Your search keyword '"Danihlík, Jiří"' showing total 30 results

1. Spatial clusters of Varroa destructor control strategies in Europe

Author

Brodschneider, Robert, Schlagbauer, Johannes, Arakelyan, Iliyana, Ballis, Alexis, Brus, Jan, Brusbardis, Valters, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, da Costa, Cristina Amaro, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Mazur, Ewa, Mutinelli, Franco, Patalano, Solenn, Raudmets, Aivar, Simon Delso, Noa, Stevanovic, Jevrosima, Uzunov, Aleksandar, Vejsnæs, Flemming, Williams, Anthony, and Gray, Alison

Published

2023

2. Physiological responses to honeybee venom poisoning in a model organism, the firebug Pyrrhocoris apterus

Author

Ondřichová, Anna, Štěrbová, Helena, Danihlík, Jiří, Jemelková, Jana, Hejníková, Markéta, Šerý, Michal, and Kodrík, Dalibor

Published

2023

3. COLOSS B-RAP Expert Evaluation of Beekeeping Advice From ChatGPT, Part 1

Author

Morawetz, Linde, primary, Kristiansen, Lotta Fabricius, additional, Brus, Jan, additional, Dahle, Bjørn, additional, Danihlík, Jiří, additional, Diéguez-Antón, Ana, additional, Fischer, Johann, additional, Gray, Alison, additional, Mazur, Ewa, additional, Schaunitzer, Georg, additional, and Brodschneider, Robert, additional

Published

2024

4. Omics-based analysis of honey bee (Apis mellifera) response to Varroa sp. parasitisation and associated factors reveals changes impairing winter bee generation

Author

Kunc, Martin, Dobeš, Pavel, Ward, Rachel, Lee, Saetbyeol, Čegan, Radim, Dostálková, Silvie, Holušová, Kateřina, Hurychová, Jana, Eliáš, Sara, Pinďáková, Eliška, Čukanová, Eliška, Prodělalová, Jana, Petřivalský, Marek, Danihlík, Jiří, Havlík, Jaroslav, Hobza, Roman, Kavanagh, Kevin, and Hyršl, Pavel

Published

2022

5. Fatty acids and their derivatives from Chlorella vulgaris extracts exhibit in vitro antimicrobial activity against the honey bee pathogen Paenibacillus larvae.

Author

Dostálková, Silvie, Urajová, Petra, Činčárová, Dominika, Vránová, Tereza, Hrouzek, Pavel, Petřivalský, Marek, Lukeš, Martin, Čapková Frydrychová, Radmila, and Danihlík, Jiří

Abstract

The green microalga Chlorella vulgaris Beijerinck (Chlorellaceae) is widely used as a food supplement for humans and animals. In beekeeping practice, Chlorella vulgaris has potential as a pollen supplement. We studied whether Chlorella extracts display antimicrobial properties against Paenibacillus larvae, the causative agent of the honey bee bacterial disease American foulbrood. We identified components responsible for antimicrobial activity and evaluated the added values of Chlorella as a food supplement for honey bees. Different extracts (water, acetone, methanol) were prepared from Chlorella biomass (phototrophically and heterotrophically cultivated) and screened for antimicrobial activity against ERIC I and ERIC II genotypes of P. larvae. Active acetone extracts of phototrophically cultivated Chlorella vulgaris biomass were fractioned via preparative reverse-phase chromatography. Antimicrobial activity was detected for 9 of the resulting 33 fractions. Further analysis revealed the chemical composition of the active fractions. C. vulgaris extracts showed a significant antimicrobial effect against vegetative cells and spores of P. larvae strains of ERIC I and ERIC II genotypes. The lowest MIC of the most active acetone extract was 6.3 µg/mL for both tested genotypes. In the majority of the active fractions, monolinolenin, fatty acid linoleic acid, and methyl esters of linoleic and/or palmitic acid were identified via high-performance liquid chromatography coupled with high-resolution mass spectrometry analysis. Based on our results, we concluded that algal C. vulgaris food supplements not only contain nutritional but also potential prophylactic properties for honey bee health. [ABSTRACT FROM AUTHOR]

Published

2024

6. Effects of Chlorella sp. on biological characteristics of the honey bee Apis mellifera

Author

Jehlík, Tomáš, Kodrík, Dalibor, Krištůfek, Václav, Koubová, Justina, Sábová, Michala, Danihlík, Jiří, Tomčala, Aleš, and Čapková Frydrychová, Radmila

Published

2019

7. Fatty acids and their derivatives from Chlorella vulgarisextracts exhibit in vitroantimicrobial activity against the honey bee pathogen Paenibacillus larvae

Author

Dostálková, Silvie, Urajová, Petra, Činčárová, Dominika, Vránová, Tereza, Hrouzek, Pavel, Petřivalský, Marek, Lukeš, Martin, Čapková Frydrychová, Radmila, and Danihlík, Jiří

Abstract

AbstractThe green microalga Chlorella vulgarisBeijerinck (Chlorellaceae) is widely used as a food supplement for humans and animals. In beekeeping practice, Chlorella vulgarishas potential as a pollen supplement. We studied whether Chlorellaextracts display antimicrobial properties against Paenibacillus larvae, the causative agent of the honey bee bacterial disease American foulbrood. We identified components responsible for antimicrobial activity and evaluated the added values of Chlorellaas a food supplement for honey bees. Different extracts (water, acetone, methanol) were prepared from Chlorellabiomass (phototrophically and heterotrophically cultivated) and screened for antimicrobial activity against ERIC I and ERIC II genotypes of P. larvae. Active acetone extracts of phototrophically cultivated Chlorella vulgarisbiomass were fractioned via preparative reverse-phase chromatography. Antimicrobial activity was detected for 9 of the resulting 33 fractions. Further analysis revealed the chemical composition of the active fractions. C. vulgaris extracts showed a significant antimicrobial effect against vegetative cells and spores of P. larvaestrains of ERIC I and ERIC II genotypes. The lowest MIC of the most active acetone extract was 6.3 µg/mL for both tested genotypes. In the majority of the active fractions, monolinolenin, fatty acid linoleic acid, and methyl esters of linoleic and/or palmitic acid were identified via high-performance liquid chromatography coupled with high-resolution mass spectrometry analysis. Based on our results, we concluded that algal C. vulgarisfood supplements not only contain nutritional but also potential prophylactic properties for honey bee health.

Published

2024

8. Omics-based analysis of honey bee (Apis mellifera) response to Varroa sp. parasitisation and associated factors reveals changes impairing winter bee generation

Author

Kunc, Martin, primary, Dobeš, Pavel, additional, Ward, Rachel, additional, Lee, Saetbyeol, additional, Čegan, Radim, additional, Dostálková, Silvie, additional, Holušová, Kateřina, additional, Hurychová, Jana, additional, Eliáš, Sara, additional, Pinďáková, Eliška, additional, Čukanová, Eliška, additional, Prodělalová, Jana, additional, Petřivalský, Marek, additional, Danihlík, Jiří, additional, Havlík, Jaroslav, additional, Hobza, Roman, additional, Kavanagh, Kevin, additional, and Hyršl, Pavel, additional

Published

2023

9. Fine-scale assessment of Chlorella syrup as a nutritional supplement for honey bee colonies

Author

Dostálková, Silvie, primary, Kodrík, Dalibor, additional, Simone-Finstrom, Michael, additional, Petřivalský, Marek, additional, and Danihlík, Jiří, additional

Published

2022

10. A sensitive quantification of the peptide apidaecin 1 isoforms in single bee tissues using a weak cation exchange pre-separation and nanocapillary liquid chromatography coupled with mass spectrometry

Author

Danihlík, Jiří, Šebela, Marek, Petřivalský, Marek, and Lenobel, René

Published

2014

11. Honey bee colony loss rates in 37 countries using the COLOSS survey for winter 2019–2020: the combined effects of operation size, migration and queen replacement

Author

Gray, Alison, primary, Adjlane, Noureddine, additional, Arab, Alireza, additional, Ballis, Alexis, additional, Brusbardis, Valters, additional, Bugeja Douglas, Adrian, additional, Cadahía, Luis, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F., additional, Cornelissen, Bram, additional, Costa, Cristina Amaro da, additional, Danneels, Ellen, additional, Danihlík, Jiří, additional, Dobrescu, Constantin, additional, Evans, Garth, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Gregorc, Aleš, additional, Ilieva Arakelyan, Iliyana, additional, Johannesen, Jes, additional, Kauko, Lassi, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Mazur, Ewa, additional, Medina-Flores, Carlos Aurelio, additional, Mutinelli, Franco, additional, Omar, Eslam M., additional, Patalano, Solenn, additional, Raudmets, Aivar, additional, San Martin, Gilles, additional, Soroker, Victoria, additional, Stahlmann-Brown, Philip, additional, Stevanovic, Jevrosima, additional, Uzunov, Aleksandar, additional, Vejsnaes, Flemming, additional, Williams, Anthony, additional, and Brodschneider, Robert, additional

Published

2022

12. Honey bee colony loss rates in 37 countries using the COLOSS survey for winter 2019–2020: the combined effects of operation size, migration and queen replacement.

Author

Gray, Alison, Adjlane, Noureddine, Arab, Alireza, Ballis, Alexis, Brusbardis, Valters, Bugeja Douglas, Adrian, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Costa, Cristina Amaro da, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, and Ilieva Arakelyan, Iliyana

Abstract

This article presents managed honey bee colony loss rates over winter 2019/20 resulting from using the standardised COLOSS questionnaire in 37 countries. Six countries were from outside Europe, including, for the first time in this series of articles, New Zealand. The 30,491 beekeepers outside New Zealand reported 4.5% of colonies with unsolvable queen problems, 11.1% of colonies dead after winter and 2.6% lost through natural disaster. This gave an overall colony winter loss rate of 18.1%, higher than in the previous year. The winter loss rates varied greatly between countries, from 7.4% to 36.5%. 3216 beekeepers from New Zealand managing 297,345 colonies reported 10.5% losses for their 2019 winter (six months earlier than for other, Northern Hemisphere, countries). We modelled the risk of loss as a dead/empty colony or from unresolvable queen problems, for all countries except New Zealand. Overall, larger beekeeping operations with more than 50 colonies experienced significantly lower losses (p < 0.001). Migration was also highly significant (p < 0.001), with lower loss rates for operations migrating their colonies in the previous season. A higher proportion of new queens reduced the risk of colony winter loss (p < 0.001), suggesting that more queen replacement is better. All three factors, operation size, migration and proportion of young queens, were also included in a multivariable main effects quasi-binomial GLM and all three remained highly significant (p < 0.001). Detailed results for each country and overall are given in a table, and a map shows relative risks of winter loss at the regional level. [ABSTRACT FROM AUTHOR]

Published

2023

13. Spatial clusters of Varroa destructor control strategies in Europe

Author

Brodschneider, Robert, primary, Schlagbauer, Johannes, additional, Arakelyan, Iliyana, additional, Ballis, Alexis, additional, Brus, Jan, additional, Brusbardis, Valters, additional, Cadahía, Luis, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F., additional, Cornelissen, Bram, additional, da Costa, Cristina Amaro, additional, Danneels, Ellen, additional, Danihlík, Jiří, additional, Dobrescu, Constantin, additional, Evans, Garth, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Gregorc, Aleš, additional, Johannesen, Jes, additional, Kauko, Lassi, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Mazur, Ewa, additional, Mutinelli, Franco, additional, Patalano, Solenn, additional, Raudmets, Aivar, additional, Simon Delso, Noa, additional, Stevanovic, Jevrosima, additional, Uzunov, Aleksandar, additional, Vejsnæs, Flemming, additional, Williams, Anthony, additional, and Gray, Alison, additional

Published

2022

14. Corrigendum: American Foulbrood in the Czech Republic: ERIC II Genotype of Paenibacillus Larvae Is Prevalent

Author

Biová, Jana, primary, Bzdil, Jaroslav, additional, Dostálková, Silvie, additional, Petřivalský, Marek, additional, Brus, Jan, additional, Carra, Elena, additional, and Danihlík, Jiří, additional

Published

2021

15. Fatty acids and their derivatives from Chlorella vulgaris extracts exhibit in vitro antimicrobial activity against the honey bee pathogen Paenibacillus larvae

Author

Dostálková, Silvie, primary, Urajová, Petra, additional, Činčárová, Dominika, additional, Vránová, Tereza, additional, Hrouzek, Pavel, additional, Petřivalský, Marek, additional, Lukeš, Martin, additional, Čapková Frydrychová, Radmila, additional, and Danihlík, Jiří, additional

Published

2021

16. American Foulbrood in the Czech Republic: ERIC II Genotype of Paenibacillus Larvae Is Prevalent

Author

Biová, Jana, primary, Bzdil, Jaroslav, additional, Dostálková, Silvie, additional, Petřivalský, Marek, additional, Brus, Jan, additional, Carra, Elena, additional, and Danihlík, Jiří, additional

Published

2021

17. Direct Economic Impact Assessment of Winter Honeybee Colony Losses in Three European Countries

Author

Popovska Stojanov, Despina, primary, Dimitrov, Lazo, additional, Danihlík, Jiří, additional, Uzunov, Aleksandar, additional, Golubovski, Miroljub, additional, Andonov, Sreten, additional, and Brodschneider, Robert, additional

Published

2021

18. Melissococcus plutonius Can Be Effectively and Economically Detected Using Hive Debris and Conventional PCR

Author

Biová, Jana, primary, Charrière, Jean-Daniel, additional, Dostálková, Silvie, additional, Škrabišová, Mária, additional, Petřivalský, Marek, additional, Bzdil, Jaroslav, additional, and Danihlík, Jiří, additional

Published

2021

19. Honey bee colony winter loss rates for 35 countries participating in the COLOSS survey for winter 2018–2019, and the effects of a new queen on the risk of colony winter loss

Author

Gray, Alison, primary, Adjlane, Noureddine, additional, Arab, Alireza, additional, Ballis, Alexis, additional, Brusbardis, Valters, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F., additional, Cornelissen, Bram, additional, Amaro da Costa, Cristina, additional, Dahle, Bjørn, additional, Danihlík, Jiří, additional, Dražić, Marica Maja, additional, Evans, Garth, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Gajda, Anna, additional, de Graaf, Dirk C., additional, Gregorc, Aleš, additional, Ilieva, Iliyana, additional, Johannesen, Jes, additional, Kauko, Lassi, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Medina-Flores, Carlos Aurelio, additional, Mutinelli, Franco, additional, Patalano, Solenn, additional, Raudmets, Aivar, additional, Martin, Gilles San, additional, Soroker, Victoria, additional, Stevanovic, Jevrosima, additional, Uzunov, Aleksandar, additional, Vejsnaes, Flemming, additional, Williams, Anthony, additional, Zammit-Mangion, Marion, additional, and Brodschneider, Robert, additional

Published

2020

20. Winter honeybee (Apis mellifera) populations show greater potential to induce immune response than summer ones after immune stimuli

Author

Dostálková, Silvie, primary, Dobeš, Pavel, additional, Kunc, Martin, additional, Hurychová, Jana, additional, Škrabišová, Mária, additional, Petřivalský, Marek, additional, Titěra, Dalibor, additional, Havlík, Jaroslav, additional, Hyršl, Pavel, additional, and Danihlík, Jiří, additional

Published

2020

21. Loss rates of honey bee colonies during winter 2017/18 in 36 countries participating in the COLOSS survey, including effects of forage sources

Author

Gray, Alison, Brodschneider, Robert, Adjlane, Noureddine, Ballis, Alexis, Brusbardis, Valters, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Amaro da Costa, Cristina, Csáki, Tamás, Dahle, Bjørn, Norway, Kløfta, Danihlík, Jiří, Maja Dražić, Marica, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, de Graaf, Dirk, Gregorc, Aleš, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Medina-Flores, Carlos Aurelio, Mutinelli, Franco, Patalano, Solenn, Petrov, Plamen, Raudmets, Aivar, Ryzhikov, Vladimir A., Simon-Delso, Noa, Stevanovic, Jevrosima, Topolska, Grazyna, Uzunov, Aleksandar, Vejsnaes, Flemming, Zammit-Mangion, Marion, Soroker, Victoria, Williams, Anthony, Republic of Serbia, Slovenian Research Program, Zukunft Biene, and University of Graz

Subjects

0106 biological sciences, Beekeeping, Forage (honey bee), Honeybee -- Mortality -- Europe, beekeeping, forage sources, Biology, 01 natural sciences, Agricultural science, Biointeractions and Plant Health, 0404 agricultural biotechnology, citizen science, survey, QA, Ecological surveys, business.industry, Bee culture, Colony collapse disorder of honeybees, 04 agricultural and veterinary sciences, Honey bee, 040401 food science, mortality, 010602 entomology, monitoring, colony winter losses, Agriculture, Insect Science, Apis (Insects) -- Europe, Apis mellifera, business

Abstract

This short article presents loss rates of honey bee colonies over winter 2017/18 from 36 countries, including 33 in Europe, from data collected using the standardized COLOSS questionnaire. The 25,363 beekeepers supplying data passing consistency checks in total wintered 544,879 colonies, and reported 26,379 (4.8%, 95% CI 4.7–5.0%) colonies with unsolvable queen problems, 54,525 (10.0%, 95% CI 9.8–10.2%) dead colonies after winter and another 8,220 colonies (1.5%, 95% CI 1.4–1.6%) lost through natural disaster. This gave an overall loss rate of 16.4% (95% CI 16.1–16.6%) of honey bee colonies during winter 2017/18, but this varied greatly from 2.0 to 32.8% between countries. The included map shows relative risks of winter loss at regional level. The analysis using the total data-set confirmed findings from earlier surveys that smaller beekeeping operations with at most 50 colonies suffer significantly higher losses than larger operations (p, peer-reviewed

Published

2019

22. The Year of the Honey Bee (Apis mellifera L.) with Respect to Its Physiology and Immunity: A Search for Biochemical Markers of Longevity

Author

Kunc, Martin, primary, Dobeš, Pavel, additional, Hurychová, Jana, additional, Vojtek, Libor, additional, Poiani, Silvana Beani, additional, Danihlík, Jiří, additional, Havlík, Jaroslav, additional, Titěra, Dalibor, additional, and Hyršl, Pavel, additional

Published

2019

23. Comparison of apiculture and winter mortality of honey bee colonies (Apis mellifera) in Austria and Czechia

Author

Brodschneider, Robert, primary, Brus, Jan, additional, and Danihlík, Jiří, additional

Published

2019

24. Does the Pollen Diet Influence the Production and Expression of Antimicrobial Peptides in Individual Honey Bees?

Author

Danihlík, Jiří, primary, Škrabišová, Mária, additional, Lenobel, René, additional, Šebela, Marek, additional, Omar, Eslam, additional, Petřivalský, Marek, additional, Crailsheim, Karl, additional, and Brodschneider, Robert, additional

Published

2018

25. Multi-country loss rates of honey bee colonies during winter 2016/2017 from the COLOSS survey

Author

Brodschneider, Robert, primary, Gray, Alison, additional, Adjlane, Noureddine, additional, Ballis, Alexis, additional, Brusbardis, Valters, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F, additional, Dahle, Bjørn, additional, de Graaf, Dirk C, additional, Maja Dražić, Marica, additional, Evans, Garth, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Gregorc, Aleš, additional, Grzęda, Urszula, additional, Hetzroni, Amots, additional, Kauko, Lassi, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Aurelio Medina-Flores, Carlos, additional, Mutinelli, Franco, additional, Raudmets, Aivar, additional, A Ryzhikov, Vladimir, additional, Simon-Delso, Noa, additional, Stevanovic, Jevrosima, additional, Uzunov, Aleksandar, additional, Vejsnæs, Flemming, additional, Wöhl, Saskia, additional, Zammit-Mangion, Marion, additional, and Danihlík, Jiří, additional

Published

2018

26. Changes in plasma membrane aquaporin gene expression under osmotic stress and blue light in tomato

Author

Balarynová, Jana, primary, Danihlík, Jiří, additional, and Fellner, Martin, additional

Published

2018

27. Preliminary analysis of loss rates of honey bee colonies during winter 2015/16 from the COLOSS survey

Author

Brodschneider, Robert, primary, Gray, Alison, additional, van der Zee, Romée, additional, Adjlane, Noureddine, additional, Brusbardis, Valters, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F, additional, Crailsheim, Karl, additional, Dahle, Bjørn, additional, Danihlík, Jiří, additional, Danneels, Ellen, additional, de Graaf, Dirk C, additional, Dražić, Marica Maja, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Golubovski, Miroljub, additional, Gregorc, Ales, additional, Grzęda, Urszula, additional, Hubbuck, Ian, additional, İvgin Tunca, Rahşan, additional, Kauko, Lassi, additional, Kilpinen, Ole, additional, Kretavicius, Justinas, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Mutinelli, Franco, additional, Peterson, Magnus, additional, Otten, Christoph, additional, Ozkirim, Aslı, additional, Raudmets, Aivar, additional, Simon-Delso, Noa, additional, Soroker, Victoria, additional, Topolska, Grazyna, additional, Vallon, Julien, additional, Vejsnæs, Flemming, additional, and Woehl, Saskia, additional

Published

2016

28. Antimicrobial peptides: a key component of honey bee innate immunity

Author

Danihlík, Jiří, primary, Aronstein, Kate, additional, and Petřivalský, Marek, additional

Published

2015

29. Winter honeybee (Apis mellifera) populations show greater potential to induce immune responses than summer populations after immune stimuli

Author

Dostálková, Silvie, Dobeš, Pavel, Kunc, Martin, Hurychová, Jana, Škrabišová, Mária, Petřivalský, Marek, Titěra, Dalibor, Havlík, Jaroslav, Hyršl, Pavel, and Danihlík, Jiří

Abstract

In the temperate climates of central Europe and North America, two distinct honeybee (Apis mellifera) populations are found in colonies: short-living summer bees emerge in spring and survive until summer, whereas long-living winter bees emerge in late August and overwinter. Besides the difference in their life spans, each of these populations fulfils a different role in the colonies and individual bees have distinct physiological and immunological adaptations depending on their roles. For instance, winter worker bees have higher vitellogenin levels and larger reserves of nutrients in the fat body than summer bees. The differences between the immune systems of both populations are well described at the constitutive level; however, our knowledge of its inducibility is still very limited. In this study, we focus on the response of 10-day-old honeybee workers to immune challenges triggered in vivoby injecting heat-killed bacteria, with particular focus on honeybees that emerge and live under hive conditions. Responses to bacterial injections differed between summer and winter bees. Winter bees exhibited a more intense response, including higher expression of antimicrobial genes and antimicrobial activity, as well as a significant decrease in vitellogenin gene expression and its concentration in the hemolymph. The intense immune response observed in winter honeybees may contribute to our understanding of the relationships between colony fitness and infection with pathogens, as well as its association with successful overwintering.

Published

2021

30. Does the Pollen Diet Influence the Production and Expression of Antimicrobial Peptides in Individual Honey Bees?.

Author

Lenobel, René, Šebela, Marek, Danihlík, Jiří, Petřivalský, Marek, Škrabišová, Mária, Omar, Eslam, Crailsheim, Karl, and Brodschneider, Robert

Subjects

POLLEN, ANTIMICROBIAL peptides, HONEYBEES, APIDAECINS, GENE expression, INSECT genetics, LOW-protein diet

Abstract

We investigated the importance of protein nutrition for honey bee immunity. Different protein diets (monofloral pollen of Helianthus spp., Sinapis spp., Asparagus spp., Castanea spp., a mixture of the four different pollen and the pollen substitute FeedbeeTM) were fed to honey bees in cages ad libitum. After 18 days of feeding, apidaecin 1 isoforms concentration in the thorax were measured using nanoflow liquid chromatography coupled with mass spectrometry. Expression levels of genes, coding for apidaecins and abaecin in the abdomen were determined using quantitative PCR. The results indicate that protein-containing nutrition in adult worker honey bees can trigger certain metabolic responses. Bees without dietary protein showed lower apidaecin 1 isoforms concentrations. The significantly lowest concentration of apidaecin 1 isoforms was found in the group that was fed no pollen diet when compared to Asparagus, Castanea, Helianthus, and Sinapis pollen or the pollen supplement FeedBeeTM. Expression levels of the respective genes were also affected by the protein diets and different expression levels of these two antimicrobial peptides were found. Positive correlation between concentration and gene expression of apidaecins was found. The significance of feeding bees with different protein diets, as well as the importance of pollen nutrition for honey bee immunity is demonstrated. [ABSTRACT FROM AUTHOR]

Published

2018