Phototactic behavior of Trialeurodes vaporariorum Westwood (Hemiptera: Aleyrodidae) under visible wavelengths

The greenhouse whitefly, Trialeurodes vaporariorum Westwood (Hemiptera: Aleyrodidae), is one of the most important pests of greenhouse crops. The intensive use of chemical insecticides has resulted in insecticide resistance in T. vaporariorum and the critical level of pesticides residue in crops. It is therefore necessary to develop new control methods based on ecological pest management. The present study was designed to control greenhouse whitefly by finding and using insect repellent wavelengths. The repellent wavelength experiment was conducted by a two-way phototactic apparatus given a choice between darkness and visible wavelength spectrum from violet (380–450 nm) to red (620–750 nm). The phototactic responses of the greenhouse whitefly were then investigated in a four-way phototactic apparatus given a choice between two light regimes, light-emitting diode (LED) and sunlight. The results indicated that the lowest (69.2%) and highest (97.8%) number of whiteflies were attracted to violet and orange (590–625 nm) spectra, respectively. In addition, the present study indicated a significant attraction of T. vaporariorum adults to sunlight compared with LED. Furthermore, the eggplants grown under growth LEDs showed a significantly higher growth rate than the plants grown under sunlight. These findings suggest that this type of LED not only has positive effects on plant growth but it also has a repellent activity on T. vaporariorum adults, leading us to develop an effective behavioral control of the greenhouse whitefly.     

锈赤扁谷盗成虫趋光行为研究

【目的】研究灯光诱捕技术防治锈赤扁谷盗Cryptolestes ferrugineus(Stephens)的可行性。【方法】在实验室条件下测定了锈赤扁谷盗成虫对不同光源的趋光反应。【结果】锈赤扁谷盗成虫对实验所选取的光源都有一定的趋性。在可见光中,对主波长为575 nm的光源的趋性最强,对430、495、620、530和450 nm光源的趋性依次降低。在紫外光中,对主波长为385 nm的光源的趋性显著高于对主波长为365、375和395 nm的光源;1~10日龄的锈赤扁谷盗成虫,随日龄的增加,成虫趋光性先增强后有所减弱;雌虫的趋光性高于雄虫,且交配状态会影响雌虫和雄虫的趋光性。交配会抑制雄虫的趋光性,但是交配后的雌虫的趋光性增强;短期饥饿处理和灯光经历对害虫趋光性无显著影响。【结论】锈赤扁谷盗成虫对光波长的选择偏好性证实了其灯光诱捕技术的可行性。     

Attractive Effects of American Serpentine Leafminer, Liriomyza trifolii (Burgess), to Light-Emitting Diodes

Phototactic responses of Liriomyza trifolii adults to six different light-emitting diodes (LEDs) were investigated, and their responses were compared to that using a luring lamp (BLB) under laboratory conditions. Based on the attraction rate under optimal light conditions, the green LED (520?±?5 nm) showed the highest attraction rate (99.7 %), followed by the yellow LED (590?±?5 nm, 96.1 %), the red LED (625?±?10 nm, 91.4 %), the blue LED (470?±?10 nm, 91.2 %), the UV LED (365 nm, 71.0 %), and the IR LED (730 nm, 5.6 %). Moreover, the green LED was approximately 1.4 times more attractive than BLB (71.1 %) to L. trifolii adults. These results suggest that the green LED was the most useful for monitoring of L. trifolii adults under optimal conditions.     

Evaluating the phototactic behavior responses of the diamondback moth,Plutella xylostella,to some different wavelength LED lights in laboratory and field

Light traps equipped with light emitting diodes (LEDs) have been applied to manage some phototactic insect pests. The diamondback moth, Plutella xylostella, is a cosmopolitan insect pest to be seriously harmful to many cruciferous plants. The present research focused on evaluating the phototactic behavior responses of the moths to several wavelengths and photon flux densities of LED lights under laboratory and field conditions. The results from the laboratory showed that the highest phototactic behavior responses of P. xylostella moths were recorded for UV (380 nm) LED light under 1.5 µmol m⁻² s⁻¹ and 2.5 µmol m⁻² s⁻¹. The moths were more attracted to light traps equipped with 4 LEDs and 6 LEDs of 380 nm, respectively, between 20:00 and 22:00 than the other groups and night times in the field. The finding from the field was consistent with the results from the laboratory. We found that the 380 nm LED light results in the strongest attraction rate of the moths by 92.4 % and the moths caught in light trap with the UV LEDs was 1.62 times more than that with a black light. These data clearly demonstrate that P. xylostella moths have a high sensitivity to 380 nm, therefore, a 380 nm LED light trap could be useful for monitoring and controlling the moths.     

Acquisition of Tomato yellow leaf curl virus enhances attraction of Bemisia tabaci to green light emitting diodes

The light sensitivity of insects varies in response to different wavelengths of light. The change of light responses of vector insects plays an important role in the method of transmission and propagation of plant viruses. Here, we investigated whether the light attraction behaviors of whiteflies are altered by virus acquisition. Firstly, the light attraction rates of whiteflies were determined using LED light bulbs exhibiting different wavelengths in the visible and UV spectra. Whiteflies, Bemisia tabaci and Trialeurodes vaporariorum, were mostly attracted to green LEDs (526 nm). The attraction rate to green LED light was higher in B. tabaci than in T. vaporariorum, whereas it did not significantly differ between the B- and Q-biotypes of B. tabaci. Secondly, we investigated whether or not the green light attraction behavior of B. tabaci is influenced by the acquisition of Tomato yellow leaf curl virus (TYLCV). The attraction rate to green LED light was 2.5–3 times higher in TYLCV-infected whiteflies than in TYLCV-free whiteflies. However, this difference disappeared when the distance from the light source was greater than 0.5 m. Our results show that B. tabaci favors green light and its attraction is highly enhanced by the acquisition of the plant virus, TYLCV.     

Which wavelength does the cigarette beetle, Lasioderma serricorne (Coleoptera: Anobiidae), prefer? Electrophysiological and behavioral studies using light-emitting diodes (LEDs)

The cigarette beetle, Lasioderma serricorne (Fabricius), is an important pest insect that consumes a variety of dry foods. It is known that UV light traps attract this species. However, less attention has been paid to its preferred wavelength. First, we investigated the spectral sensitivity of the compound eye. Next, we compared the attraction efficiency of LEDs of different colors (wavelengths). Our results showed that ultraviolet (UV, 375 nm) and blue (470 nm) LEDs attracted the most cigarette beetles of both sexes, irrespective of mating or oviposition status, although the UV LED consistently tended to attract the most beetles. Although the primary sensitivity peak of the compound eye was 520 nm, the green LED (520 nm) scarcely attracted beetles. Although the reason for the difference between the peaks in spectral sensitivity and attraction of beetles awaits further studies, whether UV and/or blue LEDs is more effective as a practical light trap for controlling L. serricorne beetle is discussed in this study.     

Mutagenic interaction between near-(365 nm) and far-(254 nm)ultraviolet radiation in repair-proficient and excision-deficient strains of Escherichia coli.

The mutational interaction between radiation at 365 and 254 nm was studied in various strains of E. coli by a mutant assay based on reversion to amino-acid independence in full nutrient conditions. In the two repair-proficient strains (K12 AB 1157 and B/r), pre-treatment with radiation at 365 nm strongly suppressed the induction of mutations by far-UV, a phenomenon accompanied by a strong lethal interaction. The frequency of mutations induced by far-UV progressively declined with increasing dose of near-UV. Far-UV-induced mutagenesis to T5 resistance was almost unaltered by pre-treatment with near-UV. In AB 1886 uvrA there was no lethal interaction between the two wavelengths but the mutagenic interaction was synergistic. This synergism was maximal at a 365-nm dose of 8 X 10(5) J m-2. It is proposed that in the wild-type strain, cells containing potentially mutagenic lesions are selectively eliminated from the population because of abortive excision of an error-prone repair-inducing signal. In excisionless strains, 365-nm radiation may be less damaging to the error-prone than to the error-free post-replication repair system. Alternatively, mutation may be enhanced because of the occurrence of error-prone repair of 365-nm lesions by a system that is not induced in the absence of 254-nm radiation.     

Spectroscopic parameters of the cuticle and ethanol extracts of the fluorescent cave isopod Mesoniscus graniger (Isopoda,Oniscidea)

The body surface of the terrestrial isopod Mesoniscus graniger (Frivaldsky, 1863) showed blue autofluorescence under UV light (330–385 nm), using epifluorescence microscopy and also in living individuals under a UV lamp with excitation light of 365 nm. Some morphological cuticular structures expressed a more intense autofluorescence than other body parts. For this reason, only the cuticle was analyzed. The parameters of autofluorescence were investigated using spectroscopic methods (molecular spectroscopy in infrared, ultraviolet-visible, fluorescence, and X-ray fluorescence spectroscopy) in samples of two subspecies of Mesoniscus graniger preserved in ethanol. Samples excited by UV light (from 350 to 380 nm) emitted blue light of wavelengths 419, 420, 441, 470 and 505 nm (solid phase) and 420, 435 and 463 (ethanol extract). The results showed that the autofluorescence observed from living individuals may be due to some β-carboline or coumarin derivatives, some crosslinking structures, dityrosine, or due to other compounds showing similar excitation-emission characteristics.     

Ultraviolet and violet light: attractive orientation cues for the Indian meal moth, Plodia interpunctella

The Indian meal moth (IMM), Plodia interpunctella (Hübner) (Lepidoptera: Pyralidae), engages in long-distance or foraging flights in the twilight hours of the scotophase when blue light dominates the irradiance spectrum of the sky. We tested the hypothesis that IMM uses wavelengths of visible blue/violet light as orientation cues that trigger phototactic responses. In four-choice laboratory experiments, blue light (400–475 nm) was significantly more effective than green (475–600 nm), orange (575–700 nm), or red (590–800 nm) light in attracting males and mated females. In subsequent experiments that tested light emitting diodes (LEDs) emitting peak wavelengths in the blue/violet-light range, the 405-nm 'violet' LED was significantly more effective than the 435-, 450-, or 470-nm 'blue' LED in attracting males as well as virgin and mated females. In electroretinogram recordings, the 405-nm wavelength elicited significantly stronger receptor potentials from female and male eyes than the 350-nm (UV) wavelength, and in a behavioral experiment it significantly enhanced the known attractiveness of UV light. Equal attraction of IMMs to 405-nm LEDs at 600–700 µW/cm² with or without UV light, and significantly stronger attraction to a 405-nm LED than to a 350-nm LED at maximum light intensities, suggest that the deployment of violet instead of UV light could become one of several management tactics for control of IMMs.     

Effectiveness of portable solar-powered light-emitting diode insect trap: Experimental investigation in a groundnut field

Pest control is a major challenging component in agricultural and horticultural crops. Recently, the light-emitting diode (LED) trap driven by solar energy is a growing eco-friendly technology in pest control. The study was aimed to design, fabricate and investigate the effectiveness of a portable solar-powered LED trap for monitoring insect pests. The trap is compressed into a photovoltaic panel, battery, LED array, solar rectifier, insect collection tray, and PVC legs. Four different coloured LEDs viz., ultraviolet (UV)-405 nm, blue-470 nm, green-525 nm and red-630 nm were studied. The study was conducted in a groundnut field during the autumn season for 15 days. The results showed that the UV LED trap captured significantly more insects than the blue, green, and red LED traps except for Helicoverpa armigera. The average attraction of Spodoptera litura, Aproaerema modicella, Amsacta albistriga, Scirtothrips dorsalis, Aphis craccivora, and Empoasca kerri population to UV LED trap was 77.17 ± 18.89, 64.67 ± 12.91, 39 ± 16.80, 43.33 ± 18.30, 38.33 ± 17.08 and 33.17 ± 10.94, respectively. The red LED trap captured the least number of insects; however, the attraction of A. albistriga to the red LED was higher than the blue and green LED traps. Arcsine transformation (AT) was applied to transform experimental trap efficiency. UV LED trap had a significantly higher AT value than other LED traps. Overall mean AT values for UV, green, blue, and red LED traps were 34.98, 31.06, 29.87 and 22.87, respectively. The proposed portable solar-assisted LED trap could be a promising and effective pest control tool in areas where inconsistent electricity supply.     

Effect of several factors on the phototactic response of the oriental armyworm, Mythimna separata (Lepidoptera: Noctuidae)

Recently, light traps equipped with light-emitting diode (LED) lights have been used to monitor and control nocturnal insect pests. The oriental armyworm, Mythimna separata Walker, is an important cosmopolitan agriculture pest. The phototactic responses of nocturnal insects, including moths are influenced by abiotic and biological factors. The present study aimed to evaluate the phototactic response to different wavelength LED lights to determine the wavelength to which M. separata adults are most sensitive, and then identify the effects of several factors on the phototactic response. Our experiments revealed that M. separata adult moths had a significantly higher attraction rate to the green (520?nm) LED light compared with other LED lights, the green LED light was 1.28 times more attractive the moths than the commercial double-wave light used as a control. The phototactic response of the adult moths was significantly influenced by several factors, including adaption time in darkness, age, mating status and sexuality. These findings suggest that using a green LED light as a light source in trap could be effective in monitoring or controlling M. separata moths. Our results may provide a theoretical and scientific basis for improving the light trap technique for M. separata moths.     

Permethrin resistance in Aedes aegypti (Linnaeus) collected from Kuala Lumpur,Malaysia

Permethrin resistance status of a laboratory strain, a permethrin-selected strain and three field strains of Aedes aegypti collected in Kuala Lumpur, Malaysia were evaluated using three standard laboratory bioassays: WHO larval bioassay, WHO adult mosquito bioassay, and mixed function oxidase (MFO) enzyme microassay. The LC₅₀ values of field strains from the WHO larval bioassay did not differ significantly. The highest LC₅₀ value was from the Taman Melati field strain (0.39 mg/L). The resistance ratio for the permethrin-selected strain and the field strains ranged from 1.86 fold to 5.57 fold. Pre-exposure to piperonyl butoxide (PBO) in the WHO adult bioassay and MFOs enzyme microassay reduced the LT₅₀ values and reduced the mean optical density of elevated oxidase activity (0.28–0.42) at 630 nm. The LC₅₀ or LT₅₀ values and the level of oxidases were significantly correlated (r = 0.825; p< 0.05). This study confirmed the presence of permethrin resistance in these mosquito populations.     

Evidence for photoenzymatically repairable, lethal "non-dimer" photoproducts, formed in E. coli cells by 365-nm radiation or by sunlight greater than 360 nm.

Three pairs of E. coli strains with different dark-repair potentials, viz. H/r30 and H/r30-R, H_s30 H_s30-R, CSR 603 and AB 2480, have been investigated for their survival after exposure to 254-nm and 365-nm radiation. Each pair consists of a non-photorepairable (phr^?) and a photorepairable (phr⁺) strain of otherwise identical or similar genotype. At 254 nm, the mean inactivation fluence (F_0.37) is for the dark-repair proficient phr^? strain (H/r30) 300–750 times greater than for the completely dark-repair deficient phr^tt- strain (CSR 603), but at 365 nm the F_0.37's differ by a factor of only 5–10. Comparison of survival curves of phr^? and phr⁺ strains indicates that, at all three levels of dark-repair potential, lethal damage resulting from 365-nm exposure is extensively photorepaired by the same wavelength. Qualitatively similar effects were observed with sunlight from which all wavelengths < 360 nm were filtered out. Furthermore, we have shown that fluences of 365-nm radiation used in our experiments do not damage the enzymatic dark-repair systems themselves. These results seem compatible with one another only if one assumes that photoenzymatic repair is capable of abolishing lethal DNA damage other than the common types of cyclobutane dipyrimidines occurring after 254-nm irradiation.     

Mutation induction by monochromatic 254-nm and 365-nm radiation in strains of Escherichia coli that differ in repair capability

Mutation to tryptophan independence after exposure to radiation at the monocrhomatic wavelengths of 254 and 365 nm was studied and compared in 7 strains of Escherichia coli B/r that differ in repair capability. Efficient mutation induction was obtained with both 254-nm and 365-nm radiation with strains WP2 (wild-type), WP2s (uvrA), WP6s (polA uvrA). Mutants were not induced at either wavelength in the lexA strain WP5 or the recA strains WP10 and WP100. These results support the induction of mutants with 365-nm radiation through the error-prone (SOS) pathway of postreplication repair. Log-log plots of tryptophan revertant data at 254 nm showed the expected slopes of approximately 2.0 over the entire influence range tested. In contrast, similar plots of revertant data at 365 nm were complex in all cases tested: at low fluence values (survival greater than 0.5) in all cases where reversion occurred the slopes were approximately 1.0, while at higher fluences (survival less than 0.5) the slopes of the log-log plots were approximately 3.0 with strains WP2s and WP6s, approximately 4.0 with strain WP6 and approximately 6.0 with strain WP2. Differential sensitivity of components of excision and postreplication repair systems to 365-nm radiation may account for the 2-part mutation curves obtained with uvr⁺ rec⁺ lex⁺ strains. It is proposed that efficient error-free repair of mutational lesions occurs at 365-nm fluences below 2–4×10⁵ J m²⁻; at greater 365-nm fluences, error-free excision repair may be selectively inhibited, forcing a greater fraction of mutational lesions to be processed by the error-prone component of the postreplication repair system. The similarity of the mutational responses of WP2s and WP6 at 365 nm supports the selective inhibition of error-free excision repair.     

Interactions between uv radiation of different energies in the inactivation of bacteria.

A strong lethal interaction was observed between various monochromatic wavelengths (254, 334, 365, and 405 nm) in the repair-proficient E. coli K-12 strain AB 1157, except in the case of preexposure to 405-nm radiation which resulted in a protection against the inactivation resulting from subsequent exposure to 365-or 254-nm radiations. The results may be tentatively explained by assuming two classes of DNA lesions and two classes of damage to repair (reversible and inrreversible) whose proportions vary according to wavelength.     

Isolation and Characterization of the Thylakoid Membranes from the NaCl-Resistant (NaClr) Mutant Strain of the Cyanobacterium Anabaena variabilis

NaCl-induced changes in the thylakoid membrane of wild-type Anabaena variabilis and its NaCl^r mutant strain have been studied. Biochemical characterization of the thylakoid membrane was done by taking its absorption and fluorescence spectra at different wavelength. The thylakoid membranes of both strains were isolated by mechanical disruption of the freeze-dried and lysozyme-treated cells, followed by differential and density gradient centrifugation. The light absorption spectra of the thylakoid membrane showed three and two peaks in NaCl^r mutant strain and its wild-type counterpart respectively at wavelengths of 400–850 nm. These peaks revealed that the thylakoid membrane contains a large amount of carotenoid and chlorophyll a. Fluorescence emission spectra of thylakoid membrane of NaCl^r mutant and its wild-type strain at excitation wavelength of 335 nm showed two different peaks, one at 340 nm and the other at 663 nm respectively. The light absorption and fluorescence spectra of the thylakoid membrane also revealed that the membrane contained carotenoid pigment, chlorophyll (Chl) a, and a pigment with an emission peak at 335 nm. The HPLC analysis of the pigments of the thylakoid membrane indicates that the NaCl^r mutant strain under NaCl stress contained an additional peak for the carotenoid pigment, which was lacking in its wild-type counterpart. The major peak in thylakoid membrane was that of echinenone and β-carotene. Whereas the polypeptide composition of thylakoid membrane differed in the wild-type and its NaCl^r mutant strain, no difference in the cell wall protein pattern was observed in both strains. The thylakoid membrane of NaCl^r mutant strain contained two additional protein bands that were absent in its wild-type counterpart. The thylakoid membrane of the wild-type and its NaCl^r mutant strain also showed morphological variations under NaCl stress. Received: 14 April 2000 / Accepted: 23 May 2000     

Blue–green opponency and trichromatic vision in the greenhouse whitefly (Trialeurodes vaporariorum) explored using light emitting diodes

Visual orientation in the greenhouse whitefly (Trialeurodes vaporariorum Westwood, Hemiptera: Aleyrodidae) is the result of “wavelength‐specific behaviours.” Green–yellow elicits “settling behaviour” while ultraviolet (UV) radiation initiates “migratory behaviour.” The only available physiological study of the photoreceptors' spectral efficiency showed peaks in the green and the UV range and whitefly vision was said to be dichromatic so far. In order to study the visual behaviour of T. vaporariorum, 19 narrow‐bandwidth light emitting diodes (LEDs) covering the UV‐A and visible range were used in combination with light scattering acrylic glass screens in a small‐scale choice arena under greenhouse conditions. Multiple‐choice and dual‐choice assays were performed, resulting in LED‐based behavioural action spectra of settling (green) and migratory behaviour (UV). A potential inhibitory blue–green chromatic mechanism was studied by combining yellow with different bluish LEDs. Intensity dependencies were illustrated by changing LED intensities. Regarding the “settling response,” highest attraction was achieved by a green LED with a centroid wavelength of 550 nm, while a blue LED with 469 nm proved to be most inhibitory. Besides this inhibitory interaction, an intensity dependence was observed within the action spectrum in the green–yellow range. “Migratory behaviour” was elicited the most by the UV LED with the shortest available wavelength of 373 nm. The results provide compelling behavioural evidence for the presence of a green and a yet undescribed blue sensitive photoreceptor and a blue–green opponent mechanism. Furthermore, empirical colour choice models were built and receptor peaks were estimated around 510–520 nm (green), 480–490 nm (blue) and 340–370 nm (UV). Consequently, a trichromatic receptor setup is suggested for T. vaporariorum.     

Light emitting diode(LED)‐based trapping of the greenhouse whitefly (Trialeurodes vaporariorum)

Visual traps like yellow sticky card traps are used for monitoring and control of the greenhouse whitefly (Trialeurodes vaporariorum). However, reflected intensity (brightness) and hence, attractiveness depend on the ambient light conditions, and the colour (wavelength) might not fit with the sensitivity of whitefly photoreceptors. The use of light emitting diodes (LEDs) is a promising approach to increase the attractiveness, specificity and adaptability of visual traps. We constructed LED‐based visual traps equipped with blue and green high‐power LEDs and ultraviolet (UV) standard LEDs according to the putative spectral sensitivities of the insects' photoreceptors. In a series of small‐scale choice and no‐choice recapture experiments, the factors time of day as well as light intensity and light quality (colour) of LED traps were studied in terms of attractiveness compared to yellow traps without LEDs. Green LED traps (517 nm peak wavelength) were comparably attractive in no‐choice experiments but clearly preferred over yellow traps in all choice experiments. The time of day had a clear effect on the flight activity of the whiteflies and thereby on the trapping success. Blue LEDs (474 nm) suppressed the attractiveness of the light traps when combined with green LEDs suggesting that a yet undetected photoreceptor, sensitive for blue light, and an inhibiting interaction with the green receptor, might exist in T. vaporariorum. In choice experiments between LED traps emitting green light only or in combination with UV (368 nm), the green‐UV combination was preferred. In no‐choice night‐time experiments, UV LEDs considerably increased whitefly flight activity and efficacy of trapping. Most likely, the reason for the modifying effect of UV is the stimulating influence on flight activity. In conclusion, it seems that the use of green LEDs alone or in combination with UV LEDs could be an innovative option for improving attractiveness of visual traps.     

Wavelength discrimination in the ‘visible’ and ultraviolet spectrum by pigeons

Summary Using operant conditioning methods, the pigeon's wavelength discrimination abilities were assessed in two experiments to generate discrimination functions. Both these functions showed three minima at 460, 530 and 595 nm. In the second wavelength discrimination experiment, extending measurements into the UV spectral region, pigeons also maintained good discrimination between wavelengths within the UV range tested. A fourth minimum was indicated at the lower end of the spectral range tested (365–385 nm). The results point to the complexity of the pigeon's chromatic system, which must be at least tetrachromatic, probably pentachromatic.Abbreviations S+ positive stimulus - S– negative stimulus We thank the technical staff of the Psychology Department at Durham University for their assistance and. in particular, Mr. D. Harper who collected some of the data in the second experiment. Mrs. C. Thompson gave us much helpful advice about the computer programming. The work was, in part, supported by an SRC Research Grant to J.D. Delius; J. Emmerton received a Durham University Research Studentship. The paper was prepared while the authors were supported by the Deutsche Forschungsgemeinschaft through its Sonderforschungsbereich 114.     

不同波长LED光源对韭菜迟眼蕈蚊生殖行为的影响

【目的】明确不同波长的LED光源对韭菜迟眼蕈蚊Bradysia odoriphaga Yang et Zhang求偶、交配及繁殖等生殖行为的影响。【方法】采用红(625~630 nm)、橙(600~605 nm)、黄(590~595nm)、绿(525~530 nm)、蓝(455~460 nm)和白(6 000~6 500 k)6种LED光源在韭菜迟眼蕈蚊成虫交配期进行照光处理,观察统计其求偶和交配行为以及单雌产卵量、卵孵化情况和有效后代数量。【结果】韭菜迟眼蕈蚊成虫求偶前期时长在橙光下最长,为28.48 min。求偶率在蓝光下最高,为86%;橙光下最低,为48%。交配期时长在蓝光下最长,为4.59 min;橙光下较短,为4.23 min。单雌产卵量在各波长光源下与对照均无显著差异。卵孵化率在蓝光下最低,仅为43.41%。有效后代数量在蓝光下最低,仅为27.00头;橙光下次之,为43.40头。【结论】LED光源的波长可影响韭菜迟眼蕈蚊的生殖行为,其中橙光(600~605 nm)不利于其求偶、交配和繁殖;蓝光(455~460nm)虽有利于其求偶和交配,但明显抑制其繁殖。