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8. Construction and characterization of a BAC-library for a key pollinator, the bumblebee Bombus terrestris L

Author

Wilfert, L., Torres, M., Reber-Funk, C., Schmid-Hempel, R., Tomkins, J., Gadau, J., and Schmid-Hempel, P.

Abstract

The primitively social bumblebee Bombus terrestris is an ecological model species as well as an important agricultural pollinator. As part of the ongoing development of genomic resources for this model organism, we have constructed a publicly available bacterial artificial chromosome (BAC) library from males of a field-derived colony. We have shown that this library has a high coverage, which allows any particular sequence to be retrieved from at least one clone with a probability of 99.7%. We have further demonstrated the library's usefulness by successfully screening it with probes derived both from previously described B. terrestris genes and candidate genes from another bumblebee species and the honeybee. This library will facilitate genomic studies in B. terrestris and will allow for novel comparative studies in the social Hymenoptera

Published
2018

10. The genomes of Crithidia bombi and C. expoeki, common parasites of bumblebees

Author

Schmid-Hempel, P, Aebi, M, Barribeau, S, Kitajima, T, du Plessis, L, Schmid-Hempel, R, and Zoller, S

Subjects
Trypanosoma, Computer and Information Sciences, Bioinformatics, Protozoan Proteins, lcsh:Medicine, Synteny, Host-Parasite Interactions, Evolution, Molecular, Species Specificity, Polysaccharides, Crithidia, Invertebrate Genomics, parasitic diseases, Genetics, Animals, Evolutionary Systematics, lcsh:Science, Phylogeny, BLAST algorithm, Taxonomy, Data Management, Protozoans, Leishmania, Evolutionary Biology, Sequence Assembly Tools, Database and informatics methods, lcsh:R, Organisms, Sequence analysis, Biology and Life Sciences, Computational Biology, Eukaryota, Molecular Sequence Annotation, Phylogenetic Analysis, Genomics, Bees, Genome Analysis, Parasitic Protozoans, Research and analysis methods, Phylogenetics, Animal Genomics, lcsh:Q, Genome, Protozoan, Sequence Alignment, Metabolic Networks and Pathways, Research Article
Abstract

Trypanosomatids (Trypanosomatidae, Kinetoplastida) are flagellated protozoa containing many parasites of medical or agricultural importance. Among those, Crithidia bombi and C. expoeki, are common parasites in bumble bees around the world, and phylogenetically close to Leishmania and Leptomonas. They have a simple and direct life cycle with one host, and partially castrate the founding queens greatly reducing their fitness. Here, we report the nuclear genome sequences of one clone of each species, extracted from a field-collected infection. Using a combination of Roche 454 FLX Titanium, Pacific Biosciences PacBio RS, and Illumina GA2 instruments for C. bombi, and PacBio for C. expoeki, we could produce high-quality and well resolved sequences. We find that these genomes are around 32 and 34 MB, with 7,808 and 7,851 annotated genes for C. bombi and C. expoeki, respectively—which is somewhat less than reported from other trypanosomatids, with few introns, and organized in polycistronic units. A large fraction of genes received plausible functional support in comparison primarily with Leishmania and Trypanosoma. Comparing the annotated genes of the two species with those of six other trypanosomatids (C. fasciculata, L. pyrrhocoris, L. seymouri, B. ayalai, L. major, and T. brucei) shows similar gene repertoires and many orthologs. Similar to other trypanosomatids, we also find signs of concerted evolution in genes putatively involved in the interaction with the host, a high degree of synteny between C. bombi and C. expoeki, and considerable overlap with several other species in the set. A total of 86 orthologous gene groups show signatures of positive selection in the branch leading to the two Crithidia under study, mostly of unknown function. As an example, we examined the initiating glycosylation pathway of surface components in C. bombi, finding it deviates from most other eukaryotes and also from other kinetoplastids, which may indicate rapid evolution in the extracellular matrix that is involved in interactions with the host. Bumble bees are important pollinators and Crithidia-infections are suspected to cause substantial selection pressure on their host populations. These newly sequenced genomes provide tools that should help better understand host-parasite interactions in these pollinator pathogens., PLoS ONE, 13 (1), ISSN:1932-6203

Published
2018

11. The Bee Microbiome: Impact on Bee Health and Model for Evolution and Ecology of Host-Microbe Interactions

Author

Engel, P., Kwong, W.K., McFrederick, Q., Anderson, K.E., Barribeau, S.M., Chandler, J.A., Cornman, R.S., Dainat, J., de Miranda, J.R., Doublet, V., Emery, O., Evans, J.D., Farinelli, L., Flenniken, M.L., Granberg, F., Grasis, J.A., Gauthier, L., Hayer, J., Koch, H., Kocher, S., Martinson, V.G., Moran, N., Munoz-Torres, M., Newton, I., Paxton, R.J., Powell, E., Sadd, B.M., Schmid-Hempel, P., Schmid-Hempel, R., Song, S.J., Schwarz, R.S., vanEngelsdorp, D., and Dainat, B.

Subjects
fungi, Animals, Bacteria/classification, Bacteria/genetics, Bacteria/isolation & purification, Bees/genetics, Bees/microbiology, Bees/physiology, Biological Evolution, Microbiota, Pollination, Symbiosis, complex mixtures
Abstract

As pollinators, bees are cornerstones for terrestrial ecosystem stability and key components in agricultural productivity. All animals, including bees, are associated with a diverse community of microbes, commonly referred to as the microbiome. The bee microbiome is likely to be a crucial factor affecting host health. However, with the exception of a few pathogens, the impacts of most members of the bee microbiome on host health are poorly understood. Further, the evolutionary and ecological forces that shape and change the microbiome are unclear. Here, we discuss recent progress in our understanding of the bee microbiome, and we present challenges associated with its investigation. We conclude that global coordination of research efforts is needed to fully understand the complex and highly dynamic nature of the interplay between the bee microbiome, its host, and the environment. High-throughput sequencing technologies are ideal for exploring complex biological systems, including host-microbe interactions. To maximize their value and to improve assessment of the factors affecting bee health, sequence data should be archived, curated, and analyzed in ways that promote the synthesis of different studies. To this end, the BeeBiome consortium aims to develop an online database which would provide reference sequences, archive metadata, and host analytical resources. The goal would be to support applied and fundamental research on bees and their associated microbes and to provide a collaborative framework for sharing primary data from different research programs, thus furthering our understanding of the bee microbiome and its impact on pollinator health.

Published
2016

12. Invasion success of the bumblebee, Bombus terrestris, despite a drastic genetic bottleneck

Author

Schmid-Hempel, P., Schmid-Hempel, R., Brunner, P.C., Seeman, O.D., and Allen, G.R.

Subjects
Biological invasions -- Research, Bumblebees -- Genetic aspects, Population genetics -- Research, Biological sciences
Abstract

The results of genetic screening, based on micro satellites of the invading population of Bombus terrestris in Tasmania are presented. The findings show that Bombus terrestris is a highly invasive species capable of establishing itself even after a dramatic genetic bottleneck.

Published
2007

13. Parasite infection of specific host genotypes relates to changes in prevalence in two natural populations of bumblebees

Author

Manlik, O, Schmid-Hempel, R, Schmid-Hempel, P, Manlik, O, Schmid-Hempel, R, and Schmid-Hempel, P

Abstract

The antagonistic relationship between parasites and their hosts is strongly influenced by genotype-by-genotype interactions. Defense against parasitism is commonly studied in the context of immune system-based mechanisms and, thus, the focus in the search for candidate genes in host-parasite interactions is often on immune genes.In this study, we investigated the association between prevalence of parasite infection and host mitochondrial DNA (mtDNA) haplotypes in two natural populations of bumblebees (Bombus terrestris). The two most common haplotypes of the host populations, termed A and B, differ by a single nonsynonymous nucleotide substitution within the coding region of cytochrome oxidase I, an important player in metabolic pathways. We screened infection by Nosema bombi, a common endoparasite of bumblebees, and the corresponding host mtDNA-haplotype frequencies in over 1400 bumblebees between 2000 and 2010. The island population of Gotland showed lower mtDNA diversity compared to the mainland population in Switzerland. Over time, we observed large fluctuations in infection prevalence, as well as variation in host haplotype frequencies in both populations. Our long-term observation revealed that N. bombi infection of specific host genotypes is transient: We found that withincreasing infection prevalence, proportionally more individuals with haplotype B, but fewer individuals with haplotype A were infected. This suggests that the presence of N. bombi in specific host genotypes relates to infection prevalence. This may be a result of parasite competition, or differential resilience of host types to ward off infections. The findings highlight the important role of host mtDNA haplotypes in the interaction with parasites.

Published
2017

14. Time and energy constraints and the relationships between currencies in foraging theory

Author

Ydenberg, R. C., Welham, C. V. J., Schmid-Hempel, R., Schmid-Hempel, P., Beauchamp, G., Ydenberg, R. C., Welham, C. V. J., Schmid-Hempel, R., Schmid-Hempel, P., and Beauchamp, G.

Abstract

Measured foraging strategies often cluster around values that maximize the ratio of energy gained over energy spent while foraging (efficiency), rather than values that would maximize the long-term net rate of energy gain (rate). The reasons for this are not understood. This paper focuses on time and energy constraints while foraging to illustrate the relationship between efficiency and rate-maximizing strategies and develops models that provide a simple framework to analyze foraging strategies in two distinct foraging contexts. We assume that while capturing and ingesting food for their own use (which we term feeding), foragers behave so as to maximize the total net daily energetic gain. When gathering food for others or for storage (which we term provisioning), we assume that foragers behave so as to maximize the total daily delivery, subject to meeting their own energetic requirements. In feeding contexts, the behavior maximizing total net daily gain also maximizes efficiency when daily intake is limited by the assimilation capacity. In contrast, when time available to forage sets the limit to gross intake, the behavior maximizing total net daily gain also maximizes rate. In provisioning contexts, when daily delivery is constrained by the energy needed to power self-feeding, maximizing efficiency ensures the highest total daily delivery. When time needed to recoup energetic expenditure limits total delivery, a low self-feeding rate relative to the rate of energy expenditure favors efficient strategies. However, as the rate of self-feeding increases, foraging behavior deviates from efficiency maximization in the direction predicted by rate maximization. Experimental manipulations of the rate of self-feeding in provisioning contexts could be a powerful tool to explore the relationship between rate and efficiency-maximizing behavior

Published
2017

16. The genomes of two key bumblebee species with primitive eusocial organization.

Author

Sadd, BM, Barribeau, SM, Bloch, G, de Graaf, DC, Dearden, P, Elsik, CG, Gadau, J, Grimmelikhuijzen, CJP, Hasselmann, M, Lozier, JD, Robertson, HM, Smagghe, G, Stolle, E, Van Vaerenbergh, M, Waterhouse, RM, Bornberg-Bauer, E, Klasberg, S, Bennett, AK, Câmara, F, Guigó, R, Hoff, K, Mariotti, M, Munoz-Torres, M, Murphy, T, Santesmasses, D, Amdam, GV, Beckers, M, Beye, M, Biewer, M, Bitondi, MMG, Blaxter, ML, Bourke, AFG, Brown, MJF, Buechel, SD, Cameron, R, Cappelle, K, Carolan, JC, Christiaens, O, Ciborowski, KL, Clarke, DF, Colgan, TJ, Collins, DH, Cridge, AG, Dalmay, T, Dreier, S, du Plessis, L, Duncan, E, Erler, S, Evans, J, Falcon, T, Flores, K, Freitas, FCP, Fuchikawa, T, Gempe, T, Hartfelder, K, Hauser, F, Helbing, S, Humann, FC, Irvine, F, Jermiin, LS, Johnson, CE, Johnson, RM, Jones, AK, Kadowaki, T, Kidner, JH, Koch, V, Köhler, A, Kraus, FB, Lattorff, HMG, Leask, M, Lockett, GA, Mallon, EB, Antonio, DSM, Marxer, M, Meeus, I, Moritz, RFA, Nair, A, Näpflin, K, Nissen, I, Niu, J, Nunes, FMF, Oakeshott, JG, Osborne, A, Otte, M, Pinheiro, DG, Rossié, N, Rueppell, O, Santos, CG, Schmid-Hempel, R, Schmitt, BD, Schulte, C, Simões, ZLP, Soares, MPM, Swevers, L, Winnebeck, EC, Wolschin, F, Yu, N, Zdobnov, EM, Aqrawi, PK, Blankenburg, KP, Coyle, M, Francisco, L, Hernandez, AG, Holder, M, Hudson, ME, Jackson, L, Jayaseelan, J, Joshi, V, Kovar, C, Lee, SL, Mata, R, Mathew, T, Newsham, IF, Ngo, R, Okwuonu, G, Pham, C, Pu, L-L, Saada, N, Santibanez, J, Simmons, D, Thornton, R, Venkat, A, Walden, KKO, Wu, Y-Q, Debyser, G, Devreese, B, Asher, C, Blommaert, J, Chipman, AD, Chittka, L, Fouks, B, Liu, J, O'Neill, MP, Sumner, S, Puiu, D, Qu, J, Salzberg, SL, Scherer, SE, Muzny, DM, Richards, S, Robinson, GE, Gibbs, RA, Schmid-Hempel, P, Worley, KC, Sadd, BM, Barribeau, SM, Bloch, G, de Graaf, DC, Dearden, P, Elsik, CG, Gadau, J, Grimmelikhuijzen, CJP, Hasselmann, M, Lozier, JD, Robertson, HM, Smagghe, G, Stolle, E, Van Vaerenbergh, M, Waterhouse, RM, Bornberg-Bauer, E, Klasberg, S, Bennett, AK, Câmara, F, Guigó, R, Hoff, K, Mariotti, M, Munoz-Torres, M, Murphy, T, Santesmasses, D, Amdam, GV, Beckers, M, Beye, M, Biewer, M, Bitondi, MMG, Blaxter, ML, Bourke, AFG, Brown, MJF, Buechel, SD, Cameron, R, Cappelle, K, Carolan, JC, Christiaens, O, Ciborowski, KL, Clarke, DF, Colgan, TJ, Collins, DH, Cridge, AG, Dalmay, T, Dreier, S, du Plessis, L, Duncan, E, Erler, S, Evans, J, Falcon, T, Flores, K, Freitas, FCP, Fuchikawa, T, Gempe, T, Hartfelder, K, Hauser, F, Helbing, S, Humann, FC, Irvine, F, Jermiin, LS, Johnson, CE, Johnson, RM, Jones, AK, Kadowaki, T, Kidner, JH, Koch, V, Köhler, A, Kraus, FB, Lattorff, HMG, Leask, M, Lockett, GA, Mallon, EB, Antonio, DSM, Marxer, M, Meeus, I, Moritz, RFA, Nair, A, Näpflin, K, Nissen, I, Niu, J, Nunes, FMF, Oakeshott, JG, Osborne, A, Otte, M, Pinheiro, DG, Rossié, N, Rueppell, O, Santos, CG, Schmid-Hempel, R, Schmitt, BD, Schulte, C, Simões, ZLP, Soares, MPM, Swevers, L, Winnebeck, EC, Wolschin, F, Yu, N, Zdobnov, EM, Aqrawi, PK, Blankenburg, KP, Coyle, M, Francisco, L, Hernandez, AG, Holder, M, Hudson, ME, Jackson, L, Jayaseelan, J, Joshi, V, Kovar, C, Lee, SL, Mata, R, Mathew, T, Newsham, IF, Ngo, R, Okwuonu, G, Pham, C, Pu, L-L, Saada, N, Santibanez, J, Simmons, D, Thornton, R, Venkat, A, Walden, KKO, Wu, Y-Q, Debyser, G, Devreese, B, Asher, C, Blommaert, J, Chipman, AD, Chittka, L, Fouks, B, Liu, J, O'Neill, MP, Sumner, S, Puiu, D, Qu, J, Salzberg, SL, Scherer, SE, Muzny, DM, Richards, S, Robinson, GE, Gibbs, RA, Schmid-Hempel, P, and Worley, KC

Abstract

BACKGROUND: The shift from solitary to social behavior is one of the major evolutionary transitions. Primitively eusocial bumblebees are uniquely placed to illuminate the evolution of highly eusocial insect societies. Bumblebees are also invaluable natural and agricultural pollinators, and there is widespread concern over recent population declines in some species. High-quality genomic data will inform key aspects of bumblebee biology, including susceptibility to implicated population viability threats. RESULTS: We report the high quality draft genome sequences of Bombus terrestris and Bombus impatiens, two ecologically dominant bumblebees and widely utilized study species. Comparing these new genomes to those of the highly eusocial honeybee Apis mellifera and other Hymenoptera, we identify deeply conserved similarities, as well as novelties key to the biology of these organisms. Some honeybee genome features thought to underpin advanced eusociality are also present in bumblebees, indicating an earlier evolution in the bee lineage. Xenobiotic detoxification and immune genes are similarly depauperate in bumblebees and honeybees, and multiple categories of genes linked to social organization, including development and behavior, show high conservation. Key differences identified include a bias in bumblebee chemoreception towards gustation from olfaction, and striking differences in microRNAs, potentially responsible for gene regulation underlying social and other traits. CONCLUSIONS: These two bumblebee genomes provide a foundation for post-genomic research on these key pollinators and insect societies. Overall, gene repertoires suggest that the route to advanced eusociality in bees was mediated by many small changes in many genes and processes, and not by notable expansion or depauperation.

Published
2015

22. Invasion success of the bumblebee, Bombus terrestris, despite a drastic genetic bottleneck

Author

Schmid-Hempel, P, Schmid-Hempel, R, Brunner, PC, Seeman, OD, Allen, GR, Schmid-Hempel, P, Schmid-Hempel, R, Brunner, PC, Seeman, OD, and Allen, GR

Abstract

In early 1992, the European bumblebee, Bombus terrestris, was first seen in Tasmania and currently has spread to most of the island. Here, we report on the genetic structure, using micro-satellites, of the invading population from samples collected in the years 1998–2000, a few years after the first sighting of the species in its new area. The data show that the Tasmanian population has a very low genetic diversity, with less than half of the allelic richness (Richness=2.89 alleles; Hexp=0.591) and lower levels of heterozygosity as compared to populations in New Zealand (4.24 alleles; Hexp=0.729) and Europe (5.08 alleles; Hexp=0.826). In addition, the genetic data suggest that the invasion must have happened once, probably around late 1991, and was the result of very few, perhaps only two, individuals arriving in Tasmania. Furthermore, these founders came from the New Zealand population. Today, the population in the south of Tasmania seems to act as a source population from which individuals migrate into other parts of the state. A similar source–sink structure seems also the case for New Zealand. The data show that B. terrestris is a highly invasive species capable of establishing itself even after a dramatic genetic bottleneck. B. terrestris may be an invasive species due to the haplo–diploid sex determination system, which exposes recessive, deleterious mutations to selection. Offspring of such purged lines may then be able to tolerate high levels of inbreeding.

23. Construction and characterization of a BAC-library for a key pollinator, the bumblebee Bombus terrestris L

Author

Wilfert, L., Torres, M., Reber-Funk, C., Schmid-Hempel, R., Tomkins, J., Gadau, J., Schmid-Hempel, P., Wilfert, L., Torres, M., Reber-Funk, C., Schmid-Hempel, R., Tomkins, J., Gadau, J., and Schmid-Hempel, P.

Abstract

The primitively social bumblebee Bombus terrestris is an ecological model species as well as an important agricultural pollinator. As part of the ongoing development of genomic resources for this model organism, we have constructed a publicly available bacterial artificial chromosome (BAC) library from males of a field-derived colony. We have shown that this library has a high coverage, which allows any particular sequence to be retrieved from at least one clone with a probability of 99.7%. We have further demonstrated the library's usefulness by successfully screening it with probes derived both from previously described B. terrestris genes and candidate genes from another bumblebee species and the honeybee. This library will facilitate genomic studies in B. terrestris and will allow for novel comparative studies in the social Hymenoptera

24. Time and energy constraints and the relationships between currencies in foraging theory

Author

Ydenberg, R. C., Welham, C. V. J., Schmid-Hempel, R., Schmid-Hempel, P., Beauchamp, G., Ydenberg, R. C., Welham, C. V. J., Schmid-Hempel, R., Schmid-Hempel, P., and Beauchamp, G.

Abstract

Measured foraging strategies often cluster around values that maximize the ratio of energy gained over energy spent while foraging (efficiency), rather than values that would maximize the long-term net rate of energy gain (rate). The reasons for this are not understood. This paper focuses on time and energy constraints while foraging to illustrate the relationship between efficiency and rate-maximizing strategies and develops models that provide a simple framework to analyze foraging strategies in two distinct foraging contexts. We assume that while capturing and ingesting food for their own use (which we term feeding), foragers behave so as to maximize the total net daily energetic gain. When gathering food for others or for storage (which we term provisioning), we assume that foragers behave so as to maximize the total daily delivery, subject to meeting their own energetic requirements. In feeding contexts, the behavior maximizing total net daily gain also maximizes efficiency when daily intake is limited by the assimilation capacity. In contrast, when time available to forage sets the limit to gross intake, the behavior maximizing total net daily gain also maximizes rate. In provisioning contexts, when daily delivery is constrained by the energy needed to power self-feeding, maximizing efficiency ensures the highest total daily delivery. When time needed to recoup energetic expenditure limits total delivery, a low self-feeding rate relative to the rate of energy expenditure favors efficient strategies. However, as the rate of self-feeding increases, foraging behavior deviates from efficiency maximization in the direction predicted by rate maximization. Experimental manipulations of the rate of self-feeding in provisioning contexts could be a powerful tool to explore the relationship between rate and efficiency-maximizing behavior

26. RNA viruses of Crithidia bombi, a parasite of bumblebees.

Author

Klocek D, Grybchuk D, Macedo DH, Galan A, Votýpka J, Schmid-Hempel R, Schmid-Hempel P, Yurchenko V, and Kostygov AY

Subjects
Bees, Animals, Phylogeny, Crithidia genetics, North America, Parasites, RNA Viruses genetics
Abstract

Leishbuviridae (Bunyavirales) are a diverse monophyletic group of negative-sense single-stranded RNA virus infecting parasitic flagellates of the family Trypanosomatidae. The presence of RNA viruses in trypanosomatids can influence the virulence of the latter. Here, we performed a screening for viruses in Crithidia bombi - a common parasite of important pollinators Bombus spp. (bumblebees) that negatively affects its host in stressful conditions. The majority (8/10) of C. bombi isolates collected in Europe and North America were positive for a virus that we named Crithidia bombi leishbuvirus 1 with high conservation of amino acid sequences between isolates. The results of our comparative phylogenetic analyses of the trypanosomatids and their viruses suggest that the high mobility of bumblebees and frequent coinfections by different strains of C. bombi determine an extensive viral exchange between the latter., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published
2023
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27. Impact of climate change on parasite infection of an important pollinator depends on host genotypes.

Author

Manlik O, Mundra S, Schmid-Hempel R, and Schmid-Hempel P

Subjects
Bees genetics, Animals, Genotype, Host-Parasite Interactions genetics, Climate Change, Parasitic Diseases
Abstract

Climate change is predicted to affect host-parasite interactions, and for some hosts, parasite infection is expected to increase with rising temperatures. Global population declines of important pollinators already have been attributed to climate change and parasitism. However, the role of climate in driving parasite infection and the genetic basis for pollinator hosts to respond often remain obscure. Based on decade-long field data, we investigated the association between climate and Nosema bombi (Microsporidia) infection of buffed-tailed bumblebees (Bombus terrestris), and whether host genotypes play a role. For this, we genotyped 876 wild bumblebee queens and screened for N. bombi infection of those queens between 2000 and 2010. We recorded seven climate parameters during those 11 years and tested for correlations between climate and infection prevalence. Here we show that climatic factors drive N. bombi infection and that the impact of climate depends on mitochondrial DNA cytochrome oxidase I (COI) haplotypes of the host. Infection prevalence was correlated with climatic variables during the time when queens emerge from hibernation. Remarkably, COI haplotypes best predict this association between climatic factors and infection. In particular, two host haplotypes ("A" and "B") displayed phenotypic plasticity in response to climatic variation: Temperature was positively correlated with infection of host haplotype B, but not haplotype A. The likelihood of infection of haplotype A was associated with moisture, conferring greater resistance to parasite infection during wetter years. In contrast, infection of haplotype B was unrelated to moisture. To the best of our knowledge, this is the first study that identifies specific host genotypes that confer differential parasite resistance under variable climatic conditions. Our results underscore the importance of mitochondrial haplotypes to ward off parasites in a changing climate. More broadly, this also suggests that COI may play a pertinent role in climate change adaptations of insect pollinators., (© 2022 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published
2023
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28. Genetic variation and microbiota in bumble bees cross-infected by different strains of C. bombi.

Author

Barribeau SM, Schmid-Hempel P, Walser JC, Zoller S, Berchtold M, Schmid-Hempel R, and Zemp N

Subjects
Bees genetics, Animals, Genome-Wide Association Study, Crithidia genetics, Genetic Variation, Microbiota, Neisseriaceae
Abstract

The bumblebee Bombus terrestris is commonly infected by a trypanosomatid gut parasite Crithidia bombi. This system shows a striking degree of genetic specificity where host genotypes are susceptible to different genotypes of parasite. To a degree, variation in host gene expression underlies these differences, however, the effects of standing genetic variation has not yet been explored. Here we report on an extensive experiment where workers of twenty colonies of B. terrestris were each infected by one of twenty strains of C. bombi. To elucidate the host's genetic bases of susceptibility to infection (measured as infection intensity), we used a low-coverage (~2 x) genome-wide association study (GWAS), based on angsd, and a standard high-coverage (~15x) GWAS (with a reduced set from a 8 x 8 interaction matrix, selected from the full set of twenty). The results from the low-coverage approach remained ambiguous. The high-coverage approach suggested potentially relevant genetic variation in cell surface and adhesion processes. In particular, mucin, a surface mucoglycoprotein, potentially affecting parasite binding to the host gut epithelia, emerged as a candidate. Sequencing the gut microbial community of the same bees showed that the abundance of bacterial taxa, such as Gilliamella, Snodgrassella, or Lactobacillus, differed between 'susceptible' and 'resistant' microbiota, in line with earlier studies. Our study suggests that the constitutive microbiota and binding processes at the cell surface are candidates to affect infection intensity after the first response (captured by gene expression) has run its course. We also note that a low-coverage approach may not be powerful enough to analyse such complex traits. Furthermore, testing large interactions matrices (as with the full 20 x 20 combinations) for the effect of interaction terms on infection intensity seems to blur the specific host x parasite interaction effects, likely because the outcome of an infection is a highly non-linear process dominated by variation in individually different pathways of host defence (immune) responses., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2022 Barribeau et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published
2022
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29. Genomic Variation among Strains of Crithidia bombi and C. expoeki .

Author

Gerasimov E, Zemp N, Schmid-Hempel R, Schmid-Hempel P, and Yurchenko V

Subjects
Alaska, Animals, Bees parasitology, Europe, Female, Genomics, Host-Parasite Interactions, Phylogeny, Polymorphism, Single Nucleotide, Crithidia genetics, DNA Copy Number Variations, Genetic Variation, Genome, Protozoan
Abstract

In this study, we sequenced and analyzed the genomes of 40 strains, in addition to the already-reported two type strains, of two Crithidia species infecting bumblebees in Alaska and Central Europe and demonstrated that different strains of Crithidia bombi and C. expoeki vary considerably in terms of single nucleotide polymorphisms and gene copy number. Based on the genomic structure, phylogenetic analyses, and the pattern of copy number variation, we confirmed the status of C. expoeki as a separate species. The Alaskan populations appear to be clearly separated from those of Central Europe. This pattern fits a scenario of rapid host-parasite coevolution, where the selective advantage of a given parasite strain is only temporary. This study provides helpful insights into possible scenarios of selection and diversification of trypanosomatid parasites. IMPORTANCE A group of trypanosomatid flagellates includes several well-studied medically and economically important parasites of vertebrates and plants. Nevertheless, the vast majority of trypanosomatids infect only insects (mostly flies and true bugs) and, because of that, has attracted little research attention in the past. Of several hundred trypanosomatid species, only four can infect bees (honeybees and bumblebees). Because of such scarcity, these parasites are severely understudied. We analyzed whole-genome information for a total of 42 representatives of bee-infecting trypanosomatids collected in Central Europe and Alaska from a population genetics point of view. Our data shed light on the evolution, selection, and diversification in this important group of trypanosomatid parasites., (Copyright © 2019 Gerasimov et al.)

Published
2019
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30. Large-scale cultivation of the bumblebee gut microbiota reveals an underestimated bacterial species diversity capable of pathogen inhibition.

Author

Praet J, Parmentier A, Schmid-Hempel R, Meeus I, Smagghe G, and Vandamme P

Subjects
Animals, Bacteria classification, Bacteria genetics, Crithidia growth & development, Gastrointestinal Microbiome physiology, Paenibacillus larvae growth & development, Pectins metabolism, RNA, Ribosomal, 16S genetics, Bacteria isolation & purification, Bacteria metabolism, Bees microbiology, Biological Control Agents analysis, Gastrointestinal Microbiome genetics
Abstract

A total of 1940 isolates from gut samples of 60 bumblebees representing Bombus pascuorum, Bombus terrestris, Bombus lucorum and Bombus lapidarius was collected and identified through state-of the-art taxonomic methods. The bacterial species diversity in these Bombus species exceeded that suggested by phylotype analysis through 16S rRNA amplicon sequencing, and revealed that B. pascuorum and B. terrestris had a unique microbiota composition, each. Representatives of most phylotypes reported earlier and detected in the present study were effectively isolated, and included several novel bacterial taxa and species reported for the first time in the bumblebee gut. Isolates were screened in pectin degradation assays and growth inhibition assays against the honeybee pathogens Paenibacillus larvae, Melissococcus plutonius and Ascosphaera apis and the bumblebee parasite Crithidia bombi. While inhibitory activity against each of these pathogens was observed, only one single culture was able to degrade pectin and polygalacturonic acid in vitro. The availability of accurately identified microbial isolates will facilitate future evaluation of the functional potential of the bumblebee gut microbiota., (© 2017 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published
2018
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31. Parasite infection of specific host genotypes relates to changes in prevalence in two natural populations of bumblebees.

Author

Manlik O, Schmid-Hempel R, and Schmid-Hempel P

Subjects
Animals, DNA, Mitochondrial, Genetic Variation, Haplotypes, Prevalence, Sequence Analysis, DNA, Animal Diseases epidemiology, Animal Diseases parasitology, Bees genetics, Bees parasitology, Genetics, Population, Genotype, Host-Parasite Interactions genetics
Abstract

The antagonistic relationship between parasites and their hosts is strongly influenced by genotype-by-genotype interactions. Defense against parasitism is commonly studied in the context of immune system-based mechanisms and, thus, the focus in the search for candidate genes in host-parasite interactions is often on immune genes. In this study, we investigated the association between prevalence of parasite infection and host mitochondrial DNA (mtDNA) haplotypes in two natural populations of bumblebees (Bombus terrestris). The two most common haplotypes of the host populations, termed A and B, differ by a single nonsynonymous nucleotide substitution within the coding region of cytochrome oxidase I, an important player in metabolic pathways. We screened infection by Nosema bombi, a common endoparasite of bumblebees, and the corresponding host mtDNA-haplotype frequencies in over 1400 bumblebees between 2000 and 2010. The island population of Gotland showed lower mtDNA diversity compared to the mainland population in Switzerland. Over time, we observed large fluctuations in infection prevalence, as well as variation in host haplotype frequencies in both populations. Our long-term observation revealed that N. bombi infection of specific host genotypes is transient: We found that with increasing infection prevalence, proportionally more individuals with haplotype B, but fewer individuals with haplotype A were infected. This suggests that the presence of N. bombi in specific host genotypes relates to infection prevalence. This may be a result of parasite competition, or differential resilience of host types to ward off infections. The findings highlight the important role of host mtDNA haplotypes in the interaction with parasites., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published
2017
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32. The Bee Microbiome: Impact on Bee Health and Model for Evolution and Ecology of Host-Microbe Interactions.

Author

Engel P, Kwong WK, McFrederick Q, Anderson KE, Barribeau SM, Chandler JA, Cornman RS, Dainat J, de Miranda JR, Doublet V, Emery O, Evans JD, Farinelli L, Flenniken ML, Granberg F, Grasis JA, Gauthier L, Hayer J, Koch H, Kocher S, Martinson VG, Moran N, Munoz-Torres M, Newton I, Paxton RJ, Powell E, Sadd BM, Schmid-Hempel P, Schmid-Hempel R, Song SJ, Schwarz RS, vanEngelsdorp D, and Dainat B

Subjects
Animals, Bacteria classification, Bacteria isolation & purification, Bees genetics, Pollination, Symbiosis, Bacteria genetics, Bees microbiology, Bees physiology, Biological Evolution, Microbiota
Abstract

As pollinators, bees are cornerstones for terrestrial ecosystem stability and key components in agricultural productivity. All animals, including bees, are associated with a diverse community of microbes, commonly referred to as the microbiome. The bee microbiome is likely to be a crucial factor affecting host health. However, with the exception of a few pathogens, the impacts of most members of the bee microbiome on host health are poorly understood. Further, the evolutionary and ecological forces that shape and change the microbiome are unclear. Here, we discuss recent progress in our understanding of the bee microbiome, and we present challenges associated with its investigation. We conclude that global coordination of research efforts is needed to fully understand the complex and highly dynamic nature of the interplay between the bee microbiome, its host, and the environment. High-throughput sequencing technologies are ideal for exploring complex biological systems, including host-microbe interactions. To maximize their value and to improve assessment of the factors affecting bee health, sequence data should be archived, curated, and analyzed in ways that promote the synthesis of different studies. To this end, the BeeBiome consortium aims to develop an online database which would provide reference sequences, archive metadata, and host analytical resources. The goal would be to support applied and fundamental research on bees and their associated microbes and to provide a collaborative framework for sharing primary data from different research programs, thus furthering our understanding of the bee microbiome and its impact on pollinator health., (Copyright © 2016 Engel et al.)

Published
2016
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33. Large scale patterns of abundance and distribution of parasites in Mexican bumblebees.

Author

Gallot-Lavallée M, Schmid-Hempel R, Vandame R, Vergara CH, and Schmid-Hempel P

Subjects
Animals, Bayes Theorem, Conservation of Natural Resources, Crithidia genetics, DNA, Protozoan chemistry, Host Specificity, Host-Parasite Interactions, Mexico, Microsatellite Repeats, Nosema genetics, Phylogeny, Population Density, Bees parasitology, Crithidia physiology, Nosema physiology
Abstract

Bumblebees are highly valued for their pollination services in natural ecosystems as well as for agricultural crops. These precious pollinators are known to be declining worldwide, and one major factor contributing to this decline are infections by parasites. Knowledge about parasites in wild bumblebee populations is thus of paramount importance for conservation purposes. We here report the geographical distribution of Crithidia and Nosema, two common parasites of bumblebees, in a yet poorly investigated country: Mexico. Based on sequence divergence of the Cytochrome b and Glycosomal glyceraldehyde phosphate deshydrogenase (gGPDAH) genes, we discovered the presence of a new Crithidia species, which is mainly distributed in the southern half of the country. It is placed by Bayesian inference as a sister species to C. bombi. We suggest the name Crithidia mexicana for this newly discovered organism. A population of C. expoeki was encountered concentrated on the flanks of the dormant volcanic mountain, Iztaccihuatl, and microsatellite data showed evidence of a bottleneck in this population. This study is the first to provide a large-scale insight into the health status of endemic bumblebees in Mexico, based on a large sample size (n=3,285 bees examined) over a variety of host species and habitats., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published
2016
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34. Differential diagnosis of the honey bee trypanosomatids Crithidia mellificae and Lotmaria passim.

Author

Ravoet J, Schwarz RS, Descamps T, Yañez O, Tozkar CO, Martin-Hernandez R, Bartolomé C, De Smet L, Higes M, Wenseleers T, Schmid-Hempel R, Neumann P, Kadowaki T, Evans JD, and de Graaf DC

Subjects
Amino Acid Sequence, Animals, Genes, Protozoan, Genotype, Molecular Sequence Data, Polymerase Chain Reaction, Polymorphism, Restriction Fragment Length, Bees parasitology, Crithidia parasitology, Diagnosis, Differential, Trypanosomatina parasitology
Abstract

Trypanosomatids infecting honey bees have been poorly studied with molecular methods until recently. After the description of Crithidia mellificae (Langridge and McGhee, 1967) it took about forty years until molecular data for honey bee trypanosomatids became available and were used to identify and describe a new trypanosomatid species from honey bees, Lotmaria passim (Evans and Schwarz, 2014). However, an easy method to distinguish them without sequencing is not yet available. Research on the related bumble bee parasites Crithidia bombi and Crithidia expoeki revealed a fragment length polymorphism in the internal transcribed spacer 1 (ITS1), which enabled species discrimination. In search of fragment length polymorphisms for differential diagnostics in honey bee trypanosomatids, we studied honey bee trypanosomatid cell cultures of C. mellificae and L. passim. This research resulted in the identification of fragment length polymorphisms in ITS1 and ITS1-2 markers, which enabled us to develop a diagnostic method to differentiate both honey bee trypanosomatid species without the need for sequencing. However, the amplification success of the ITS1 marker depends probably on the trypanosomatid infection level. Further investigation confirmed that L. passim is the dominant species in Belgium, Japan and Switzerland. We found C. mellificae only rarely in Belgian honey bee samples, but not in honey bee samples from other countries. C. mellificae was also detected in mason bees (Osmia bicornis and Osmia cornuta) besides in honey bees. Further, the characterization and comparison of additional markers from L. passim strain SF (published as C. mellificae strain SF) and a Belgian honey bee sample revealed very low divergence in the 18S rRNA, ITS1-2, 28S rRNA and cytochrome b sequences. Nevertheless, a variable stretch was observed in the gp63 virulence factor., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published
2015
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35. A depauperate immune repertoire precedes evolution of sociality in bees.

Author

Barribeau SM, Sadd BM, du Plessis L, Brown MJ, Buechel SD, Cappelle K, Carolan JC, Christiaens O, Colgan TJ, Erler S, Evans J, Helbing S, Karaus E, Lattorff HM, Marxer M, Meeus I, Näpflin K, Niu J, Schmid-Hempel R, Smagghe G, Waterhouse RM, Yu N, Zdobnov EM, and Schmid-Hempel P

Subjects
Animals, Bees classification, Female, Gene Expression Regulation, Genes, Insect, Genetic Variation, Male, Selection, Genetic, Bees genetics, Bees immunology, Behavior, Animal, Evolution, Molecular, Social Behavior
Abstract

Background: Sociality has many rewards, but can also be dangerous, as high population density and low genetic diversity, common in social insects, is ideal for parasite transmission. Despite this risk, honeybees and other sequenced social insects have far fewer canonical immune genes relative to solitary insects. Social protection from infection, including behavioral responses, may explain this depauperate immune repertoire. Here, based on full genome sequences, we describe the immune repertoire of two ecologically and commercially important bumblebee species that diverged approximately 18 million years ago, the North American Bombus impatiens and European Bombus terrestris., Results: We find that the immune systems of these bumblebees, two species of honeybee, and a solitary leafcutting bee, are strikingly similar. Transcriptional assays confirm the expression of many of these genes in an immunological context and more strongly in young queens than males, affirming Bateman's principle of greater investment in female immunity. We find evidence of positive selection in genes encoding antiviral responses, components of the Toll and JAK/STAT pathways, and serine protease inhibitors in both social and solitary bees. Finally, we detect many genes across pathways that differ in selection between bumblebees and honeybees, or between the social and solitary clades., Conclusions: The similarity in immune complement across a gradient of sociality suggests that a reduced immune repertoire predates the evolution of sociality in bees. The differences in selection on immune genes likely reflect divergent pressures exerted by parasites across social contexts.

Published
2015
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36. The genomes of two key bumblebee species with primitive eusocial organization.

Author

Sadd BM, Barribeau SM, Bloch G, de Graaf DC, Dearden P, Elsik CG, Gadau J, Grimmelikhuijzen CJ, Hasselmann M, Lozier JD, Robertson HM, Smagghe G, Stolle E, Van Vaerenbergh M, Waterhouse RM, Bornberg-Bauer E, Klasberg S, Bennett AK, Câmara F, Guigó R, Hoff K, Mariotti M, Munoz-Torres M, Murphy T, Santesmasses D, Amdam GV, Beckers M, Beye M, Biewer M, Bitondi MM, Blaxter ML, Bourke AF, Brown MJ, Buechel SD, Cameron R, Cappelle K, Carolan JC, Christiaens O, Ciborowski KL, Clarke DF, Colgan TJ, Collins DH, Cridge AG, Dalmay T, Dreier S, du Plessis L, Duncan E, Erler S, Evans J, Falcon T, Flores K, Freitas FC, Fuchikawa T, Gempe T, Hartfelder K, Hauser F, Helbing S, Humann FC, Irvine F, Jermiin LS, Johnson CE, Johnson RM, Jones AK, Kadowaki T, Kidner JH, Koch V, Köhler A, Kraus FB, Lattorff HM, Leask M, Lockett GA, Mallon EB, Antonio DS, Marxer M, Meeus I, Moritz RF, Nair A, Näpflin K, Nissen I, Niu J, Nunes FM, Oakeshott JG, Osborne A, Otte M, Pinheiro DG, Rossié N, Rueppell O, Santos CG, Schmid-Hempel R, Schmitt BD, Schulte C, Simões ZL, Soares MP, Swevers L, Winnebeck EC, Wolschin F, Yu N, Zdobnov EM, Aqrawi PK, Blankenburg KP, Coyle M, Francisco L, Hernandez AG, Holder M, Hudson ME, Jackson L, Jayaseelan J, Joshi V, Kovar C, Lee SL, Mata R, Mathew T, Newsham IF, Ngo R, Okwuonu G, Pham C, Pu LL, Saada N, Santibanez J, Simmons D, Thornton R, Venkat A, Walden KK, Wu YQ, Debyser G, Devreese B, Asher C, Blommaert J, Chipman AD, Chittka L, Fouks B, Liu J, O'Neill MP, Sumner S, Puiu D, Qu J, Salzberg SL, Scherer SE, Muzny DM, Richards S, Robinson GE, Gibbs RA, Schmid-Hempel P, and Worley KC

Subjects
Animals, Bee Venoms genetics, Bees classification, Bees physiology, Chemoreceptor Cells metabolism, Chromosome Mapping, Databases, Genetic, Evolution, Molecular, Female, Gene Expression Regulation, Gene Rearrangement, Genomics, Interspersed Repetitive Sequences, Male, Open Reading Frames, Polymorphism, Single Nucleotide, Selenoproteins genetics, Selenoproteins metabolism, Sequence Analysis, DNA, Species Specificity, Synteny, Bees genetics, Behavior, Animal, Genes, Insect, Social Behavior
Abstract

Background: The shift from solitary to social behavior is one of the major evolutionary transitions. Primitively eusocial bumblebees are uniquely placed to illuminate the evolution of highly eusocial insect societies. Bumblebees are also invaluable natural and agricultural pollinators, and there is widespread concern over recent population declines in some species. High-quality genomic data will inform key aspects of bumblebee biology, including susceptibility to implicated population viability threats., Results: We report the high quality draft genome sequences of Bombus terrestris and Bombus impatiens, two ecologically dominant bumblebees and widely utilized study species. Comparing these new genomes to those of the highly eusocial honeybee Apis mellifera and other Hymenoptera, we identify deeply conserved similarities, as well as novelties key to the biology of these organisms. Some honeybee genome features thought to underpin advanced eusociality are also present in bumblebees, indicating an earlier evolution in the bee lineage. Xenobiotic detoxification and immune genes are similarly depauperate in bumblebees and honeybees, and multiple categories of genes linked to social organization, including development and behavior, show high conservation. Key differences identified include a bias in bumblebee chemoreception towards gustation from olfaction, and striking differences in microRNAs, potentially responsible for gene regulation underlying social and other traits., Conclusions: These two bumblebee genomes provide a foundation for post-genomic research on these key pollinators and insect societies. Overall, gene repertoires suggest that the route to advanced eusociality in bees was mediated by many small changes in many genes and processes, and not by notable expansion or depauperation.

Published
2015
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37. The invasion of southern South America by imported bumblebees and associated parasites.

Author

Schmid-Hempel R, Eckhardt M, Goulson D, Heinzmann D, Lange C, Plischuk S, Escudero LR, Salathé R, Scriven JJ, and Schmid-Hempel P

Subjects
Animals, Argentina, Chile, Crithidia genetics, DNA, Protozoan genetics, Host-Parasite Interactions, Molecular Sequence Data, Nosema genetics, Phylogeny, Sequence Analysis, DNA, Animal Distribution, Bees parasitology, Bees physiology, Crithidia isolation & purification, Introduced Species, Nosema isolation & purification
Abstract

The Palaearctic Bombus ruderatus (in 1982/1983) and Bombus terrestris (1998) have both been introduced into South America (Chile) for pollination purposes. We here report on the results of sampling campaigns in 2004, and 2010-2012 showing that both species have established and massively expanded their range. Bombus terrestris, in particular, has spread by some 200 km year(-1) and had reached the Atlantic coast in Argentina by the end of 2011. Both species, and especially B. terrestris, are infected by protozoan parasites that seem to spread along with the imported hosts and spillover to native species. Genetic analyses by polymorphic microsatellite loci suggest that the host population of B. terrestris is genetically diverse, as expected from a large invading founder population, and structured through isolation by distance. Genetically, the populations of the trypanosomatid parasite, Crithidia bombi, sampled in 2004 are less diverse, and distinct from the ones sampled later. Current C. bombi populations are highly heterozygous and also structured through isolation by distance correlating with the genetic distances of B. terrestris, suggesting the latter's expansion to be a main structuring factor for the parasite. Remarkably, wherever B. terrestris spreads, the native Bombus dahlbomii disappears although the reasons remain unclear. Our ecological and genetic data suggest a major invasion event that is currently unfolding in southern South America with disastrous consequences for the native bumblebee species., (© 2013 The Authors. Journal of Animal Ecology © 2013 British Ecological Society.)

Published
2014
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38. Probing mixed-genotype infections I: extraction and cloning of infections from hosts of the trypanosomatid Crithidia bombi.

Author

Salathé R, Tognazzo M, Schmid-Hempel R, and Schmid-Hempel P

Subjects
Animals, Crithidia genetics, Bees parasitology, Cloning, Organism methods, Crithidia isolation & purification, Host-Parasite Interactions genetics
Abstract

We here present an efficient, precise and reliable method to isolate and cultivate healthy and viable single Crithidia bombi cells from bumblebee faeces using flow cytometry. We report a precision of >99% in obtaining single trypanosomatid cells for further culture and analysis ("cloning"). In the study, we have investigated the use of different liquid media to cultivate C. bombi and present an optimal medium for obtaining viable clones from all tested, infected host donors. We show that this method can be applied to genotype a collection of clones from natural infections. Furthermore, we show how to cryo-preserve C. bombi cells to be revived to become infective clones after at least 4 years of storage. Considering the high prevalence of infections in natural populations, our method provides a powerful tool in studying the level and diversity of these infections, and thus enriches the current methodology for the studies of complex host-parasite interactions.

Published
2012
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39. Diversity of Nosema associated with bumblebees (Bombus spp.) from China.

Author

Li J, Chen W, Wu J, Peng W, An J, Schmid-Hempel P, and Schmid-Hempel R

Subjects
Animals, China, Cluster Analysis, DNA, Fungal chemistry, DNA, Fungal genetics, DNA, Ribosomal chemistry, DNA, Ribosomal genetics, Genes, rRNA, Haplotypes, Molecular Sequence Data, Nosema genetics, Phylogeny, RNA, Fungal genetics, RNA, Ribosomal, 18S genetics, Sequence Analysis, DNA, Bees microbiology, Genetic Variation, Nosema classification, Nosema isolation & purification
Abstract

Bumblebees (Bombus spp.) are important pollinators of many economically important crops and microsporidia are among the most important infections of these hosts. Using molecular markers, we screened a large sample (n=1,009 bees) of workers of 27 different Bombus spp. from China (Sichuan, Qinghai, Inner Mongolia, and Gansu provinces). The results showed that 62 individuals representing 12 Bombus spp. were infected by microsporidia with an overall prevalence of 6.1%. Based on the haplotypes (ssrRNA sequences), we confirmed the presence of Nosema bombi, Nosema ceranae and (likely) Nosema thomsoni. In addition, four new putatively novel taxa were identified by phylogenetic reconstruction: Nosema A, Nosema B-complex, Nosema C-complex and Nosema D-complex. In many cases, hosts were infected by more than one Nosema taxon. Possible caveats of sequence analyses are discussed., (Copyright © 2011 Australian Society for Parasitology Inc. Published by Elsevier Ltd. All rights reserved.)

Published
2012
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40. Probing mixed-genotype infections II: high multiplicity in natural infections of the trypanosomatid, Crithidia bombi, in its host, Bombus spp.

Author

Tognazzo M, Schmid-Hempel R, and Schmid-Hempel P

Subjects
Animals, Crithidia pathogenicity, Genetic Variation, Genotype, Microsatellite Repeats genetics, Switzerland, Trypanosomatina genetics, Trypanosomatina pathogenicity, Bees genetics, Bees parasitology, Coinfection genetics, Crithidia genetics, Host-Parasite Interactions genetics
Abstract

Mixed-genotype infections have major consequences for many essential elements of host-parasite interactions. With genetic exchange between co-infecting parasite genotypes increased diversity among parasite offspring and the emergence of novel genotypes from infected hosts is possible. We here investigated mixed- genotype infections using the host, Bombus spp. and its trypanosome parasite Crithidia bombi as our study case. The natural infections of C. bombi were genotyped with a novel method for a representative sample of workers and spring queens in Switzerland. We found that around 60% of all infected hosts showed mixed-genotype infections with an average of 2.47±0.22 (S.E.) and 3.65±1.02 genotypes per worker or queen, respectively. Queens, however, harboured up to 29 different genotypes. Based on the genotypes of co-infecting strains, these could be putatively assigned to either 'primary' and 'derived' genotypes - the latter resulting from genetic exchange among the primary genotypes. High genetic relatedness among co-infecting derived but not primary genotypes supported this scenario. Co-infection in queens seems to be a major driver for the diversity of genotypes circulating in host populations.

Published
2012
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41. Genetic exchange and emergence of novel strains in directly transmitted trypanosomatids.

Author

Schmid-Hempel R, Salathé R, Tognazzo M, and Schmid-Hempel P

Subjects
Animals, Crithidia physiology, Female, Genetic Loci, Genetic Variation, Genotype, Heredity, Humans, Loss of Heterozygosity, Multilocus Sequence Typing, Recombination, Genetic, Bees parasitology, Crithidia genetics
Abstract

The breeding structure of protozoan infections, i.e. whether and how frequently parasites exchange genes ("sexual reproduction"), is a crucially important parameter for many important questions; it also matters for how new virulent strains might emerge. Whether protozoan parasites are clonal or sexual is therefore a hotly debated issue. For trypanosomatids, few experimental tests of breeding structure exist to date and are limited to the vector-borne human diseases Trypanosoma brucei, Trypanosoma cruzi, and Leishmania major. We infected the natural host (Bombus terrestris) of the monoxenous parasite Crithidia bombi (Trypanosomatida) either with a single strain of the parasite or in mixed infections and tested for genetic exchange among co-infecting strains using microsatellite markers. We show that strains regularly exchange genetic material, with occasional self-crossing during mixed infections. Most offspring clones fit the expected allelic pattern from a standard Mendelian segregation. In some cases, alleles are lost or gained, leading to an entirely new genotype different from either parent. Genetic exchange in C. bombi therefore does occur and the process also leads to allelic loss or gain that could result from slippage during recombination. The majority of novel offspring types correspond to a recombination of parental alleles. The case of C. bombi demonstrates that directly transmitted, monoxenic trypanosomatids can also exchange genes. Sex therefore seems to be found in very different lineages of the trypanosomatids. Furthermore, the data allowed estimating a frequency at which C. bombi shows genetic exchange in populations., (Copyright © 2011 Elsevier B.V. All rights reserved.)

Published
2011
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42. A second generation genetic map of the bumblebee Bombus terrestris (Linnaeus, 1758) reveals slow genome and chromosome evolution in the Apidae.

Author

Stolle E, Wilfert L, Schmid-Hempel R, Schmid-Hempel P, Kube M, Reinhardt R, and Moritz RF

Subjects
Animals, Quantitative Trait Loci, Bees genetics, Biological Evolution, Chromosome Mapping methods, Genome, Insect genetics
Abstract

Background: The bumblebee Bombus terrestris is an ecologically and economically important pollinator and has become an important biological model system. To study fundamental evolutionary questions at the genomic level, a high resolution genetic linkage map is an essential tool for analyses ranging from quantitative trait loci (QTL) mapping to genome assembly and comparative genomics. We here present a saturated linkage map and match it with the Apis mellifera genome using homologous markers. This genome-wide comparison allows insights into structural conservations and rearrangements and thus the evolution on a chromosomal level., Results: The high density linkage map covers ~ 93% of the B. terrestris genome on 18 linkage groups (LGs) and has a length of 2'047 cM with an average marker distance of 4.02 cM. Based on a genome size of ~ 430 Mb, the recombination rate estimate is 4.76 cM/Mb. Sequence homologies of 242 homologous markers allowed to match 15 B. terrestris with A. mellifera LGs, five of them as composites. Comparing marker orders between both genomes we detect over 14% of the genome to be organized in synteny and 21% in rearranged blocks on the same homologous LG., Conclusions: This study demonstrates that, despite the very high recombination rates of both A. mellifera and B. terrestris and a long divergence time of about 100 million years, the genomes' genetic architecture is highly conserved. This reflects a slow genome evolution in these bees. We show that data on genome organization and conserved molecular markers can be used as a powerful tool for comparative genomics and evolutionary studies, opening up new avenues of research in the Apidae.

Published
2011
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43. Molecular divergence defines two distinct lineages of Crithidia bombi (Trypanosomatidae), parasites of bumblebees.

Author

Schmid-Hempel R and Tognazzo M

Subjects
Animals, Crithidia cytology, Crithidia isolation & purification, Cytochromes b genetics, DNA, Protozoan genetics, DNA, Ribosomal Spacer genetics, Evolution, Molecular, Glyceraldehyde-3-Phosphate Dehydrogenases genetics, Molecular Sequence Data, Phylogeny, Protozoan Proteins genetics, Bees parasitology, Crithidia classification, Crithidia genetics
Abstract

This study provides, for the first time, sequence data for the protozoan flagellates Crithidia bombi and Crithidia mellificae (Kinetoplastea: Trypanosomatidae). We amplified the partial sequences of the small subunit ribosomal RNA (SSU rRNA), glycosomal glyceraldehyde phosphate dehydrogenase (gGAPDH), cytochrome b (Cyt b), and the complete internal transcribed spacer region 1 (ITS1) of the ribosomal RNA gene region for 66 clones of C. bombi from Switzerland and Alaska. Furthermore, we sequenced the same stretch of SSU rRNA and gGAPDH for one isolate of C. mellificae from Switzerland. All four molecular markers classified the C. bombi samples into two distinct lineages A and B. Both lineages were found in the two sampling locations. Variation within lineages was small or non-existing. Sequence differences between lineages were 1.64% for SSU rRNA, 4.36% for gGAPDH, and 12.02% for Cyt b. The ITS1-sequences of lineages A and B have diverged so much that no alignment was possible. With regard to ITS1, we additionally found fragment length polymorphism (variation in microsatellite repeat numbers) as well as nucleotide diversity within each lineage. Furthermore, the sequences of SSU rRNA and gGAPDH of C. mellificae were different from both lineages of C. bombi. The separation of lineages A and B, based on sequence differences and phylogenetic reconstruction, is so pronounced as to characterize two species of "C. bombi." We propose to retain C. bombi for the more common lineage A and suggest the name Crithidia expoeki n. sp. for lineage B.

Published
2010
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44. Novel microsatellite DNA loci for Bombus terrestris (Linnaeus, 1758).

Author

Stolle E, Rohde M, Vautrin D, Solignac M, Schmid-Hempel P, Schmid-Hempel R, and Moritz RF

Abstract

We present details and characteristics of 123 novel polymorphic microsatellite DNA loci for Bombus terrestris. Thirty-four of these loci have been tested in nine other Bombus species and 25 of them showed polymorphisms in at least one species. These microsatellite DNA loci together with the already established 60 loci will be useful for characterizing wild and managed populations of B. terrestris and other Bombus species as well as for detailed genetic studies in including mapping studies and genome annotations., (© 2009 Blackwell Publishing Ltd.)

Published
2009
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45. Heritability of sperm length in the bumblebee Bombus terrestris.

Author

Baer B, de Jong G, Schmid-Hempel R, Schmid-Hempel P, Høeg JT, and Boomsma JJ

Subjects
Analysis of Variance, Animals, Body Size, Female, Genetic Variation, Male, Models, Genetic, Selection, Genetic, Bees genetics, Quantitative Trait, Heritable, Spermatozoa cytology
Abstract

Sperm length is highly variable, both between and within species, but the evolutionary significance of this variation is poorly understood. Sexual selection on sperm length requires a significant additive genetic variance, but few studies have actually measured this. Here we present the first estimates of narrow sense heritability of sperm length in a social insect, the bumblebee Bombus terrestris. In spite of a balanced and straightforward rearing design of colonies, and the possibility to replicate measurements of sperm within single males nested within colonies, the analysis proved to be complex. Several appropriate statistical models were derived, each depending on different assumptions. The heritability estimates obtained ranged from h (2) = 0.197 +/- 0.091 to h (2) = 0.429 +/- 0.154. All our estimates were substantially lower than previous estimates of sperm length heritability in non-social insects and vertebrates.

Published
2006
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46. Trans-generational immune priming in a social insect.

Author

Sadd BM, Kleinlogel Y, Schmid-Hempel R, and Schmid-Hempel P

Subjects
Animals, Arthrobacter physiology, Bees microbiology, Female, Immunity, Maternally-Acquired physiology, Bees immunology
Abstract

Detecting functional homology between invertebrate and vertebrate immunity is of interest in terms of understanding the dynamics and evolution of immune systems. Trans-generational effects on immunity are well known from vertebrates, but their existence in invertebrates remains controversial. Earlier work on invertebrates has interpreted increased offspring resistance to pathogens as trans-generational immune priming. However, interpretation of these earlier studies involves some caveats and thus full evidence for a direct effect of maternal immune experience on offspring immunity is still lacking in invertebrates. Here we show that induced levels of antibacterial activity are higher in the worker offspring of the bumblebee, Bombus terrestris L. when their mother queen received a corresponding immune challenge prior to colony founding. This shows trans-generational immune priming in an insect, with ramifications for the evolution of sociality.

Published
2005
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47. DYNAMIC AND GENETIC CONSEQUENCES OF VARIATION IN HORIZONTAL TRANSMISSION FOR A MICROPARASITIC INFECTION.

Author

Schmid-Hempel P, Puhr K, Krüger N, Reber C, and Schmid-Hempel R

Abstract

Transmission to a new host is a critical step in the life cycle of a parasite. Variation in the characteristics of the transmission process, for example, due to host demography, is assumed to select for different variants of the parasite. We have experimentally tested how variation in the time to transmission (early or late after infection) and exposure to adverse conditions outside the host (immediate or delayed contact with new host) interact to determine the success of the infection in the next host, using the trypanosome Crithidia bombi infecting its bumblebee host, Bombus terrestris. These two experimentally manageable steps mimic the processes of within- and among-host selection for the parasite. We found that early transmission led to higher infection success in the next host as did immediate contact with the new host. However, there was no interaction between the two parameters as would be expected if early-transmitted variants, resulting from rapid multiplication within the host, would be less adapted to the conditions encountered during the between-host transfer or infection of the next host. Furthermore, typing the genetic variability of the parasites with microsatellites showed that the four different transmission routes of our experiment selected for different degrees of allelic diversity of the infecting parasite populations. The results support the idea that variation in the transmission process selects for different genotypic variants of the parasite. At the same time, the relationship of allelic diversity with infection intensity suggested that the coinfection model of May and Nowak (1995) may be appropriate, where each parasite is able to infect and multiply independent of others within the same host., (© 1999 The Society for the Study of Evolution.)

Published
1999
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48. Host choice and fitness correlates for conopid flies parasitising bumblebees.

Author

Schmid-Hempel R and Schmid-Hempel P

Abstract

Two parasitoid flies,Physocephala rufipes andSicus ferrugineus (Diptera, Conopidae), and their hosts,Bombus spp., coexist at various locations in northwestern Switzerland. A detailed field study showed that both conopid species use the hostB. pascuorum to a similar degree, while the hostB. terr-luc (a pooled category ofB. terrestris andB. lucorum) is more frequently parasitised than expected byS. ferrugineus. The hostB. lapidarius in turn is exclusively used byP. rufipes. Furthermore, hosts ofB. terr-luc andB. pascuorum parasitised byS. ferrugineus were larger than hosts parasitised byP. rufipes, or than those not parasitised. The findings suggest thatS. ferrugineus selects larger hosts and may displaceP. rufipes. Pupal weight, a predictor of adult body size and parasitoid fecundity, is positively correlated with host size and larger pupae are more likely to emerge, while host species had no effect on the probability of emergence in either conopid species. Host species affected pupal weight inS. ferrugineus, but not inP. rufipes, althoughP. rufipes grew larger in hosts of a given size. Daughters emerged from larger pupae than males, but this did not correlate with larger host sizes. These observations add to the scarce knowledge of dipteran parasitoids.

Published
1996
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49. Endoparasitic flies, pollen-collection by bumblebees and a potential host-parasite conflict.

Author

Schmid-Hempel R and Schmid-Hempel P

Abstract

Conopid flies (Conopidae, Diptera) are common larval parasites of bumblebees. The larva develops inside the abdomen of workers, queens and males. Development is completed within 10-12 days after oviposition when the host is killed and the parasite pupates in situ. Development results in parasitised bees becoming unable to carry large loads of nectar, as the conopid larvae reside where the honey crop is normally located. Furthermore, an addition to the bee's unloaden body mass is likely (average larval weight reached at pupation by the common parasite species Sicus ferrugineus: ±SD 36.3±12.3 mg, n=59; by Physocephala rufipes: 55.8±16.9 mg, n=108). We here asked whether the propensity of workers of the bumblebee Bombus pascuorum to collect nectar rather than pollen is related to the presence of conopid larvae. For samples of bees (n=2254 workers) collected over 3 years of field studies in northwestern Switzerland, there was no difference in the frequency of bees caught as pollen collectors among parasitised (38.1% of cases, n=210) as compared to non-parastised bees (43.9%, n=360) (χ 2 =1.83, n.s.). However, compared to the non-parasitised bees (n=360), those hosts containing a third (last) instar larva (n=9) were less likely to collect pollen than expected by chance χ 2 =6.91, P=0.003. Similarly, hosts with short survival time between capture and being killed by the developing larva (which hence must have harboured a late instar parasite at time of capture) were less likely to collect pollen (8%, n=25) than those found not parasitised (37.6%, n=891 χ 2 =9.16, P<0.001). Late instar larvae grow so big that they fill the entire abdomen. Although there was also a tendency for presumably older bees to collect less pollen, this is unlikely to explain the observations. We also discuss whether these changes in foraging behaviour of bumblebees may reflect a host-parasite conflict over the type of resource to be collected.

Published
1991
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