位碱基由T突变为C，引起所编码的245位丙氨酸突变为缬氨酸 (V245A)；突变体6-9 cyt b的510位碱基由T突变为A，所编码的170位由精氨酸替代了丝氨酸 (S170R)；突变体6-11 cyt b的732位碱基由T突变为A，所编码的244位由苯丙氨酸替代了亮氨酸 (L244F)，其776位碱基由T突变为C，所编码的259位由丙氨酸替代了缬氨酸（V259A），其1 156位碱基由A突变为G，所编码的氨基酸未发生变化。研究结果初步表明，烟草赤星病菌对嘧菌酯存在潜在的抗药性风险，其cyt b基因的点突变与其对嘧菌酯的抗药性有关。     

浙江省稻田藤仓镰孢霉对咪鲜胺的敏感性及抗药性菌株的适合度与交互抗性

为明确浙江省水稻恶苗病主要致病菌藤仓镰孢霉Fusarium fujikuroi对咪鲜胺的抗性现状,以1μg/mL为区分剂量,对2017和2018两年采自浙江省绍兴、嘉兴和金华3个地区稻田的共400株藤仓镰孢霉对咪鲜胺的抗性进行了检测,并测定了抗药性菌株的适合度及其对其他常用甾醇脱甲基抑制剂类(DMIs)杀菌剂的交互抗性。结果表明:两年的抗药性菌株频率分别为53.2%和46.7%;多数田间敏感菌株在产孢能力和孢子萌发能力上强于田间抗药性菌株,在菌丝生长速率和致病性方面则两者差异不大;就稻田藤仓镰孢霉而言,咪鲜胺与丙硫菌唑之间存在交互抗性,但咪鲜胺与戊唑醇、苯醚甲环唑、丙环唑、叶菌唑、己唑醇和三唑酮之间均不存在交互抗性。研究表明,浙江省稻田藤仓镰孢霉对咪鲜胺已经产生了严重的抗药性,需要轮换使用不同作用机制的杀菌剂进行防治。     

The Y123H substitution perturbs FvCYP51B function and confers prochloraz resistance in laboratory mutants of Fusarium verticillioides

Fusarium verticillioides reduces corn yield and contaminates infected kernels with the toxin fumonisin, which is harmful to humans and animals. Previous research has demonstrated that F. verticillioides can be controlled by the azole fungicide prochloraz. Currently, prochloraz is used as a foliar spray to control maize disease in China, which will increase the risk of resistance. Although F. verticillioides resistance to prochloraz has not been reported in the field, possible resistance risk and mechanisms resulting in prochloraz resistance were explored in the laboratory. Four prochloraz‐resistant strains of F. verticillioides were generated by successive selection on fungicide‐amended media. The mycelial growth rates of the mutants were inversely related to the level of resistance. All four mutants were cross‐resistant to the triazole fungicides triadimefon, tebuconazole and difenoconazole, but not to the multisite fungicide chlorothalonil or to the MAP/histidine‐kinase inhibitor fungicide fludioxonil. Based on the Y123H mutation in FvCYP51B, the four resistant mutants were subdivided into two genotypes: PCZ‐R1 mutants with wildtype FvCYP51B and PCZ‐R2 mutants with substitution Y123H in FvCYP51B. Wildtype FvCYP51B complemented the function of native ScCYP51 in Saccharomyces cerevisiae YUG37::erg11, whereas Y123H‐mutated FvCYP51B did not. For the PCZ‐R1 mutants, induced expression of FvCYP51A increased resistance to prochloraz. For the PCZ‐R2 mutants, disruption of FvCYP51B function by the Y123H substitution caused constitutive up‐regulation of FvCYP51A expression and thus resistance to prochloraz.     

Vegetative compatibility among isolates ofColletotrichum gloeosporioides from almond in Israel

Anthracnose, caused byColletotrichum gloeosporioides, is the major disease of almond in Israel. Pathogen attack of young fruit results in fruit rot and leaf wilting. Seventy isolates ofC. gloeosporioides were obtained from affected almond fruits collected at 11 sites during 1991–2 and 1994. Chlorate-resistant nitrate-nonutilizing (nit) mutants were generated from each isolate and used in complementation (heterokaryon) tests. The formation of complementary stable heterokaryons between mutants from different isolates showed that all the isolates belonged to a single vegetative compatibility group. Representative isolates ofC. gloeosporioides from almond did not form heterokaryons with local isolates ofColletotrichum from anemone and avocado, indicating that the almond isolates constitute a distinct subspecific group withinC. gloeosporioides.     

Molecular and biochemical characterization of Colletotrichum gloeosporioides isolates resistant to azoxystrobin from grape in China

Anthracnose, caused by Colletotrichum gloeosporioides, is one of the most important diseases in grape-growing regions worldwide. In Jiangsu Province of China, quinone-outside inhibitor fungicides (QoIs) have been extensively sprayed as disease control for more than 10 years. A spore germination assay of 64 isolates obtained from 32 commercial vineyards was used to assess isolate sensitivity to azoxystrobin and 62 were found to be resistant to azoxystrobin. The biological fitness of QoI-resistant (QoI^R) isolates was significantly lower than the sensitive isolates (QoI^S) in terms of mycelial growth and conidiation. Nucleotide sequence alignment of CgCytb genes from the QoI^R and QoI^S isolates revealed that two point mutations (F129L and G143A) are involved in the QoI resistance. Isolates with the G143A mutation expressed high resistance to azoxystrobin, whereas isolates carrying the F129L mutation exhibited moderate resistance. Positive cross-resistance was observed between azoxystrobin and kersoxim-methyl, pyraclostrobin, or benzothiostrobin, but not with fluazinam. This study provides important information for management of QoI^R populations of C. gloeosporioides in the field.     

Widespread distribution of resistance to triazole fungicides in Brazilian populations of the wheat blast pathogen

Fungicides have not been effective in controlling the wheat blast disease in Brazil. An earlier analysis of 179 isolates of Pyricularia oryzae Triticum lineage (PoTl) sampled from wheat fields across six populations in central-southern Brazil during 2012 discovered a high level of resistance to strobilurin fungicides. Here we analysed azole resistance in the same strains based on EC₅₀ measurements for tebuconazole and epoxiconazole. All six Brazilian populations of PoTl exhibited high resistance to both azoles, with in vitro EC₅₀ values that were at least 35 to 50 times higher than the recommended field doses. We sequenced the CYP51A and CYP51B genes to determine if they were likely to play a role in the observed azole resistance. Although we found five distinct haplotypes in PoTl carrying four nonsynonymous substitutions in CYP51A, none of these substitutions were correlated with elevated EC₅₀. CYP51B was sequenced for nine PoTl isolates, three each representing low, medium, and high tebuconazole EC₅₀. Both PoTl CYP51A and CYP51B could complement yeast CYP51 function. All PoTl CYP51A-expressing yeast transformants were less sensitive to triazoles than the PoTl CYP51B ones. Transformants expressing PoTl CYP51A haplotype H1 carrying the R158K substitution were not more resistant than those expressing PoTl CYP51A haplotype H5, which is synonymous to haplotype H6, found in triazole-sensitive P. oryzae Oryza isolates from rice blast. Therefore, the reduced triazole sensitivity of wheat blast isolates compared to rice blast isolates appears to be associated with a non-target-site related resistance mechanism acquired after higher exposure to triazoles.     

Sensitivity ofFusarium graminearum to fungicide JS399-19:In vitro determination of baseline sensitivity and the risk of developing fungicide resistance

The baseline sensitivity ofFusarium graminearum Schwade [teleomorph =Gibberella zeae (Schweinitz) Petch] to the fungicide JS399-19 (development code no.) [2-cyano-3-amino-3-phenylacrylic acetate] and the assessment of risk to JS399-19 resistancein vitro are presented. The mean EC₅₀ values for JS399-19 inhibiting mycelial growth of three populations of wild-typeF. graminearum isolates were 0.102±0.048, 0.113±0.035 and 0.110±0.036 μg ml⁻¹, respectively. Through UV irradiation and selection for resistance to the fungicide, we obtained a total of 76 resistant mutants derived from five wild-type isolates ofF. graminearum with an average frequency of 1.71 × 10⁻⁷% and 3.5%, respectively. These mutants could be divided into three categories of resistant phenotypes with low (LR), moderate (MR) and high (HR) level of resistance, determined by the EC₅₀ values of 1.5–15.0 μg ml⁻¹, 15.1–75.0 μg ml⁻¹ and more than 75.0 μg ml⁻¹, respectively. There was no positive cross-resistance between JS399-19 and fungicides belonging to other chemical classes, such as benzimidazoles, ergosterol biosynthesis inhibitors and strobilurins, suggesting that JS399-19 presumably has a new biochemical mode of action. Although the resistant mutants appeared to have comparable pathogenicity to their wild-type parental isolates, they showed decreased mycelial growth on potato-sucrose-agar plates and decreased sporulation capacity in mung bean broth. Nevertheless, most of the resistant mutants possessed fitness levels comparable to their parents and had MR or HR levels of resistance. As these studies yielded a high frequency of laboratory resistance inF. graminearum, appropriate precautions against resistance development in natural populations should be taken into account. http://www.phytoparasitica.org posting August 7, 2008.     

番茄灰霉病菌对咯菌腈的抗性诱变及抗药突变体的生物学特性

为评估番茄灰霉病菌Botrytis cinerea对咯菌腈的抗性风险,就室内经紫外照射获得抗药突变体的方法及抗性突变体的生物学性状进行了研究。结果表明:番茄灰霉病菌分生孢子的紫外照射亚致死时间为90~120 s;经亚致死时间紫外照射后,4个亲本菌株中有2个菌株共产生了6个抗咯菌腈的突变体,其EC50值是亲本菌株的310倍以上,抗性突变频率为3.13×10-7;经紫外照射诱变获得的所有抗性突变体在菌丝生长速率、产孢量、产菌核能力及其在番茄果实上的致病性方面均比其亲本菌株明显降低。相关分析显示,所得抗咯菌腈突变体对氟啶胺、啶菌唑、啶酰菌胺和嘧霉胺无交互抗性。表明番茄灰霉病菌对咯菌腈的抗药性风险较低。     

新疆MEAM1烟粉虱隐种对吡虫啉的抗性遗传力分析及交互抗性测定

采用Tabashnik的域性状指标分析了新疆MEAM1(Middle-East-Asia-Minor l)烟粉虱隐种对吡虫啉的抗性现实遗传力(h2)和不同致死率下的抗性发展速率,同时测定了抗性种群对不同类型杀虫剂的交互抗性。结果表明,在30%~50%较低的选择压力下,新疆MEAM1烟粉虱隐种连续汰选8代后,对吡虫啉的抗性上升28.01倍,抗性现实遗传力h2为0.429 7。假设田间种群现实遗传力为实验室筛选估算值的1/2,即h2=0.214 9,对新疆MEAM1烟粉虱隐种对吡虫啉的抗性发展速率估算结果表明:在药剂选择压力为50%~60%下,若使其对吡虫啉的抗性增长10倍,则需要生长10~8代;而在药剂选择压力为70%~90%下,若使其抗性增长10倍,则仅需要生长6~4代。表明新疆MEAM1烟粉虱隐种对吡虫啉产生抗性的风险很大。交互抗性测定结果显示:抗性种群对同类型的杀虫剂吡虫清和噻虫嗪分别产生了10.78倍和4.75倍的中等至低水平交互抗性;对多杀菌素、毒死蜱、吡丙醚和高效氯氰菊酯的敏感性有所降低;对阿维菌素、氟啶虫胺腈和乙基多杀菌素等杀虫剂则无交互抗性。     

烟粉虱对螺虫乙酯的抗性监测及交互抗性测定

为明确螺虫乙酯在湖北地区的抗性水平以及与其存在潜在交互抗性风险的常用药剂类型,采用着卵叶片浸渍法,于2013年对湖北省13个烟粉虱MEAM1和MED隐种地理种群对螺虫乙酯的抗药性进行了监测,并以室内敏感品系SUD-S为参照,对经螺虫乙酯连续17代抗性筛选的WH-2种群进行了交互抗性分析。结果表明:湖北省13个烟粉虱地理种群对螺虫乙酯均表现出极低的抗性,LC50介于0.015~0.081 mg/L之间;其中MED隐种WH-2种群对螺虫乙酯的抗性最高,LC50为0.081 mg/L。在室内用螺虫乙酯对MED隐种WH-2种群连续17代抗性筛选后,其对螺虫乙酯的抗性倍数上升约7倍。经螺虫乙酯筛选的WH-2种群对吡虫啉、乙酰甲胺磷、灭多威、氟氯氰菊酯、氰戊菊酯和氟啶虫胺腈均产生了低水平的交互抗性,抗性倍数分别为8.699、7.165、5.317、6.681、2.958、5.662倍,而对毒死蜱和阿维菌素无交互抗性。表明烟粉虱在湖北省部分地区对螺虫乙酯存在低水平抗性,且螺虫乙酯与部分常用杀虫剂存在交互抗性风险。