Your search keyword '"Priyadarshini Chakrabarti"' showing total 14 results

1. Honey Bee Nutrition

Author

Jennifer M. Tsuruda, Priyadarshini Chakrabarti, and Ramesh R. Sagili

Subjects

Forage (honey bee), business.industry, Foraging, Nutritional Status, General Medicine, Honey bee, Bees, Biology, Diet, Honey Bees, Food Animals, Agronomy, Optimal nutrition, Dietary Supplements, Animals, Livestock, business, Cropping

Abstract

Optimal nutrition is crucial for honey bee colony growth and robust immune systems. Honey bee nutrition is complex and depends on the floral composition of the landscape. Foraging behavior of honey bees depends on both colony environment and external environment. There are significant gaps in knowledge regarding honey bee nutrition, and hence no optimal diet is available for honey bees, as there is for other livestock. In this review, we discuss (1) foraging behavior of honey bees, (2) nutritional needs, (3) nutritional supplements used by beekeepers, (4) probiotics, and (5) supplemental forage and efforts integrating floral diversity into cropping systems.

Published

2021

2. Honey Bee (Hymenoptera: Apidae) Nursing Responses to Cuticular Cues Emanating from Short-term Changes in Larval Rearing Environment

Author

Ramesh R. Sagili, Bradley N. Metz, and Priyadarshini Chakrabarti

Subjects

AcademicSubjects/SCI01382, animal structures, gas chromatography, Foraging, Social Structure, Hymenoptera, Pheromones, pheromone, Nursing, nursing, honey bee, Animals, Research Articles, Larva, Appetitive Behavior, biology, Apidae, fungi, Special Collection: Honey Bee Research in the United States: Investigating Fundamental and Applied Aspects of Honey Bee Biology, Part I, General Medicine, Honey bee, larval nutrition, Bees, biology.organism_classification, Brood, Insect Science, Sex pheromone, Pheromone, Cues

Abstract

Honey bee larvae are dependent on the social structure of colony for their provisioning and survival. With thousands of larvae being managed collectively by groups of foragers (collecting food resources) and nurse bees (processing food and provisioning larvae), coordination of colony efforts in rearing brood depends on multiple dynamic cues of larval presence and needs. Much of these cues appear to be chemical, with larvae producing multiple pheromones, major being brood ester pheromone (BEP; nonvolatile blend of fatty acid esters) that elicits both short-term releaser effects and long-term primer effects. While BEP can affect colony food collection and processing with the signaling of larval presence, it is unclear if BEP signals individual larval needs. To understand this aspect, in a series of experiments we manipulated larval feeding environment by depriving larvae from adult bee contact for 4-h period and examined (1) nurse bee interactions with contact-deprived and nondeprived larvae and larval extracts; (2) forager bee responses to contact-deprived and nondeprived larval extracts. We also characterized BEP of contact-deprived and nondeprived larvae. We found that nurse honey bees tend to aggregate more over contact-deprived larvae when compared with nondeprived larvae, but that these effects were not found in response to whole hexane extracts. Our analytical results suggest that BEP components changed in both quantity and quality over short period of contact deprivation. These changes affected foraging behavior, but did not appear to directly affect nursing behavior, suggesting that different chemical cues are involved in regulating nursing effort to individual larvae.

Published

2021

3. Collection and Identification of Pollen from Honey Bee Colonies

Author

Priyadarshini Chakrabarti, Ellen Topitzhofer, Ramesh R. Sagili, Hannah M Lucas, and Emily A Carlson

Subjects

Palynology, Beekeeping, Forage (honey bee), Staining and Labeling, Pollination, General Immunology and Microbiology, General Chemical Engineering, General Neuroscience, Foraging, Honey bee, Bees, Biology, medicine.disease_cause, General Biochemistry, Genetics and Molecular Biology, Specimen Handling, Pollinator, Pollen, Botany, medicine, Animals, Acetic Acid

Abstract

Researchers often collect and analyze corbicular pollen from honey bees to identify the plant sources on which they forage for pollen or to estimate pesticide exposure of bees via pollen. Described herein is an effective pollen-trapping method for collecting corbicular pollen from honey bees returning to their hives. This collection method results in large quantities of corbicular pollen that can be used for research purposes. Honey bees collect pollen from many plant species, but typically visit one species during each collection trip. Therefore, each corbicular pollen pellet predominantly represents one plant species, and each pollen pellet can be described by color. This allows the sorting of samples of corbicular pollen by color to segregate plant sources. Researchers can further classify corbicular pollen by analyzing the morphology of acetolyzed pollen grains for taxonomic identification. These methods are commonly used in studies related to pollinators such as pollination efficiency, pollinator foraging dynamics, diet quality, and diversity. Detailed methodologies are presented for collecting corbicular pollen using pollen traps, sorting pollen by color, and acetolyzing pollen grains. Also presented are results pertaining to the frequency of pellet colors and taxa of corbicular pollen collected from honey bees in five different cropping systems.

Published

2021

4. Impacts of Different Winter Storage Conditions on the Physiology of Diutinus Honey Bees (Hymenoptera: Apidae)

Author

Walter S. Sheppard, Priyadarshini Chakrabarti, Brandon K. Hopkins, Ramesh R. Sagili, and Hannah M Lucas

Subjects

0106 biological sciences, 0301 basic medicine, Beekeeping, Forage (honey bee), Ecology, Apidae, biology, Physiology, General Medicine, Hymenoptera, Honey bee, Bees, biology.organism_classification, 01 natural sciences, Brood, 010602 entomology, 03 medical and health sciences, 030104 developmental biology, Pollinator, Insect Science, Animals, Seasons, Overwintering

Abstract

Global decline in insect pollinators, especially bees, have resulted in extensive research into understanding the various causative factors and formulating mitigative strategies. For commercial beekeepers in the United States, overwintering honey bee colony losses are significant, requiring tactics to overwinter bees in conditions designed to minimize such losses. This is especially important as overwintered honey bees are responsible for colony expansion each spring, and overwintered bees must survive in sufficient numbers to nurse the spring brood and forage until the new ‘replacement’ workers become fully functional. In this study, we examined the physiology of overwintered (diutinus) bees following various overwintering storage conditions. Important physiological markers, i.e., head proteins and abdominal lipid contents were higher in honey bees that overwintered in controlled indoor storage facilities, compared with bees held outdoors through the winter months. Our findings provide new insights into the physiology of honey bees overwintered in indoor and outdoor environments and have implications for improved beekeeping management.

Published

2020

5. Colony-level pesticide exposure affects honey bee (Apis mellifera L.) royal jelly production and nutritional composition

Author

David R. Tarpy, Ramesh R. Sagili, Priyadarshini Chakrabarti, and Joseph P. Milone

Subjects

Environmental Engineering, food.ingredient, Health, Toxicology and Mutagenesis, Nutritional composition, education, 0208 environmental biotechnology, 02 engineering and technology, Nutritional quality, 010501 environmental sciences, Biology, 01 natural sciences, Toxicology, Honey Bees, food, Royal jelly, Environmental Chemistry, Animals, Pesticides, 0105 earth and related environmental sciences, Developmental nutrition, fungi, Fatty Acids, Public Health, Environmental and Occupational Health, General Medicine, General Chemistry, Honey bee, Pesticide, Bees, Pollution, 020801 environmental engineering, Larva, behavior and behavior mechanisms, Social consequence, Pollen

Abstract

Honey bees provision glandular secretions in the form of royal jelly as larval nourishment to developing queens. Exposure to chemicals and nutritional conditions can influence queen development and thus impact colony fitness. Previous research reports that royal jelly remains pesticide-free during colony-level exposure and that chemical residues are buffered by the nurse bees. However, the impacts of pesticides can also manifest in quality and quantity of royal jelly produced by nurse bees. Here, we tested how colony exposure to a multi-pesticide pollen treatment influences the amount of royal jelly provisioned per queen and the additional impacts on royal jelly nutritional quality. We observed differences in the metabolome, proteome, and phytosterol compositions of royal jelly synthesized by nurse bees from multi-pesticide exposed colonies, including significant reductions of key nutrients such as 24-methylenecholesterol, major royal jelly proteins, and 10-hydroxy-2-decenoic acid. Additionally, quantity of royal jelly provisioned per queen was lower in colonies exposed to pesticides, but this effect was colony-dependent. Pesticide treatment had a greater impact on royal jelly nutritional composition than the weight of royal jelly provisioned per queen cell. These novel findings highlight the indirect effects of pesticide exposure on queen developmental nutrition and allude to social consequences of nurse bee glandular degeneration.

Published

2020

6. Novel Insights into Dietary Phytosterol Utilization and Its Fate in Honey Bees (Apis mellifera L.)

Author

Ramesh R. Sagili, Priyadarshini Chakrabarti, and Hannah M Lucas

Subjects

0106 biological sciences, media_common.quotation_subject, Population, Pharmaceutical Science, Insect, 010603 evolutionary biology, 01 natural sciences, complex mixtures, Article, honey bee nutrition, 24-methylenecholesterol, Analytical Chemistry, lcsh:QD241-441, Nutrient, isotopomer, lcsh:Organic chemistry, Drug Discovery, Animals, Food science, Physical and Theoretical Chemistry, education, insect physiology, media_common, phytosterol, education.field_of_study, biology, Phytosterol, Organic Chemistry, fungi, Insect physiology, Phytosterols, food and beverages, Honey bee, Feeding Behavior, Bees, biology.organism_classification, Lipid Metabolism, Animal Feed, Sterol, Brood, Survival Rate, 010602 entomology, Chemistry (miscellaneous), behavior and behavior mechanisms, Molecular Medicine, Insect Proteins, Animal Nutritional Physiological Phenomena, endogenous sterol replacement

Abstract

Poor nutrition is an important factor in global bee population declines. A significant gap in knowledge persists regarding the role of various nutrients (especially micronutrients) in honey bees. Sterols are essential micronutrients in insect diets and play a physiologically vital role as precursors of important molting hormones and building blocks of cellular membranes. Sterol requirements and metabolism in honey bees are poorly understood. Among all pollen sterols, 24-methylenecholesterol is considered the key phytosterol required by honey bees. Nurse bees assimilate this sterol from dietary sources and store it in their tissues as endogenous sterol, to be transferred to the growing larvae through brood food. This study examined the duration of replacement of such endogenous sterols in honey bees. The dietary 13C-labeled isotopomer of 24-methylenecholesterol added to artificial bee diet showed differential, progressive in vivo assimilation across various honey bee tissues. Significantly higher survival, diet consumption, head protein content and abdominal lipid content were observed in the dietary sterol-supplemented group than in the control group. These findings provide novel insights into phytosterol utilization and temporal pattern of endogenous 24-methylenecholesterol replacement in honey bees.

Published

2020

7. Potential Risk to Pollinators from Nanotechnology-Based Pesticides

Author

Stacey L. Harper, Bryan J. Harper, Ramesh R. Sagili, Louisa A. Hooven, and Priyadarshini Chakrabarti

Subjects

Exposure potential, Pharmaceutical Science, Environmental pollution, Nanotechnology, Review, 010501 environmental sciences, Biology, 01 natural sciences, Analytical Chemistry, 03 medical and health sciences, Honey Bees, Pollinator, Drug Discovery, Animals, Humans, Physical and Theoretical Chemistry, Pesticides, Pollination, 030304 developmental biology, 0105 earth and related environmental sciences, Nanotechnology-based particles, 0303 health sciences, Potential risk, Pollinators, Organic Chemistry, Pesticide, Bees, Multiple factors, Chemistry (miscellaneous), Molecular Medicine, Pollen, Particulate matter

Abstract

The decline in populations of insect pollinators is a global concern. While multiple factors are implicated, there is uncertainty surrounding the contribution of certain groups of pesticides to losses in wild and managed bees. Nanotechnology-based pesticides (NBPs) are formulations based on multiple particle sizes and types. By packaging active ingredients in engineered particles, NBPs offer many benefits and novel functions, but may also exhibit different properties in the environment when compared with older pesticide formulations. These new properties raise questions about the environmental disposition and fate of NBPs and their exposure to pollinators. Pollinators such as honey bees have evolved structural adaptations to collect pollen, but also inadvertently gather other types of environmental particles which may accumulate in hive materials. Knowledge of the interaction between pollinators, NBPs, and other types of particles is needed to better understand their exposure to pesticides, and essential for characterizing risk from diverse environmental contaminants. The present review discusses the properties, benefits and types of nanotechnology-based pesticides, the propensity of bees to collect such particles and potential impacts on bee pollinators.

Published

2019

8. The omics approach to bee nutritional landscape

Author

Ramesh R. Sagili, Hannah M Lucas, Claudia S. Maier, Jeffery T. Morré, and Priyadarshini Chakrabarti

Subjects

0106 biological sciences, Endocrinology, Diabetes and Metabolism, Clinical Biochemistry, Biology, medicine.disease_cause, 01 natural sciences, Biochemistry, Crop, 03 medical and health sciences, Nutrient, Pollinator, Pollen, medicine, Animals, Metabolomics, Bee nutrition, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, business.industry, fungi, Phytosterols, Honey bee, Bees, Pesticide, medicine.disease, Brood, Diet, Biotechnology, 010602 entomology, Malnutrition, Original Article, Vegetable oils, Crop pollens, business, Protein supplements

Abstract

Background Significant annual honey bee colony losses have been reported in the USA and across the world over the past years. Malnutrition is one among several causative factors for such declines. Optimal nutrition serves as the first line of defense against multiple stressors such as parasites/pathogens and pesticides. Given the importance of nutrition, it is imperative to understand bee nutrition holistically, identifying dietary sources that may fulfill bee nutritional needs. Pollen is the primary source of protein for bees and is critical for brood rearing and colony growth. Currently, there is significant gap in knowledge regarding the chemical and nutritional composition of pollen. Methods Targeted sterol analysis and untargeted metabolomics were conducted on five commercially available crop pollens, three bee-collected crop pollens, three vegetable oils (often added to artificial protein supplements by beekeepers), and one commonly used artificial protein supplement. Results This study reports key phytosterols and metabolites present across a spectrum of bee diets, including some of the major bee-pollinated crop pollens in the western United States. Significant differences were observed in sterol concentrations among the dietary sources tested. Among all quantified sterols, the highest concentrations were observed for 24-methylenecholesterol and further, pollen samples exhibited the highest 24-methylenecholesterol among all diet sources that were tested. Also, 236 metabolites were identified across all dietary sources examined. Conclusion Information gleaned from this study is crucial in understanding the nutritional landscape available to all bee pollinators and may further assist in future efforts to develop comprehensive database of nutrients and metabolites present in all bee diets.

Published

2019

9. Pesticide induced visual abnormalities in Asian honey bees (Apis cerana L.) in intensive agricultural landscapes

Author

Parthiba Basu, Sagartirtha Sarkar, and Priyadarshini Chakrabarti

Subjects

Rhodopsin, Environmental Engineering, Health, Toxicology and Mutagenesis, 0208 environmental biotechnology, Visual Acuity, Zoology, 02 engineering and technology, 010501 environmental sciences, Biology, Eye, 01 natural sciences, Honey Bees, Environmental Chemistry, Animals, Eye Abnormalities, Pesticides, Apis cerana, 0105 earth and related environmental sciences, Visual abnormalities, Opsins, Public Health, Environmental and Occupational Health, Agriculture, General Medicine, General Chemistry, Pesticide, Bees, biology.organism_classification, Pollution, 020801 environmental engineering, Agricultural intensification, Microscopy, Electron, Scanning, Agricultural landscapes

Abstract

Pesticide stress is one of the important factors for global bee declines. Apart from physiological and developmental anomalies, pesticides also impose cognitive damages on bees. The present study investigates the visual acuity of wild populations of honey bees, in an agricultural intensification landscape, and corroborates the findings with controlled laboratory experiments. Even though overall morphometric examinations revealed no significant differences between the populations, correct color choices by bees in pesticide exposed populations were significantly reduced. The study reports, for the first time, the significant reduction in ommatidia facet diameter in these populations, as viewed under scanning electron microscope, along with the molecular underpinnings to these findings. Western blot studies revealed a significant reduction in expression of two visual proteins – blue-sensitive opsin and rhodopsin – in the pesticide exposed populations in both field and laboratory conditions. The novel findings from this study form the basis for further investigations into the effects of field realistic doses of multiple pesticide exposures on wild populations of honey bees.

Published

2019

10. Assessment of Pollen Diversity Available to Honey Bees (Hymenoptera: Apidae) in Major Cropping Systems During Pollination in the Western United States

Author

Ellen Topitzhofer, Ramesh R. Sagili, Carolyn R. Breece, Vaughn M. Bryant, Hannah M Lucas, and Priyadarshini Chakrabarti

Subjects

0106 biological sciences, Crops, Agricultural, honey bees, Forage (honey bee), Pollination, Hymenoptera, medicine.disease_cause, 01 natural sciences, Crop, crop pollination, 03 medical and health sciences, Pollen, medicine, Animals, Apiculture and Social Insects, pollen diversity, 030304 developmental biology, 0303 health sciences, Ecology, Apidae, biology, pollen abundance, Agriculture, General Medicine, Honey bee, Bees, biology.organism_classification, United States, Western honey bee, 010602 entomology, Agronomy, Insect Science

Abstract

Global western honey bee, Apis mellifera (L.) (Hymenoptera: Apidae), colony declines pose a significant threat to food production worldwide. Poor nutrition resulting from habitat loss, extensive monocultures, and agricultural intensification is among the several suggested drivers for colony declines. Pollen is the primary source of protein for honey bees; therefore, both pollen abundance and diversity are critical for colony growth and survival. Many cropping systems that employ honey bee colonies for pollination may lack sufficient pollen diversity and abundance to provide optimal bee nutrition. In this observational study, we documented the diversity and relative abundance of pollen collected by honey bees in five major pollinator-dependent crops in the western United States. We sampled pollen from pollen traps installed on honey bee colonies in the following cropping systems—almond, cherry, highbush blueberry, hybrid carrot, and meadowfoam. The pollen diversity was estimated by documenting the number of different pollen pellet colors and plant taxa found in each pollen sample. The lowest pollen diversity was found in almond crop. Relatively higher quantities of pollen collection were collected in almond, cherry, and meadowfoam cropping systems. The information gleaned from this study regarding pollen diversity and abundance may help growers, land managers, and beekeepers improve pollen forage available to bees in these cropping systems.

Published

2018

11. Field rates of Sivanto™ (flupyradifurone) and Transform® (sulfoxaflor) increase oxidative stress and induce apoptosis in honey bees (Apis mellifera L.)

Author

Andony P. Melathopoulos, Emily A Carlson, Priyadarshini Chakrabarti, Ramesh R. Sagili, and Hannah M Lucas

Subjects

0106 biological sciences, Insecticides, Time Factors, Pyridines, Apoptosis, medicine.disease_cause, 01 natural sciences, Toxicology, chemistry.chemical_compound, 4-Butyrolactone, Pollinator, Pollination, Sulfoxaflor, 0303 health sciences, Multidisciplinary, Cell Death, biology, Caspase 3, Eukaryota, Insect physiology, Agriculture, Bees, Insects, Cell Processes, Insect Proteins, Medicine, Honey Bees, Agrochemicals, Research Article, Arthropoda, Cell Survival, Science, Insect Physiology, 03 medical and health sciences, medicine, Animals, Animal Physiology, Pesticides, Sugar, 030304 developmental biology, Invertebrate Physiology, Sulfur Compounds, business.industry, Organisms, Pest control, Biology and Life Sciences, Cell Biology, Honey bee, Pesticide, biology.organism_classification, Invertebrates, Hymenoptera, Oxidative Stress, 010602 entomology, chemistry, Pest Control, business, Zoology, Entomology, Oxidative stress

Abstract

Pesticide exposures can have detrimental impacts on bee pollinators, ranging from immediate mortality to sub-lethal impacts. Flupyradifurone is the active ingredient in Sivanto™ and sulfoxaflor is the active ingredient in Transform®. They are both relatively new insecticides developed with an intent to reduce negative effects on bees, when applied to bee-attractive crops. With the growing concern regarding pollinator health and pollinator declines, it is important to have a better understanding of any potential negative impacts, especially sub-lethal, of these pesticides on bees. This study reports novel findings regarding physiological stress experienced by bees exposed to field application rates of these two insecticides via a Potter Tower sprayer. Two contact exposure experiments were conducted-a shorter 6-hour study and a longer 10-day study. Honey bee mortality, sugar syrup and water consumption, and physiological responses (oxidative stress and apoptotic protein assays) were assessed in bees exposed to Sivanto™ and Transform®, and compared to bees in control group. For the longer, 10-day contact exposure experiment, only the Sivanto™ group was compared to the control group, as high mortality recorded in the sulfoxaflor treatment group during the shorter contact exposure experiment, made the latter group unfeasible to test in the longer 10-days experiment. In both the studies, sugar syrup and water consumptions were significantly different between treatment groups and controls. The highest mortality was observed in Transform® exposed bees, followed by the Sivanto™ exposed bees. Estimates of reactive oxygen/nitrogen species indicated significantly elevated oxidative stress in both pesticide treatment groups, when compared to controls. Caspase-3 protein assays, an indicator of onset of apoptosis, was also significantly higher in the pesticide treatment groups. These differences were largely driven by post exposure duration, indicating sub-lethal impacts. Further, our findings also emphasize the need to revisit contact exposure impacts of Sivanto™, given the sub-lethal impacts and mortality observed in our long-term (10-day) contact exposure experiment.

Published

2020

12. Honey bees consider larval nutritional status rather than genetic relatedness when selecting larvae for emergency queen rearing

Author

Carolyn R. Breece, Priyadarshini Chakrabarti, Hannah M Lucas, Ramesh R. Sagili, and Bradley N. Metz

Subjects

Male, 0106 biological sciences, 0301 basic medicine, animal structures, Science, media_common.quotation_subject, Nutritional Status, Zoology, Context (language use), Biology, 01 natural sciences, Article, 03 medical and health sciences, Honey Bees, parasitic diseases, Animals, Selection, Genetic, Social Behavior, reproductive and urinary physiology, media_common, Larva, Multidisciplinary, Reproduction, fungi, Nutritional status, Honey bee, Bees, biology.organism_classification, Brood, 010602 entomology, 030104 developmental biology, behavior and behavior mechanisms, Medicine, Queen (butterfly), Female

Abstract

In honey bees and many other social insects, production of queens is a vital task, as colony fitness is dependent on queens. The factors considered by honey bee workers in selecting larvae to rear new queens during emergency queen rearing are poorly understood. Identifying these parameters is critical, both in an evolutionary and apicultural context. As female caste development in honey bees is dependent on larval diet (i.e. nutrition), we hypothesized that larval nutritional state is meticulously assessed and used by workers in selection of larvae for queen rearing. To test this hypothesis, we conducted a series of experiments manipulating the nutritional status of one day old larvae by depriving them of brood food for a four-hour period, and then allowing workers to choose larvae for rearing queens from nutritionally deprived and non-deprived larvae. We simultaneously investigated the role of genetic relatedness in selection of larvae for queen rearing. In all the experiments, significantly greater numbers of non-deprived larvae than deprived larvae were selected for queen rearing irrespective of genetic relatedness. Our results demonstrate that honey bees perceive the nutritional state of larvae and use that information when selecting larvae for rearing queens in the natural emergency queen replacement process.

Published

2018

13. Field Populations of Wild Apis cerana Honey Bees Exhibit Increased Genetic Diversity Under Pesticide Stress Along an Agricultural Intensification Gradient in Eastern India

Author

Sagartirtha Sarkar, Parthiba Basu, and Priyadarshini Chakrabarti

Subjects

0301 basic medicine, Population, India, Zoology, 03 medical and health sciences, RAPD–PCR study, Stress, Physiological, Pollinator, Genetic variation, Animals, Pesticides, education, Apis cerana, Genetic diversity, education.field_of_study, biology, Apidae, Esterases, Genetic Variation, genetic diversity, General Medicine, Honey bee, Bees, biology.organism_classification, Adaptation, Physiological, Random Amplified Polymorphic DNA Technique, wild population, 030104 developmental biology, Genetic distance, Insect Science, Glucose-6-Phosphatase, isozyme study, agricultural intensification, Research Article

Abstract

Pesticides have been reported to be one of the major drivers in the global pollinator losses. The large-scale decline in honey bees, an important pollinator group, has resulted in comprehensive studies on honey bee colonies. Lack of information on native wild pollinators has paved the way for this study, which highlights the underlying evolutionary changes occurring in the wild honey bee populations exposed to pesticides along an agricultural intensification landscape. The study reports an increased genetic diversity in native Apis cerana Fabricius (Hymenoptera: Apidae) populations continually exposed to pesticide stress. An increased heterozygosity, evidenced by a higher electrophoretic banding pattern, was observed in the pesticide-exposed populations for two isozymes involved with xenobiotic metabolism—esterase and glucose-6-phosphate dehydrogenase. Differential banding patterns also revealed a higher percentage of polymorphic loci, number of polymorphic bands, Nei’s genetic distance, etc. observed in these populations in the Randomly Amplified Polymorphic DNA–Polymerase Chain Reaction (RAPD–PCR) experiments using three random decamer primers. Higher heterozygosity, being indicative of a more resistant population, implies population survival within the threshold pesticide stress. This study reports such changes for the first time in native wild Indian honey bee populations exposed to pesticides and has far-reaching implications on the population adaptability under pesticide stress.

Published

2018

14. Field populations of native Indian honey bees from pesticide intensive agricultural landscape show signs of impaired olfaction

Author

Santanu Rana, Parthiba Basu, Sreejata Bandopadhyay, Sagartirtha Sarkar, Priyadarshini Chakrabarti, and Dattatraya G. Naik

Subjects

animal structures, India, Zoology, Olfaction, complex mixtures, Article, Honey Bees, Spatio-Temporal Analysis, Botany, Animals, Apis cerana, Multidisciplinary, Dose-Response Relationship, Drug, biology, Pesticide residue, fungi, Proboscis, Pesticide Residues, food and beverages, Environmental Exposure, Environmental exposure, Honey bee, Bees, Pesticide, biology.organism_classification, Smell, behavior and behavior mechanisms

Abstract

Little information is available regarding the adverse effects of pesticides on natural honey bee populations. This study highlights the detrimental effects of pesticides on honey bee olfaction through behavioural studies, scanning electron microscopic imaging of antennal sensillae and confocal microscopic studies of honey bee brains for calcium ions on Apis cerana, a native Indian honey bee species. There was a significant decrease in proboscis extension response and biologically active free calcium ions and adverse changes in antennal sensillae in pesticide exposed field honey bee populations compared to morphometrically similar honey bees sampled from low/no pesticide sites. Controlled laboratory experiments corroborated these findings. This study reports for the first time the changes in antennal sensillae, expression of Calpain 1(an important calcium binding protein) and resting state free calcium in brains of honey bees exposed to pesticide stress.

Published

2015