Explore the vast range of titles available.

Major latitudinal clines have been observed in Drosophila melanogaster, a human commensal that originated in tropical Africa and has subsequently dispersed globally to colonize temperate habitats. However, despite the crucial role pathogens play in species distribution, our understanding of how geographical factors influence disease susceptibility remains limited. This investigation explored the effects of latitudinal clines and biomes on disease resistance using the common fly pathogen Metarhizium anisopliae and 43 global Drosophila melanogaster populations. The findings revealed correlations between disease resistance and latitudinal gradients of sleep duration, temperature, and humidity. Although enhanced defenses may be driven by fungal diversity at tropical latitudes, the most disease‐resistant tropical males also showed the highest susceptibility to desiccation. This suggests potential trade‐offs between abiotic stress resistance, necessary for survival in temperate habitats, and disease resistance. Furthermore, the study uncovered interactions between sex, mating status, sleep, and abiotic stresses, affecting disease resistance. Notably, longer‐sleeping males and virgin flies survived infections longer, with additional daytime sleep post‐infection being protective, particularly in the most resistant fly lines. These observations support the hypothesis that sleep and disease defense are intertwined traits linked to organismal fitness and subject to joint clinal evolution. We examined how environmental and genetic factors influence the ability of Drosophila melanogaster populations to defend themselves against a common fly pathogen. Tropical flies, particularly males and virgins (of either sex) slept more and were more resistant to disease than seasonal populations, indicating that geographical location, sex, mating status, and sleep interact to influence disease resistance. This research addresses themes of species adaptations in diverse ecological settings, the evolution of host‐pathogen interactions, and how closely related individuals exposed to the same infection can have different outcomes.

The evolution of insecticide resistance in mosquitoes is threatening the effectiveness and sustainability of malaria control programs in various parts of the world. Through their unique mode of action, entomopathogenic fungi provide promising alternatives to chemical control. However, potential interactions between fungal infection and insecticide resistance, such as cross-resistance, have not been investigated. We show that insecticide-resistant Anopheles mosquitoes remain susceptible to infection with the fungus Beauveria bassiana. Four different mosquito strains with high resistance levels against pyrethroids, organochlorines, or carbamates were equally susceptible to B. bassiana infection as their baseline counterparts, showing significantly reduced mosquito survival. Moreover, fungal infection reduced the expression of resistance to the key public health insecticides permethrin and dichlorodiphenyltrichloroethane. Mosquitoes preinfected with B. bassiana or Metarhizium anisopliae showed a significant increase in mortality after insecticide exposure compared with uninfected control mosquitoes. Our results show a high potential utility of fungal biopesticides for complementing existing vector control measures and provide products for use in resistance management strategies.

Increasing incidences of insecticide resistance in malaria vectors are threatening the sustainable use of contemporary chemical vector control measures. Fungal entomopathogens provide a possible additional tool for the control of insecticide-resistant malaria mosquitoes. This study investigated the compatibility of the pyrethroid insecticide permethrin and two mosquito-pathogenic fungi, Beauveria bassiana and Metarhizium anisopliae, against a laboratory colony and field population of West African insecticide-resistant Anopheles gambiae s.s. mosquitoes. A range of fungus-insecticide combinations was used to test effects of timing and sequence of exposure. Both the laboratory-reared and field-collected mosquitoes were highly resistant to permethrin but susceptible to B. bassiana and M. anisopliae infection, inducing 100% mortality within nine days. Combinations of insecticide and fungus showed synergistic effects on mosquito survival. Fungal infection increased permethrin-induced mortality rates in wild An. gambiae s.s. mosquitoes and reciprocally, exposure to permethrin increased subsequent fungal-induced mortality rates in both colonies. Simultaneous co-exposure induced the highest mortality; up to 70.3+/-2% for a combined Beauveria and permethrin exposure within a time range of one gonotrophic cycle (4 days). Combining fungi and permethrin induced a higher impact on mosquito survival than the use of these control agents alone. The observed synergism in efficacy shows the potential for integrated fungus-insecticide control measures to dramatically reduce malaria transmission and enable control at more moderate levels of coverage even in areas where insecticide resistance has rendered pyrethroids essentially ineffective.

Arthropod vectors are responsible for a multitude of human and animal diseases affecting poor communities in sub-Saharan Africa. Their control still relies on chemical agents, despite growing evidence of insecticide resistance and environmental health concerns. Biorational agents, such as the entomopathogenic fungus Metarhizium anisopliae, might be an alternative for vector control. Recently, the M. anisopliae isolate ICIPE 7 has been developed into a commercial product in Kenya for control of ticks on cattle. We were interested in assessing the potential of controlling not only ticks but also disease-transmitting mosquitoes and tsetse flies using cattle as blood hosts, with the aim of developing a product for integrated vector management. Laboratory bioassays were carried out with M. anisopliae, isolate ICIPE 7 and isolate ICIPE 30, to compare efficacy against laboratory-reared Anopheles arabiensis. ICIPE 7 was further tested against wild Glossina fuscipes and Rhipicephalus spp. Dose–response tests were implemented, period of mosquito exposure was evaluated for effects on time to death, and the number of spores attached to exposed vectors was assessed. Exposure to 109 spores/mL of ICIPE 7 for 10 min resulted in a similar mortality of An. arabiensis as exposure to ICIPE 30, albeit at a slower rate (12 vs. 8 days). The same ICIPE 7 concentration also resulted in mortalities of tsetse flies (LT50: 16 days), tick nymphs (LT50: 11 days), and adult ticks (LT50: 20 days). Mosquito mortality was dose-dependent, with decreasing LT50 of 8 days at a concentration of 106 spores/mL to 6 days at 1010 spores/mL. Exposure period did not modulate the outcome, 1 min of exposure still resulted in mortality, and spore attachment to vectors was dose-dependent. The laboratory bioassays confirmed that ICIPE 7 has the potential to infect and cause mortality to the three exposed arthropods, though at slower rate, thus requiring further validation under field conditions.

Indiscriminate use of synthetic pesticides by the brinjal growers in Assam has become a threat to biodiversity and consumer health. To find out the organic solution for managing brinjal pests, the efficacy of two entomopathogenic fungi (@1X10 8 spores/ml of water) was tested against naturally infested brinjal pests. The results revealed that Metarhizium anisopliae was more efficient in reducing the population of sucking pests like aphids (64.87%), jassids (57.74%), and white flies (63.80%). Meanwhile, Beauveria bassiana was found to be more effective against hadda beetle, reducing the population by 67.16% and also superior in reducing brinjal shoot and fruit borer infestations (percentage of shoot infestation = 9.34, percentage of fruit infestation by number = 11.73 and percentage of fruit infestation by weight = 14.32) . Based on our earlier experimental result of dual culture assays against brinjal pathogens and compatibility tests among the biocontrol agents, a liquid consortial formulation with three best compatible biocontrol agents namely, Trichoderma harzianum, B. bassiana and M. anisopliae was prepared. A further field experiment was conducted at Assam Agricultural University, Jorhat and Krishi Vigyan Kendra, Barpeta, Assam to test the efficacy of six different Integrated Pests and Disease Management (IPDM) modules with the prepared consortia. The study showed that module-6 (seed treatment + seed bed treatment in nursery + soil application in main field + seedling dip treatment with consortia of biofertilizer, Rhizobium sp, Azotobacter sp strain 52, Azospirillum sp strain 71 and Bacillus sp strain 5 W + spraying of consortia) was the best for managing pests (aphid, jassid, hadda beetle and brinjal shoot and fruit borer) of brinjal.

Background In recent years, Microtermes obesi (Holmgren) (Blattodea: Termitidae) has been recorded as a major pest of tea crop, causes significant losses in production. Managing termite pests in tea crops through an integrated approach has been suggested, and the use of microbial biocontrol agent is one of the economical methods. The present study evaluated the pathogenic efficacy of an entomopathogenic fungus Metarhizium anisopliae s.l. ( =  M. anisopliae) against M. obesi damaging tea plants under field conditions. Results Metarhizium anisopliae s.l. was formulated as 5% aqueous suspension (AS). Large-scale field trials with formulated entomopathogen revealed that 1000 and 1200 ml concentrations of M. anisopliae s.l. 5%AS (each concentration containing 2 × 10 7 conidia/ml) each in 400 l of water/ha significantly ( P  < 0.05) reduced the population of M. obesi in tea gardens at Dooars and Darjeeling regions, India. In the field study, M. anisopliae s.l. was more effective than the standard insecticide and was non-pathogenic on the beneficial insects present in the tea gardens. In addition, M. anisopliae s.l. 5%AS had no phytotoxic effect on the tea leaves, with acceptable organoleptic attributes. Conclusion Metarhizium anisopliae s.l. isolate can be commercialized as an alternative natural termiticide to reduce the load of synthetic insecticides in the tea crop.

Entomopathogenic fungi Metarhizium anisopliae and Beauveria bassiana isolates have been shown to infect and reduce the survival of mosquito vectors. Methods Here four different bioassays were conducted to study the effect of conidia concentration, co-formulation, exposure time and persistence of the isolates M. anisopliae ICIPE-30 and B. bassiana I93-925 on infection and survival rates of female Anopheles gambiae sensu stricto. Test concentrations and exposure times ranged between 1 × 107 - 4 × 1010 conidia m-2 and 15 min - 6 h. In co-formulations, 2 × 1010 conidia m-2 of both fungus isolates were mixed at ratios of 4:1, 2:1, 1:1,1:0, 0:1, 1:2 and 1:4. To determine persistence, mosquitoes were exposed to surfaces treated 1, 14 or 28 d previously, with conidia concentrations of 2 × 109, 2 × 1010 or 4 × 1010. Results Mosquito survival varied with conidia concentration; 2 × 1010 conidia m-2 was the concentration above which no further reductions in survival were detectable for both isolates of fungus. The survival of mosquitoes exposed to single and co-formulated treatments was similar and no synergistic or additive effects were observed. Mosquitoes were infected within 30 min and longer exposure times did not result in a more rapid killing effect. Fifteen min exposure still achieved considerable mortality rates (100% mortality by 14 d) of mosquitoes, but at lower speed than with 30 min exposure (100% mortality by 9 d). Conidia remained infective up to 28 d post-application but higher concentrations did not increase persistence. Conclusion Both fungus isolates are effective and persistent at low concentrations and short exposure times.

Although Turkey is the first among all hazelnut-producing countries, yield per unit area of this crop is low in comparison to other countries, mainly because many insect species seriously damage hazelnut trees and their fruit. To find effective and safe biocontrol agents, we conducted a survey study to isolate entomopathogenic fungi from the hazelnut-growing region of Turkey and characterized the isolated strains in detail. In addition, we determined the effectiveness of seven selected strains from this region against Melolontha melolontha (Coleoptera: Scarabaeidae) which is one of the most serious pests of hazelnut. In 2006 and 2007, 301 soil samples were collected randomly and analyzed for presence of entomopathogenic fungi using the Galleria bait method. Entomopathogenic fungi were found to occur in 20.59% of the soil samples studied. Based on morphology, ITS sequence and partial sequencing of the 18S (SSU rDNA) and EF1-α genes, the isolates were identified as Metarhizium anisopliae var. anisopliae, Metarhizium sp., Beauveria bassiana, Beauveria cf. bassiana, Isaria fumosorosea and Evlachovaea sp. Metarhizium anisopliae var. anisopliae was isolated from 34 sites and was the most frequent and abundant entomopathogenic species recovered. All the isolates tested were pathogenic to M. melolontha. M. anisopliae var. anisopliae KTU-27 and Evlachovaea sp. KTU-36 produced the highest insecticidal activity (86.6%) within 15 days after inoculation. Our results suggest that entomopathogenic fungi could be good biocontrol agents against M. melolontha, and are discussed with respect to ecology of fungi in relation to habitat in order to evaluate biocontrol potential of these isolates. This is the first study of the distribution of entomopathogenic fungi in the hazelnut-growing region of Turkey and of their pathogenicities against M. melolontha.

We investigated aspects of resistance to entomopathogenic fungi in the social insect Solenopsis invicta, the red imported fire ant (RIFA). RIFA reared individually were significantly more susceptible to the entomopathogenic fungi Metarhizium anisopliae var. anisopliae M09 than reared in groups. Fungus exposed ants performed more self-grooming behavior when isolated as individuals and received more allo-grooming when accompanied with four healthy nestmates. Using fluorescence microscopy, we counted the number of fluorescein isothiocyanate (FITC)-labeled conidia on the cuticle of fungus exposed ants reared individually or as groups. The number of conidia on the surface of grouped ants decreased more rapidly than on isolated individuals. Allo-grooming behavior appears to be important in removing the conidia on the surface of RIFA. Individuals help fungus exposed ants by performing intensive grooming behaviors, which either risk infecting themselves or get them immunized as social immunity. We show evidence that contacting with fungus exposed ants would decrease susceptibility of nestmates to the fungus. All these results indicate that RIFA benefit from grooming behavior to fight against the fungal pathogens. Future advances in biological control of RIFA with entomopathogenic fungi are also discussed.

The rhizosphere microbiome is a critical regulator of nutrient acquisition and plant growth in citrus. Here, we evaluated the effects of the entomopathogenic fungus Metarhizium anisopliae CQMa421 on soil nutrient status, rhizosphere bacterial community structure, and fruit quality in citrus using soil physicochemical assays, plant physiological measurements, and 16S rRNA amplicon high-throughput sequencing. CQMa421 application markedly reshaped soil properties, increasing available potassium by 128.50% and organic matter by 75.05%. In addition, total nitrogen, alkali-hydrolyzable nitrogen, and available phosphorus increased by 112.68%, 155.30%, 305.74% respectively, while soil pH decreased by 0.4 units. CQMa421 treatment significantly increased leaf total nitrogen content and elevated fruit vitamin C by 12.00%. Microbial community profiling showed an enrichment of putatively beneficial taxa, including Proteobacteria and Firmicutes, in treated soils. Functional prediction suggested enhanced nutrient cycling potential, with increased representation of genes associated with carbohydrate metabolism and inorganic ion transport. Collectively, these results indicate that M. anisopliae CQMa421 acts as a plant growth-promoting fungus by enhancing soil nutrient availability and restructuring the rhizosphere microbiome, thereby improving the overall nutrient status of the soil and enhancing citrus fruit quality.