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12 results on '"nurse bees"'

1. Nursing Honeybee Behavior and Sensorial-Related Genes Are Altered by Deformed Wing Virus Variant A.

Author

Diego, Silva, Nolberto, Arismendi, Pablo, Alveal Juan, Ricardo, Ceballos, Nelson, Zapata, and Marisol, Vargas

Subjects
*HONEYBEE behavior, *OLFACTORY receptors, *BEE behavior, *BEEHIVES, *POLLINATION by bees, *HONEYBEES, *ODORANT-binding proteins
Abstract

Simple Summary: Honeybees, Apis melllifera, are the most widely used bees in the world for pollination services. However, in recent years, continuous colony losses have been recorded worldwide. One of the factors behind these losses is associated with diseases specific to this species, such as those caused by viruses. One of the known viruses affecting honeybee populations is the deformed wing virus (DWV). DWV causes physical malformations, decreased olfactory sensitivity, learning difficulties, and behavioral alterations, which can compromise hive behaviors. Thus, we evaluated behavioral response, the expression of antenna-specific odorant-binding protein (OBP) genes, and brain genes related to bee behavior, especially nurse bees, in honeybees inoculated with the DWV variant A. We performed olfactory sensitivity analyses in beehives. We performed behavioral assays with the larvae-emitted alarm pheromone component to stimulate infected nurse bees. We found that high levels of viral replication in both the head and antennae altered the behavioral response, decreasing attraction to the pheromone component, and DWV-A infection decreased the gene expression of OBPs and brain genes. Thus, DWV-A infection in adult bees could compromise internal hive cohesion and A. mellifera nurse bee behaviors. Insect behavior is coordinated mainly by smell through the diverse odor-binding proteins (OBP) that allow them to identify and recognize their environment. Sensory information collected through smell is then analyzed and interpreted in the brain, allowing for correct insect functioning. The behavior of honeybees (Apis mellifera L.) can be affected by different pathogens, such as deformed wing virus (DWV). In particular, the DWV variant A (DWV-A) is capable of altering olfactory sensitivity and reducing the gene expression of different OBPs, including those associated with nursing behavior. The DWV is also capable of replicating itself in the sensory lobes of the brain, further compromising the processing of sensory information. This study evaluated the behavioral response of nurse honeybees exposed to a pheromone compound and the alterations in the gene expression of the pre- and post-synaptic neuronal genes neuroxins-1 and neurogilin-1 in the bee heads and OBP proteins in the antennae of nurse bees inoculated with DWV-A. The behavioral response of nurse bees exposed to the larval pheromone compound benzyl alcohol was analyzed using a Y-tube olfactometer. The viral load, the gene expression of OBP5 and OBP11 in antennae, and neuroxins-1 and neurogilin-1 in the bee heads were analyzed via qPCR. High viral loads significantly reduced the ability of 10- and 15-day-old nurse honeybees to choose the correct pheromone compound. Also, the gene expression of OBP5, OBP11, neuroxin-1, and neurogilin-1 in nurse honeybees decreased when they were highly infected with DWV-A. These results suggest that a DWV-A infection can disturb information processing and cause nursing honeybees to reduce their activity inside the hive, altering internal cohesion. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Acute oral toxicity, apoptosis, and immune response in nurse bees (Apis mellifera) induced by flupyradifurone.

Author

Jing Gao, Yi Guo, Jin Chen, Qing-Yun Diao, Qiang Wang, Ping-Li Dai, Li Zhang, Wen-Min Li, and Yan-Yan Wu

Subjects
HONEYBEES, BEES, IMMUNE response, NURSES, APOPTOSIS
Abstract

The potential toxicity of flupyradifurone (FPF) to honey bees has been a subject of controversy in recent years. Understanding the effect of pesticides on nurse bees is important because the fitness of nurse bees is critical for in-hive activities, such as larval survival and performing hive maintenance. In order to evaluate the acute oral toxicity of flupyradifurone on nurse bees, flupyradifurone at five different concentrations was selected to feed both larvae and nurse bees. Our results showed that nurse bees were more sensitive to flupyradifurone than larvae (LD50 of the acute oral toxicity of flupyradifurone was 17.72 μg a.i./larva and 3.368 μg a.i./nurse bee). In addition, the apoptotic rates of neurons in mushroom bodies of nurse bees were significantly induced by flupyradifurone at sublethal concentrations (8 mg/L, 20 mg/L, and 50 mg/L) and the median lethal concentration LC50 (125 mg/L). The expression of immune-related genes (Hsp90, Toll-8/Tollo, and defensin) was significantly changed in exposed nurse bees at the field-realistic concentration of flupyradifurone. However, three detoxifying enzyme genes (CYP9Q1, -2, and -3) were not affected by pesticide exposure. Our data suggest that although flupyradifurone had a relatively lower acute oral toxicity than many other common pesticides, exposures to the fieldrealistic and other sublethal concentrations of flupyradifurone still have cytotoxicity and immune-responsive effects on nurse bees. Therefore, flupyradifurone should be considered for its application in crops. [ABSTRACT FROM AUTHOR]

Published
2023
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3. Novel Insight Into the Development and Function of Hypopharyngeal Glands in Honey Bees

Author

Saboor Ahmad, Shahmshad Ahmed Khan, Khalid Ali Khan, and Jianke Li

Subjects
exocrine glands, nurse bees, acini, proteomics, protein and gene expression, royal jelly, Physiology, QP1-981
Abstract

Hypopharyngeal glands (HGs) are the most important organ of hymenopterans which play critical roles for the insect physiology. In honey bees, HGs are paired structures located bilaterally in the head, in front of the brain between compound eyes. Each gland is composed of thousands of secretory units connecting to secretory duct in worker bees. To better understand the recent progress made in understanding the structure and function of these glands, we here review the ontogeny of HGs, and the factors affecting the morphology, physiology, and molecular basis of the functionality of the glands. We also review the morphogenesis of HGs in the pupal and adult stages, and the secretory role of the glands across the ages for the first time. Furthermore, recent transcriptome, proteome, and phosphoproteome analyses have elucidated the potential mechanisms driving the HGs development and functionality. This adds a comprehensive novel knowledge of the development and physiology of HGs in honey bees over time, which may be helpful for future research investigations.

Published
2021
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5. Novel Insight Into the Development and Function of Hypopharyngeal Glands in Honey Bees.

Author

Ahmad, Saboor, Khan, Shahmshad Ahmed, Khan, Khalid Ali, and Li, Jianke

Subjects
HONEYBEES, GLANDS, INSECT physiology, EXOCRINE glands, ROYAL jelly
Abstract

Hypopharyngeal glands (HGs) are the most important organ of hymenopterans which play critical roles for the insect physiology. In honey bees, HGs are paired structures located bilaterally in the head, in front of the brain between compound eyes. Each gland is composed of thousands of secretory units connecting to secretory duct in worker bees. To better understand the recent progress made in understanding the structure and function of these glands, we here review the ontogeny of HGs, and the factors affecting the morphology, physiology, and molecular basis of the functionality of the glands. We also review the morphogenesis of HGs in the pupal and adult stages, and the secretory role of the glands across the ages for the first time. Furthermore, recent transcriptome, proteome, and phosphoproteome analyses have elucidated the potential mechanisms driving the HGs development and functionality. This adds a comprehensive novel knowledge of the development and physiology of HGs in honey bees over time, which may be helpful for future research investigations. [ABSTRACT FROM AUTHOR]

Published
2021
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6. Activity of salivary glands in secreting honey-elaborating enzymes in two subspecies of honeybee ( Apis mellifera L).

Author

Al‐Sherif, Aliaa A., Mazeed, Adel M., Ewis, Mohamed A., Nafea, Emad A., Hagag, El‐Seid E., and Kamel, Ahmed A.

Subjects
*HONEYBEES, *CLASSIFICATION of insects, *SALIVARY gland physiology, *INSECT enzymes, *GLUCOSE oxidase, *PHYSIOLOGY
Abstract

The activity of invertase, glucose oxidase and amylase in the cephalic (post-cerebral) and thoracic salivary glands is determined in Egyptian and Carniolan honeybees ( Apis mellifera L). For this purpose, three ages of worker bees are selected for enzyme assays. The results show that the three target enzymes are detected in the two glands during the three worker ages, except invertase, which cannot be detected in the cephalic gland of newly emerged bees of both subspecies. In both glands, the secretion of invertase is highest, followed by amylase and then glucose oxidase. In Carniolan bees, invertase secretion of the cephalic and thoracic glands increases gradually with age. In Egyptian bees, invertase increases with age only in the cephalic gland, whereas, in the thoracic gland, the highest secretion activity is detected in 10-15-day-old bees. The highest amounts of glucose oxidase and amylase in the cephalic gland are detected in newly emerged individuals of both Egyptian and Carniolan bees. In the thoracic gland, however, the highest activity of both enzymes is recorded only in newly emerged Egyptian bees. The results are discussed in the light of bee management and biological aspects of the two subspecies. [ABSTRACT FROM AUTHOR]

Published
2017
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8. Pollen Alters Amino Acid Levels in the Honey Bee Brain and This Relationship Changes With Age and Parasitic Stress

Author

Gloria DeGrandi-Hoffman, Samantha Calle, Stephanie L. Gage, Mark J. Carroll, and Natalia Jacobson

Subjects
0106 biological sciences, 0301 basic medicine, media_common.quotation_subject, Zoology, Insect, medicine.disease_cause, 01 natural sciences, lcsh:RC321-571, memory, nurse bees, 03 medical and health sciences, proboscis extension reflex, Pollen, Early adulthood, medicine, otorhinolaryngologic diseases, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, media_common, Original Research, chemistry.chemical_classification, learning, biology, General Neuroscience, fungi, food and beverages, Honey bee, biology.organism_classification, Nosema ceranae, Amino acid, 010602 entomology, 030104 developmental biology, nutrition, Proboscis extension reflex, chemistry, Odor, behavior and behavior mechanisms, insect, Neuroscience
Abstract

Pollen nutrition is necessary for proper growth and development of adult honey bees. Yet, it is unclear how pollen affects the honey bee brain and behavior. We investigated whether pollen affects amino acids in the brains of caged, nurse-aged bees, and what the behavioral consequences might be. We also tested whether parasitic stress altered this relationship by analyzing bees infected with prevalent stressor, Nosema ceranae. Levels of 18 amino acids in individual honey bee brains were measured using Gas Chromatography - Mass Spectrometry at two different ages (Day 7 and Day 11). We then employed the proboscis extension reflex to test odor learning and memory. We found that the honey bee brain was highly responsive to pollen. Many amino acids in the brain were elevated and were present at higher concentration with age. The majority of these amino acids were non-essential. Without pollen, levels of amino acids remained consistent, or declined. Nosema-infected bees showed a different profile. Infection altered amino acid levels in a pollen-dependent manner. The majority of amino acids were lower when pollen was given, but higher when pollen was deprived. Odor learning and memory was not affected by feeding pollen to uninfected bees; but pollen did improve performance in Nosema-infected bees. These results suggest that pollen in early adulthood continues to shape amino acid levels in the brain with age, which may affect neural circuitry and behavior over time. Parasitic stress by N. ceranae modifies this relationship revealing an interaction between infection, pollen nutrition, and behavior.

Published
2020

9. Honeybees are buffered against undernourishment during larval stages.

Author

Schilcher F, Hilsmann L, Ankenbrand MJ, Krischke M, Mueller MJ, Steffan-Dewenter I, and Scheiner R

Abstract

The negative impact of juvenile undernourishment on adult behavior has been well reported for vertebrates, but relatively little is known about invertebrates. In honeybees, nutrition has long been known to affect task performance and timing of behavioral transitions. Whether and how a dietary restriction during larval development affects the task performance of adult honeybees is largely unknown. We raised honeybees in-vitro , varying the amount of a standardized diet (150 µl, 160 µl, 180 µl in total). Emerging adults were marked and inserted into established colonies. Behavioral performance of nurse bees and foragers was investigated and physiological factors known to be involved in the regulation of social organization were quantified. Surprisingly, adult honeybees raised under different feeding regimes did not differ in any of the behaviors observed. No differences were observed in physiological parameters apart from weight. Honeybees were lighter when undernourished (150 µl), while they were heavier under the overfed treatment (180 µl) compared to the control group raised under a normal diet (160 µl). These data suggest that dietary restrictions during larval development do not affect task performance or physiology in this social insect despite producing clear effects on adult weight. We speculate that possible effects of larval undernourishment might be compensated during the early period of adult life., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Schilcher, Hilsmann, Ankenbrand, Krischke, Mueller, Steffan-Dewenter and Scheiner.)

Published
2022
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10. Pollen Alters Amino Acid Levels in the Honey Bee Brain and This Relationship Changes With Age and Parasitic Stress.

Author

Gage SL, Calle S, Jacobson N, Carroll M, and DeGrandi-Hoffman G

Abstract

Pollen nutrition is necessary for proper growth and development of adult honey bees. Yet, it is unclear how pollen affects the honey bee brain and behavior. We investigated whether pollen affects amino acids in the brains of caged, nurse-aged bees, and what the behavioral consequences might be. We also tested whether parasitic stress altered this relationship by analyzing bees infected with prevalent stressor, Nosema ceranae . Levels of 18 amino acids in individual honey bee brains were measured using Gas Chromatography - Mass Spectrometry at two different ages (Day 7 and Day 11). We then employed the proboscis extension reflex to test odor learning and memory. We found that the honey bee brain was highly responsive to pollen. Many amino acids in the brain were elevated and were present at higher concentration with age. The majority of these amino acids were non-essential. Without pollen, levels of amino acids remained consistent, or declined. Nosema -infected bees showed a different profile. Infection altered amino acid levels in a pollen-dependent manner. The majority of amino acids were lower when pollen was given, but higher when pollen was deprived. Odor learning and memory was not affected by feeding pollen to uninfected bees; but pollen did improve performance in Nosema -infected bees. These results suggest that pollen in early adulthood continues to shape amino acid levels in the brain with age, which may affect neural circuitry and behavior over time. Parasitic stress by N. ceranae modifies this relationship revealing an interaction between infection, pollen nutrition, and behavior., (Copyright © 2020 Gage, Calle, Jacobson, Carroll and DeGrandi-Hoffman.)

Published
2020
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12. One moment in time : Gene expression analysis of honey bees; nurse bees v.s. foragers

Author

Rimestad, Tove

Subjects
honey bees, nurse bees, Apis mellifera carnica, analysis, fungi, Mathematics and natural science: 400::Basic biosciences: 470::Genetics and genomics: 474 [VDP], behavior and behavior mechanisms, genes, foragers, complex mixtures, Agriculture and fishery disciplines: 900::Agriculture disciplines: 910 [VDP]
Abstract

Honey bees live in complex societies based on a division of labour. The honey bee workers specialise in different tasks throughout their lives, starting off as nurse bees and ending as foragers. The nurse bees and foragers display interesting phenotypic differences that do not have its origins in differences at genotype level, but in differences in gene expression. This thesis presents the results from an expression analysis done on honey bee workers comparing the expression profiles of nurse bees and foraging bees. We confirm patterns previously described in differences in expression of genes involved in energy storage, nutrient and energy metabolism, immune defence and communication. There are also a few surprises such as the expression of two hexamerins previously not reported in adult bees.

Published
2012

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