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103. Temporal dynamics and diversity of avian malaria in a single host species

Author

Bensch, Staffan, Waldenström, Jonas, Jonzén, Niclas, Westerdahl, Helena, Hansson, Bengt, Sejberg, Douglas, Hasselquist, Dennis, Bensch, Staffan, Waldenström, Jonas, Jonzén, Niclas, Westerdahl, Helena, Hansson, Bengt, Sejberg, Douglas, and Hasselquist, Dennis

Published
2007

104. No evidence of an MHC-based female mating preference in great reed warblers

Author

Westerdahl, Helena and Westerdahl, Helena

Abstract

Female mate-choice based on genetic compatibility is an area of growing interest. The major histocompatibility complex (MHC) genes are likely candidates for such mate-choice since these highly polymorphic genes may both increase offspring viability and also provide direct cues for mate-choice. In great reed warblers, females actively choose a breeding partner out of a handful of males that they visit and evaluate; thus, female preference for compatible or heterozygous MHC genes could have evolved. Here, I investigate whether great reed warbler females preferentially mate with males with dissimilar MHC class I alleles or with males that are heterozygous at MHC class I. Despite favourable conditions, a thorough screening method and a large sample size, there was no evidence of an MHC-based female mating preference based on either genetic compatibility or heterozygosity in this population. Power analyses of the data sets revealed that relatively small differences (15% and 8%, respectively) between true and random pairs should have been detected.

Published
2004

105. Observation of a ZZW female in a natural population: implications for avian sex determination

Author

Arlt, D, Bensch, Staffan, Hansson, Bengt, Hasselquist, Dennis, Westerdahl, Helena, Arlt, D, Bensch, Staffan, Hansson, Bengt, Hasselquist, Dennis, and Westerdahl, Helena

Abstract

Avian sex determination is chromosomal; however, the underlying mechanisms are not yet understood. There is no conclusive evidence for either of two proposed mechanisms: a dominant genetic switch or a dosage mechanism. No dominant sex-determining gene on the female-specific W chromosome has been found. Birds lack inactivation of one of the Z chromosomes in males, but seem to compensate for a double dose of Z-linked genes by other mechanisms. Recent studies showing female-specific expression of two genes may support an active role of the W chromosome. To resolve the question of avian sex determination the investigation of birds with a 2A: ZZW or 2A: Z0 genotype would be decisive. Here, we report the case of an apparent 2A: ZZW great reed warbler (Acrocephalus arundinaceus) female breeding in a natural population, which was detected using Z-linked microsatellites. Our data strongly suggest a role of W-linked genes in avian sex determination.

Published
2004

108. Diversity, Loss, and Gain of Malaria Parasites in a Globally Invasive Bird

Author

Marzal, Alfonso, primary, Ricklefs, Robert E., additional, Valkiūnas, Gediminas, additional, Albayrak, Tamer, additional, Arriero, Elena, additional, Bonneaud, Camille, additional, Czirják, Gábor A., additional, Ewen, John, additional, Hellgren, Olof, additional, Hořáková, Dita, additional, Iezhova, Tatjana A., additional, Jensen, Henrik, additional, Križanauskienė, Asta, additional, Lima, Marcos R., additional, de Lope, Florentino, additional, Magnussen, Eyðfinn, additional, Martin, Lynn B., additional, Møller, Anders P., additional, Palinauskas, Vaidas, additional, Pap, Péter L., additional, Pérez-Tris, Javier, additional, Sehgal, Ravinder N. M., additional, Soler, Manuel, additional, Szöllősi, Eszter, additional, Westerdahl, Helena, additional, Zetindjiev, Pavel, additional, and Bensch, Staffan, additional

Published
2011
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110. MHC diversity in two Acrocephalus species: the outbred Great reed warbler and the inbred Seychelles warbler

Author

Richardson, David, Westerdahl, Helena, Richardson, David, and Westerdahl, Helena

Abstract

The Great reed warbler (GRW) and the Seychelles warbler (SW) are congeners with markedly different demographic histories. The GRW is a normal outbred bird species while the SW population remains isolated and inbred after undergoing a severe population bottleneck. We examined variation at Major Histocompatibility Complex (MHC) class I exon 3 using restriction fragment length polymorphism, denaturing gradient gel electrophoresis and DNA sequencing. Although genetic variation was higher in the GRW, considerable variation has been maintained in the SW. The ten exon 3 sequences found in the SW were as diverged from each other as were a random sub-sample of the 67 sequences from the GRW. There was evidence for balancing selection in both species, and the phylogenetic analysis showing that the exon 3 sequences did not separate according to species, was consistent with transspecies evolution of the MHC.

Published
2003

113. House sparrow Passer domesticus survival is not associated with MHC-I diversity, but possibly with specific MHC-I alleles.

Author

Karlsson, Maria, Schroeder, Julia, Nakagawa, Shinichi, Smith, Henrik G., Burke, Terry, and Westerdahl, Helena

Subjects
ENGLISH sparrow, MAJOR histocompatibility complex, IMMUNE system, PATHOGENIC microorganisms
Abstract

The MHC (Major Histocompatibility Complex) plays an important role in the immune system of vertebrates. MHC genes are extremely polymorphic and this variation is considered to be maintained by selection from pathogens. We investigate whether MHC diversity (number of different alleles per individual) affects the survival and recruitment of nestling house sparrows. We hypothesize that individuals with higher MHC diversity can recognize and combat a wider range of pathogens, and therefore are more likely to survive and recruit into the breeding population. Additionally, we hypothesize that specific MHC class I alleles (MHC-I) could be associated with survival and recruitment. We screened MHC-I genotypes in 518 house sparrow chicks hatched on Lundy Island but we found no evidence for a relationship between nestling survival, post-fledging survival or recruitment success with MHC diversity. Then we investigated effects of specific MHC-I alleles in 195 individuals from a single cohort. Twenty-one MHC-I alleles were tested for relationships with nestling survival, post-fledging survival and recruitment, and we detected associations with survival for three different alleles. This pattern was, however, not different to what would be expected from random, so we could not conclude that particular MHC-I alleles are associated with survival in house sparrows on Lundy Island. Nonetheless, one of these alleles (1105) showed both a tendency for a higher probability of surviving in nestlings, and a significant association with survival in fledglings. We envision that allele 1105 could be an interesting candidate gene for testing associations with survival in house sparrows in the future. [ABSTRACT FROM AUTHOR]

Published
2015
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121. Gene duplication and fragmentation in the zebrafinch major histocompatibility complex.

Author

Balakrishnan, Christopher N., Ekblom, Robert, Völker, Martin, Westerdahl, Helena, Godinez, Ricardo, Kotkiewicz, Holly, Burt, David W., Graves, Tina, Griffin, Darren K., Warren, Wesley C., and Edwards, Scott V.

Subjects
ZEBRA finch, BACTERIAL artificial chromosomes, MAJOR histocompatibility complex, POLYMORPHISM (Zoology), CHICKENS, TAENIOPYGIA
Abstract

Background: Due to its high polymorphism and importance for disease resistance, the major histocompatibility complex (MHC) has been an important focus of many vertebrate genome projects. Avian MHC organization is of particular interest because the chicken Gallus gallus, the avian species with the best characterized MHC, possesses a highly streamlined minimal essential MHC, which is linked to resistance against specific pathogens. It remains unclear the extent to which this organization describes the situation in other birds and whether it represents a derived or ancestral condition. The sequencing of the zebra finch Taeniopygia guttata genome, in combination with targeted bacterial artificial chromosome (BAC) sequencing, has allowed us to characterize an MHC from a highly divergent and diverse avian lineage, the passerines. Results: The zebra finch MHC exhibits a complex structure and history involving gene duplication and fragmentation. The zebra finch MHC includes multiple Class I and Class II genes, some of which appear to be pseudogenes, and spans a much more extensive genomic region than the chicken MHC, as evidenced by the presence of MHC genes on each of seven BACs spanning 739 kb. Cytogenetic (FISH) evidence and the genome assembly itself place core MHC genes on as many as four chromosomes with TAP and Class I genes mapping to different chromosomes. MHC Class II regions are further characterized by high endogenous retroviral content. Lastly, we find strong evidence of selection acting on sites within passerine MHC Class I and Class II genes. Conclusion: The zebra finch MHC differs markedly from that of the chicken, the only other bird species with a complete genome sequence. The apparent lack of synteny between TAP and the expressed MHC Class I locus is in fact reminiscent of a pattern seen in some mammalian lineages and may represent convergent evolution. Our analyses of the zebra finch MHC suggest a complex history involving chromosomal fission, gene duplication and translocation in the history of the MHC in birds, and highlight striking differences in MHC structure and organization among avian lineages. [ABSTRACT FROM AUTHOR]

Published
2010
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122. Temporal dynamics and diversity of avian malaria parasites in a single host species.

Author

BENSCH, STAFFAN, WALDENSTRÖM, JONAS, JONZÉN, NICLAS, WESTERDAHL, HELENA, HANSSON, BENGT, SEJBERG, DOUGLAS, and HASSELQUIST, DENNIS

Subjects
AVIAN malaria, POULTRY diseases, PARASITISM, REED warblers, PLASMODIUM, PARASITE antigens, CYTOCHROME b, HOST-parasite relationships, COEVOLUTION, SEXUAL selection
Abstract

1. We have used molecular methods to unravel a remarkable diversity of parasite lineages in a long-term population study of great reed warblers Acrocephalus arundinaceus that was not foreseen from traditional microscopic examination of blood smears . This diversity includes eight Haemoproteus and 10 Plasmodium lineages of which most probably represent good biological species. 2. Contrary to expectation, the relative frequency of parasite lineages seemed not to change over the 17-year study period and we found no effects of the parasites on a male secondary sexual ornament (song repertoire size) and two measures of fitness (adult survival and production of recruited offspring). 3. We discuss whether the absence of fitness consequences of the parasites might relate to the fact that we have studied the host at the breeding sites in Europe, whereas the transmission seems to take place at the wintering sites in Africa, where the naïve birds encounter the parasites for the first time and the resulting primary infections likely make them sicker than during the chronic phase of the infection. 4. The prevalence of the three most common lineages appeared to fluctuate in parallel with a periodicity of approximately 3–4 years. Theoretical models based on intrinsic interactions between parasite antigen and host immune genes cannot explain such dynamics, suggesting that knowledge of extrinsic parameters such as vector distribution and alternative hosts are required to understand these patterns. [ABSTRACT FROM AUTHOR]

Published
2007
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123. TERMINAL INVESTMENT INDUCED BY IMMUNE CHALLENGE AND FITNESS TRAITS ASSOCIATED WITH MAJOR HISTOCOMPATIBILITY COMPLEX IN THE HOUSE SPARROW.

Author

Bonneaud, Camille, Mazuc, Jeremy, Chastel, Olivier, Westerdahl, Helena, Sorci, Gabriele, and Poulin, R.

Subjects
BREEDING, ENGLISH sparrow, SPARROWS, VACCINES, IMMUNE system
Abstract

The terminal investment hypothesis predicts that individuals should invest more in their present reproduction if they are less likely to survive to future reproductive events. Infections, which reduce viability, may be used by individuals as a cue of a diminishing residual reproductive value and could therefore theoretically trigger an intensification of breeding effort. We tested this hypothesis in a natural population of house sparrows (Passer domesticus). We manipulated the immune system of breeding females by injecting them with a vaccine against the Paramyxo virus, the agent of Newcastle disease. Females were captured and treated immediately after completion of their first clutch either with the vaccine (NDV) or with phosphate buffered saline (PBS). The entire clutch was subsequently removed. We also screened Mhc class I genes of females to assess possible genotype-by- immune treatment interactions on reproductive investment. Out results indicate that vaccinated females were more likely to lay replacement clutches and that the difference in number of eggs between first and replacement clutches was greater for NDV females than for controls. In addition, chick size, both in terms of tarsus length and body mass, was affected by immune activation but in interaction with nestling age and female body mass, respectively. Mhc genotype-by-immune treatment interactions were never significant; however, allelic diversity was positively correlated with nestling survival. These results show that immune system activation is potentially used as a cue of reduced survival prospect and appears to induce a costly terminal investment behavior, and Mhc diversity might be under selection in a natural population of house sparrows. [ABSTRACT FROM AUTHOR]

Published
2004
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124. DOES LINKAGE DISEQUILIBRIUM GENERATE HETEROZYGOSITY-FITNESS CORRELATIONS IN GREAT REED WARBLERS?

Author

Hansson, Bengt, Westerdahl, Helena, Hasselquist, Dennis, Åkesson, Mikael, Bensch, Staffan, and Hey, J.

Subjects
*GENETIC markers, *HETEROZYGOSITY, *MICROSATELLITE repeats, *CHROMOSOMES, *INBREEDING
Abstract

Heterozygosity-fitness correlations (HFCs) at noncoding genetic markers are commonly assumed to reflect fitness effects of heterozygosity at genomewide distributed genes in partially inbred populations. However, in populations with much linkage disequilibrium (LD), HFCs may arise also as a consequence of selection on fitness loci in the local chromosomal vicinity of the markers. Recent data suggest that relatively high levels of LD may prevail in many ecological situations. Consequently, LD may be an important factor, together with partial inbreeding, in causing HFCs in natural populations. In the present study, we evaluate whether LD can generate HFCs in a small and newly founded population of great reed warblers (Acrocephalus arundinaceus). For this purpose dyads of full siblings of which only one individual survived to adult age (i.e., returned to breed at the study area) were scored at 19 microsatellite loci, and at a gene region of hypothesized importance for survival, the major histocompatibility complex (MHC). By examining siblings, we controlled for variation in the inbreeding coefficient and thus excluded genome-wide fitness effects in our analyses. We found that recruited individuals had significantly higher multilocus heterozygosity (MLH), and mean d² (a microsatellite-specific variable), than their nonrecruited siblings. There was a tendency for the survivors to have a more diverse MHC than the nonsurvivors. Single-locus analyses showed that the strength of the genotype-survival association was especially pronounced at four microsatellite loci. By using genotype data from the entire breeding population, we detected significant LD between five of 162 pairs of microsatellite loci after accounting for multiple tests. Our present finding of a significant within-family multilocus heterozygosity-survival association in a nonequilibrium population supports the view that LD generates HFCs... [ABSTRACT FROM AUTHOR]

Published
2004
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125. Diversity of Mhc class I and IIB genes in house sparrows (Passer domesticus).

Author

Bonneaud, Camille, Sorci, Gabriele, Morin, Véronique, Westerdahl, Helena, Zoorob, Rima, and Wittzell, Håkan

Subjects
GENETIC polymorphisms, IMMUNOGENETICS, MAJOR histocompatibility complex, NATURAL immunity, HLA histocompatibility antigens, IMMUNE response
Abstract

In order to understand the expression and evolution of host resistance to pathogens, we need to examine the links between genetic variability at the major histocompatibility complex (Mhc), phenotypic expression of the immune response and parasite resistance in natural populations. To do so, we characterized the Mhc class I and IIB genes of house sparrows with the goal of designing a PCR-based genotyping method for the Mhc genes using denaturing gradient gel electrophoresis (DGGE). The incredible success of house sparrows in colonizing habitats worldwide allows us to assess the importance of the variability of Mhc genes in the face of various pathogenic pressures. Isolation and sequencing of Mhc class I and IIB alleles revealed that house sparrows have fewer loci and fewer alleles than great reed warblers. In addition, the Mhc class I genes divided in two distinct lineages with different levels of polymorphism, possibly indicating different functional roles for each gene family. This organization is reminiscent of the chicken B complex and Rfp-Y system. The house sparrow Mhc hence appears to be intermediate between the great reed warbler and the chicken Mhc, both in terms of numbers of alleles and existence of within-class lineages. We specifically amplified one Mhc class I gene family and ran the PCR products on DGGE gels. The individuals screened displayed between one and ten DGGE bands, indicating that this method can be used in future studies to explore the ecological impacts of Mhc diversity. [ABSTRACT FROM AUTHOR]

Published
2004
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126. SHORT COMMUNICATION MHC diversity in two Acrocephalus species: the outbred Great reed warbler and the inbred Seychelles warbler.

Author

Richardson, David S. and Westerdahl, Helena

Subjects
*REED warblers, *MAJOR histocompatibility complex, *BIOLOGICAL variation, *BIRD populations, *RESTRICTION fragment length polymorphisms, *NUCLEOTIDE sequence
Abstract

The Great reed warbler (GRW) and the Seychelles warbler (SW) are congeners with markedly different demographic histories. The GRW is a normal outbred bird species while the SW population remains isolated and inbred after undergoing a severe population bottleneck. We examined variation at Major Histocompatibility Complex (MHC) class I exon 3 using restriction fragment length polymorphism, denaturing gradient gel electrophoresis and DNA sequencing. Although genetic variation was higher in the GRW, considerable variation has been maintained in the SW. The ten exon 3 sequences found in the SW were as diverged from each other as were a random sub-sample of the 67 sequences from the GRW. There was evidence for balancing selection in both species, and the phylogenetic analysis showing that the exon 3 sequences did not separate according to species, was consistent with transspecies evolution of the MHC. [ABSTRACT FROM AUTHOR]

Published
2003
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127. Host specificity in avian blood parasites: a study of Plasmodiumand Haemoproteusmitochondrial DNA amplified from birds

Author

Bensch, Stffan, Stjernman, Martin, Hasselquist, Dennis, Örjan, Östman, Hannson, Bengt, Westerdahl, Helena, and Pinheiro, Renato Torres

Abstract

A fragment of the mitochondrial cytochrome b gene of avian malaria (genera Haemoproteusand Plasmodium) was amplified from blood samples of 12 species of passerine birds from the genera Acrocephalus, Phylloscopusand Parus. By sequencing 478 nucleotides of the obtained fragments, we found 17 different mitochondrial haplotypes of Haemoproteusor Plasmodiumamong the 12 bird species investigated. Only one out of the 17 haplotypes was found in more than one host species, this exception being a haplotype detected in both blue tits (Parus caeruleus) and great tits (Parus major). The phylogenetic tree which was constructed grouped the sequences into two clades, most probably representing Haemoproteusand Plasmodium, respectively. We found two to four different parasite mitochondrial DNA (mtDNA) haplotypes in four bird species. The phylogenetic tree obtained from the mtDNA of the parasites matched the phylogenetic tree of the bird hosts poorly. For example, the two tit species and the willow warbler (Phylloscopus trochilus) carried parasites differing by only 0.6sequence divergence, suggesting that Haemoproteusshift both between species within the same genus and also between species in different families. Hence, host shifts seem to have occurred repeatedly in this parasite-host system. We discuss this in terms of the possible evolutionary consequences for these bird species.

Published
2000
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128. Seasonal dynamics of haemosporidian (Apicomplexa, Haemosporida) parasites in house sparrows Passer domesticus at four European sites: comparison between lineages and the importance of screening methods

Author

Neto, Júlio Manuel, Mellinger, Samantha, Halupka, Lucyna, Marzal, Alfonso, Zehtindjiev, Pavel, and Westerdahl, Helena

Subjects
Plasmodium, Co-infections, Bird Diseases, Haemosporida, Article, PCR method, Temporal variation, Europe, Geographic variation, Prevalence, Animals, Avian malaria, Seasons, Protozoan Infections, Animal, Phylogeny, Sparrows, ComputingMethodologies_COMPUTERGRAPHICS
Abstract

Graphical abstract, Highlights • Haemosporidae prevalence and diversity in house sparrows decreased with increasing latitude. • The nested PCR method underestimates co-infections and biases results. • Seasonal dynamics varied between sites, lineages, species and genera. • Seasonality of single lineages (P_SGS1) also varied between sites. • Unexpectedly, seasonality was greatest at the southernmost site., Infectious diseases often vary seasonally in a predictable manner, and seasonality may be responsible for geographical differences in prevalence. In temperate regions, vector-borne parasites such as malaria are expected to evolve lower virulence and a time-varying strategy to invest more in transmission when vectors are available. A previous model of seasonal variation of avian malaria described a double peak in prevalence of Plasmodium parasites in multiple hosts resulting from spring relapses and transmission to susceptible individuals in summer. However, this model was rejected by a study describing different patterns of seasonal variation of two Plasmodium spp. at the same site, with the double peak only apparent when these species were combined. Here, we assessed the seasonal variation in prevalence of haemosporidian parasites (Plasmodium, Haemoproteus and Leucocytozoon) in house sparrows (Passer domesticus) sampled across 1 year at four temperate European sites spanning a latitudinal range of 17°. We showed that parasite prevalence and diversity decreased with increasing latitude, but the parasite communities differed between sites, with only one Plasmodium lineage (P_SGS1) occurring at all sites. Moreover, the nested PCR method commonly used to detect and identify haemosporidian parasites strongly underestimated co-infections of Haemoproteus and Plasmodium, significantly biasing the pattern of seasonal variation, so additional molecular methods were used. Finally, we showed that: (i) seasonal variation in prevalence of haemosporidian parasites varied between study sites and parasite lineages/species/genera, describing further cases where the double peak model is not met; (ii) the seasonal dynamics of single lineages (P_SGS1) varied between sites; and (iii) unexpectedly, seasonality was greatest at the southernmost site, a pattern that was mostly driven by lineage H_PADOM05. Limitations of the genotyping methods and consequences of pooling (parasite lineages, sites and years) in studies of haemosporidian parasites are discussed and recommendations proposed, since these actions may obscure the patterns of prevalence and limit ecological inferences.

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129. Avian MHC Evolution in the Era of Genomics: Phase 1.0.

Author

O'Connor, Emily A., Westerdahl, Helena, Burri, Reto, and Edwards, Scott V.

Subjects
*MAJOR histocompatibility complex, *GENOMICS, *BIRD diversity, *BIOLOGICAL evolution, *BIRD behavior, *AVIAN influenza
Abstract

Birds are a wonderfully diverse and accessible clade with an exceptional range of ecologies and behaviors, making the study of the avian major histocompatibility complex (MHC) of great interest. In the last 20 years, particularly with the advent of high-throughput sequencing, the avian MHC has been explored in great depth in several dimensions: its ability to explain ecological patterns in nature, such as mating preferences; its correlation with parasite resistance; and its structural evolution across the avian tree of life. Here, we review the latest pulse of avian MHC studies spurred by high-throughput sequencing. Despite high-throughput approaches to MHC studies, substantial areas remain in need of improvement with regard to our understanding of MHC structure, diversity, and evolution. Recent studies of the avian MHC have nonetheless revealed intriguing connections between MHC structure and life history traits, and highlight the advantages of long-term ecological studies for understanding the patterns of MHC variation in the wild. Given the exceptional diversity of birds, their accessibility, and the ease of sequencing their genomes, studies of avian MHC promise to improve our understanding of the many dimensions and consequences of MHC variation in nature. However, significant improvements in assembling complete MHC regions with long-read sequencing will be required for truly transformative studies. [ABSTRACT FROM AUTHOR]

Published
2019
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130. Only rare classical MHC-I alleles are highly expressed in the European house sparrow.

Author

Watson, Hannah, Drews, Anna, Skogsmyr, Kelly Hultman, Neto, Júlio Manuel, Roved, Jacob, and Westerdahl, Helena

Abstract

The exceptional polymorphism observed within genes of the major histocompatibility complex (MHC), a core component of the vertebrate immune system, has long fascinated biologists. The highly polymorphic classical MHC class-I (MHC-I) genes are maintained by pathogen-mediated balancing selection (PMBS), as shown by many sites subject to positive selection, while the more monomorphic non-classical MHC-I genes show signatures of purifying selection. In line with PMBS, at any point in time, rare classical MHC alleles are more likely than common classical MHC alleles to confer a selective advantage in host–pathogen interactions. Combining genomic and expression data from the blood of wild house sparrows Passer domesticus, we found that only rare classical MHC-I alleles were highly expressed, while common classical MHC-I alleles were lowly expressed or not expressed. Moreover, highly expressed rare classical MHC-I alleles had more positively selected sites, indicating exposure to stronger PMBS, compared with lowly expressed classical alleles. As predicted, the level of expression was unrelated to allele frequency in the monomorphic non-classical MHC-I alleles. Going beyond previous studies, we offer a fine-scale view of selection on classical MHC-I genes in a wild population by revealing differences in the strength of PMBS according to allele frequency and expression level. [ABSTRACT FROM AUTHOR]

Published
2024
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131. Seasonal dynamics of haemosporidian (Apicomplexa, Haemosporida) parasites in house sparrows Passer domesticus at four European sites: comparison between lineages and the importance of screening methods.

Author

Neto, Júlio Manuel, Mellinger, Samantha, Halupka, Lucyna, Marzal, Alfonso, Zehtindjiev, Pavel, and Westerdahl, Helena

Subjects
*ENGLISH sparrow, *PLASMODIUM, *PLASMODIUM vivax, *AVIAN malaria, *HAEMOSPORIDA, *PARASITES, *APICOMPLEXA
Abstract

• Haemosporidae prevalence and diversity in house sparrows decreased with increasing latitude. • The nested PCR method underestimates co-infections and biases results. • Seasonal dynamics varied between sites, lineages, species and genera. • Seasonality of single lineages (P_SGS1) also varied between sites. • Unexpectedly, seasonality was greatest at the southernmost site. Infectious diseases often vary seasonally in a predictable manner, and seasonality may be responsible for geographical differences in prevalence. In temperate regions, vector-borne parasites such as malaria are expected to evolve lower virulence and a time-varying strategy to invest more in transmission when vectors are available. A previous model of seasonal variation of avian malaria described a double peak in prevalence of Plasmodium parasites in multiple hosts resulting from spring relapses and transmission to susceptible individuals in summer. However, this model was rejected by a study describing different patterns of seasonal variation of two Plasmodium spp. at the same site, with the double peak only apparent when these species were combined. Here, we assessed the seasonal variation in prevalence of haemosporidian parasites (Plasmodium , Haemoproteus and Leucocytozoon) in house sparrows (Passer domesticus) sampled across 1 year at four temperate European sites spanning a latitudinal range of 17°. We showed that parasite prevalence and diversity decreased with increasing latitude, but the parasite communities differed between sites, with only one Plasmodium lineage (P_SGS1) occurring at all sites. Moreover, the nested PCR method commonly used to detect and identify haemosporidian parasites strongly underestimated co-infections of Haemoproteus and Plasmodium , significantly biasing the pattern of seasonal variation, so additional molecular methods were used. Finally, we showed that: (i) seasonal variation in prevalence of haemosporidian parasites varied between study sites and parasite lineages/species/genera, describing further cases where the double peak model is not met; (ii) the seasonal dynamics of single lineages (P_SGS1) varied between sites; and (iii) unexpectedly, seasonality was greatest at the southernmost site, a pattern that was mostly driven by lineage H_PADOM05. Limitations of the genotyping methods and consequences of pooling (parasite lineages, sites and years) in studies of haemosporidian parasites are discussed and recommendations proposed, since these actions may obscure the patterns of prevalence and limit ecological inferences. [ABSTRACT FROM AUTHOR]

Published
2020
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132. Evidence for sexual conflict over major histocompatibility complex diversity in a wild songbird.

Author

Roved, Jacob, Hansson, Bengt, Tarka, Maja, Hasselquist, Dennis, and Westerdahl, Helena

Subjects
*MAJOR histocompatibility complex, *SONGBIRDS, *IMMUNE response, *IMMUNOPATHOLOGY, *AUTOIMMUNE diseases, *GENETICS
Abstract

Sex differences in parasite load and immune responses are found across a wide range of animals, with females generally having lower parasite loads and stronger immune responses than males. Intrigued by these general patterns, we investigated if there was any sign of sex-specific selection on an essential component of adaptive immunity that is known to affect fitness, the major histocompatibility complex class I (MHC-I) genes, in a 20-year study of great reed warblers. Our analyses on fitness related to MHC-I diversity showed a highly significant interaction between MHC-I diversity and sex, where males with higher, and females with lower, MHC-I diversity were more successful in recruiting offspring. Importantly, mean MHC-I diversity did not differ between males and females, and consequently neither sex reached its MHC-I fitness optimum. Thus, there is an unresolved genetic sexual conflict over MHC-I diversity in great reed warblers. Selection from pathogens is known to maintain MHC diversity, but previous theory ignores that the immune environments are considerably different in males and females. Our results suggest that sexually antagonistic selection is an important, previously neglected, force in the evolution of vertebrate adaptive immunity, and have implications for evolutionary understanding of costs of immune responses and autoimmune diseases. [ABSTRACT FROM AUTHOR]

Published
2018
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133. Odour-based discrimination of similarity at the major histocompatibility complex in birds.

Author

Leclaire, Sarah, Mardon, Jérôme, Bonadonna, Francesco, Strandh, Maria, and Westerdahl, Helena

Subjects
*SEXUAL behavior in birds, *MAJOR histocompatibility complex, *OLFACTORY perception, *PETRELS, *COURTSHIP, *GENETICS, *BIRDS, *IMMUNITY, *BEHAVIOR
Abstract

Many animals are known to preferentially mate with partners that are dissimilar at the major histocompatibility complex (MHC) in order to maximize the antigen binding repertoire (or disease resistance) in their offspring. Although several mammals, fish or lizards use odour cues to assessMHCsimilarity with potential partners, the ability of birds to assessMHC similarity using olfactory cues has not yet been explored. Here we used a behavioural binary choice test and high-throughput-sequencing of MHC class IIB to determine whether blue petrels can discriminate MHC similarity based on odour cues alone. Blue petrels are seabirds with particularly good sense of smell, they have a reciprocalmate choice and are known to preferentially mate withMHC-dissimilar partners. Incubating males preferentially approached the odour of the more MHC-dissimilar female, whereas incubating females showed opposite preferences. Given their mating pattern, females were, however, expected to show preference for the odour of the more MHC-dissimilar male. Further studies are needed to determine whether, as in women and female mice, the preference varies with the reproductive cycle in blue petrel females. Our results provide the first evidence that birds can use odour cues only to assess MHC dissimilarity. [ABSTRACT FROM AUTHOR]

Published
2017
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134. Ecoimmunology perspective of host-parasite interactions in Limosa limosa across its migratory flyway

Author

Pardal, Sara Lopes, Ramos, Jaime A., and Westerdahl, Helena

Subjects
Ecoimmunology, evolução molecular, molecular evolution, limícolas, imunidade adaptativa, Ecoimunologia, pressão parasítica, adaptive immunity, imunidade inata, pathogen pressure, migradores de longa distância, long-distance migration, waders, Ciências Naturais::Ciências Biológicas [Domínio/Área Científica], innate immunity
Abstract

Tese de doutoramento em Biociências, na especialidade de Ecologia, apresentada ao Departamento de Ciências da Vida da Faculdade de Ciências e Tecnologia da Universidade de Coimbra For long-distance migrant birds, ecological changes along the flyway and strenuous work, can unbalance immune investments and thereby increasing the vulnerability to disease and reducing survival. Despite an essential self-maintenance component, immunity comes with costs as well as benefits. At an ecological context (i.e. limited energy), trade-offs are generated between immunity and other competing physiological components, leading to variations on immune response across time (annual-cycle) and space (different environments). Moreover, immune responses also vary between species and are optimized according to specific situations of an individual´s life, to maximize survival and fitness. Many ecoimmunology studies are focused on understanding the general patterns of immune responses in free-living birds, and what mechanisms mediate the changes in disease susceptibility, which in turn may affect population dynamics and survival. Information regarding these immunologic trade-offs remain largely unknown, and thus becoming of paramount importance when contextualized with climate change effects over migration ecology and the distribution of animal diseases. The work comprised in this thesis addressed the general question of how differences in environmental pathogen pressure shape the innate and adaptive immunity of a free-living bird species. The long-distance migrant Black-tailed godwit (Limosa limosa; hereafter godwit), was used as a study model, since the two subspecies, nominate (Limosa limosa limosa) and Icelandic (L. l. islandica), vary on migratory strategy and habitat-use, which consequently differ in pathogen pressure. Below, I summarize the main contributions of my work for the ecoimmunology research area. On chapter I, I tested whether the strength of immune response is indeed correlated with the environmental pathogen risk that differ with the migratory strategies and habitat use of godwit´s. The work focused innate baseline immunity parameters and I showed that it changes during the annual cycle of godwits in response to seasonal demands, availability of resources and physiological trade-offs. The investments in immune defence and the strategies deployed also varied in response to risk of getting infected. Trade-offs between innate immunity and other physiological components were more apparent during energetically demanding periods, such as the breeding season. For e.g. the Icelandic godwits downregulated innate responses when occupying parasite-poor breeding areas. Moreover, data indicates that immune adjustments and strategies are rather unique for each species. Nonetheless, migration seems to affect several bird species the same way, leading to an overall immunosuppression of the innate immune response and possibly to a higher vulnerability to disease. On chapter II, the MHC-I gene of the Icelandic godwit is characterized based on Sanger and ultradeep Illumina MiSeq sequencing. Characterization mostly focused the α2 domain (exon 3) of this gene, which is known to be highly polymorphic and for coding the proteins that recognize pathogens. I found 47 new alleles of MHC-I exon 3 and of a putatively classical nature (functional). Individuals had between one to four loci, with at least three being expressed. The gene organization was quite similar to their closest relative, the Red knots (Calidris canutus), but comparing to other Charadriiformes species, the alleles had a lower polymorphism and few sites subjected to positive selection. This pattern most likely reflects the lower pathogenic pressure that individuals experience along their migratory flyway. On chapter III, the role of pathogens as drivers of the diversifying selection of MHC genes is analysed. By using Illumina MiSeq sequencing we compared two godwit subspecies in terms of MHC-I exon 3 diversity and polymorphism. Both nominate and Icelandic godwits overlapped in terms of number of alleles (and loci) per individual, but nominate birds had significantly higher number of alleles and polymorphism. A population size effect could partly explain the differences seen between subspecies at the MHC-I diversity, but the number of positively selected sites for the nominate godwit was twice as high as those found for the Icelandic godwits. Positive selection differences suggest a stronger balancing selection for the nominate godwit and thus an adaptation to pathogen-rich habitats. Chapter IV is focus on sexual signals and whether they truly advertise the quality of mates and their capacity to fight-off pathogens. I tested whether investment on innate immunity could be reflected by the sexual characters of godwits. Results indicate that some plumage features of male and female godwits were linked to soluble parameters of innate immunity and were not cost-free. Moreover, the signal was honest for males but not for females, a difference that may be related to sex-specific energetic demands and roles undertaken in breeding. Results suggest that females select males that are better at combining moult and migration and more able to fight infections. Chapter V tackles a more pratical issue faced by researchers that work with free-living birds, and with no immediate access to laboratory facilities. Immunological assays have become a widespread tool for an integrate approach of immune variation, but it was unknown whether post-sampling repeated freeze-thawing (FT) cycles could affect the final outcome of the assays. An experimental approach testing post-sampling handling and methodological issues was implemented, and overall results showed that plasma (and serum) samples remain stable after repeated FT cycles, and thus the indices of immune function are mostly unaffected. Moreover, small methodological deviations of the assay´s protocols, caused no substantial variations on the final results. Para aves migradoras de longa distância, as mudanças ecológicas ao longo da migração, aliadas ao esforço físico, podem desequilibrar os investimentos em imunidade, levando a uma maior a vulnerabilidade à doença e reduzindo a capacidade de sobrevivência. Apesar de a imunidade ser um componente fisiológico de auto-preservação, esta implica custos bem como benefícios. Num contexto ecológico (ex. energia limitada), são gerados trade-offs entre a imunidade e outros componentes fisiológicos, dando origem a variações da resposta imune ao longo do tempo (ciclo anual) e do espaço (diferentes habitats). Para além disso, as respostas imunitárias também variam entre espécies e são optimizadas em função de situações específicas da vida de um indivíduo para maximizar a sobrevivência e o fitness. Muitos estudos em ecoimunologia focam-se na compreensão dos padrões globais de respostas imunes em aves selvagens e nos mecanismos que alteram a susceptibilidade à doença, o que consequentemente poderá afectar a sobrevivência e a dinâmica populacional. Infelizmente a informação relativa a estes trade-offs imunológicos permanece maioritariamente desconhecida, tratando-se portanto de conhecimento essencial quando contextualizado com os efeitos das alterações climáticas sobre a ecologia das migrações e distribuição de doenças animais. O trabalho englobado nesta tese procurou responder como é que as diferenças na pressão parasítica ambiental afectam a imunidade inata e adaptativa de aves selvagens. O migrador de longa distância Maçarico-de-bico-direito (Limosa limosa; Maçarico), foi usado como modelo de estudo, uma vez que duas das suas subespécies, nominal (Limosa limosa limosa) e islandesa (L. l. Islandica), variam na estratégia migratória e uso de habitat, que consequentemente difere na pressão parasítica. De seguida, resumo as principais contribuições do meu trabalho para a área da ecoimunologia. No capítulo I, usando uma ave límicola como modelo, testei se a capacidade da resposta imune está de facto correlacionada com o risco de contrair doenças, uma vez que o risco difere com as estratégias de migração e habitat. O trabalho focou parâmetros de imunidade inata e demonstrei que esta não é de natureza estanque, mas que varia ao longo do ciclo anual dos Maçaricos em resposta à estação do ano, disponibilidade de recursos e trade-offs fisiológicos. Os investimentos na imunidade e estratégias aplicadas também variaram em resposta ao risco de infecção. Os trade-offs entre a imunidade e outros componentes fisiológicos, tornaram-se mais evidentes durante períodos energeticamente exigentes, como a reprodução. Por exemplo, neste período a subespécie islandesa suprimiu alguns componentes da imunidade inata, quando ocupava áreas onde o risco de infecção é baixo. Os resultados também indicam que os ajustes e estratégias imunitárias são únicas para cada espécie. Contudo a migração parece afectar as variadas espécies de aves da mesma maneira, dando origem a uma imunosupressão geral da resposta inata e possivelmente a uma maior vulnerabilidade à doença. No capítulo II, o gene MHC-I da subespécie islandesa de Maçarico foi caracterizado com o auxílio da sequenciação de Sanger e Illumina MiSeq. A caracterização focou quase exclusivamente o domínio α2 (exão 3) deste gene, que é conhecido pelo seu polimorfismo e por codificar parte das glicoproteínas que reconhecem agentes patogénicos. Neste trabalho descobri 47 novos alelos do gene MHC-I, todos eles de natureza provavelmente clássica (ou funcional). Os Maçaricos islandeses têm entre um e quatro loci, com pelo menos três a ser expressos. A organização do gene MHC-I é bastante semelhante à do seu parente mais próximo, a Seixoeira (Calidris canutus), mas comparado com outras espécies de Charadriiformes, os alelos tinham um polimorfismo menor e poucos locais sujeitos a selecção positiva. Este padrão parece ser um reflexo de os indivíduos experienciarem a uma menor pressão patogénica ao longo da sua rota de migração. No capítulo III, aprofundámos o papel da pressão patogénica como origem da diversificação dos genes MHC. Com o auxílio da sequenciação Illumina MiSeq, comparámos as duas subespécies de Maçarico relativamente à diversidade e ao polimorfismo do exão 3 do gene MHC-I. Ambas as subespécies sobrepuseram-se no que toca ao número de alelos (e loci) por indivíduo, mas a subespécie nominal, tinha significativamente mais alelos e tendencialmente um maior polimorfismo. Diferentes tamanhos populacionais poderão explicar parcialmente as diferenças encontradas entre subespécies ao nível da diversidade genética, no entanto, o número de locais sujeitos a selecção positiva encontrados para a subespécie nominal, foi duas vezes superior ao encontrado para a subespécie islandesa. As diferenças no que toca à selecção positiva, sugerem que a selecção natural é mais forte para a subespécie nominal e portanto uma adaptação a habitats ricos em parasitas. O capítulo IV centra-se nos sinais sexuais e avalia se eles realmente reflectem a qualidade dos parceiros e a sua capacidade em combater doenças. Para isso testei se o investimento na imunidade inata poderia ser reflectido pelos carácteres sexuais secundários da plumagem dos Maçaricos. Os resultados indicam que algumas características da plumagem dos machos e fêmeas estão ligadas a componentes solúveis de imunidade inata e que os investimentos na plumagem são custosos. Para além disso, o sinal foi honesto para os machos, mas não para as fêmeas, uma diferença que poderá estar relacionada com constrangimentos energéticos específicos para cada sexo, e pelos papéis desempenhados durante a reprodução. Em resumo, os dados indicam que as fêmeas seleccionam não só os machos que são melhores a combinar a muda da plumagem e a migração, mas também os mais competentes no combate às infecções. O Capítulo V aborda uma questão mais prática enfrentada por investigadores que trabalham com aves selvagens e sem acesso fácil ou imediato ao laboratório. Os ensaios imunológicos tornaram-se uma ferramenta generalizada para uma abordagem integrada da imunidade, mas desconhecia-se até à data se os ciclos repetidos de congelamento-descongelamento (CD) pós-amostragem poderiam afectar o resultado final dos ensaios imunológicos. Neste trabalho foi implementada uma abordagem experimental para o tratamento pós amostragem, bem como outras questões metodológicas, e os resultados indicaram que as amostras de plasma (ou soro) permanecem estáveis após ciclos repetidos de CD e que portanto, os componentes imunológicos permanecem inalterados. Mostrámos também que pequenas alterações metodológicas nos protocolos destes ensaios não causaram variações substanciais nos resultados finais. GHTM, IHMT, UNL – Global Health and Tropical Medicine, Instituto de Higiene e Medicina Tropical, Universidade Nova de Lisboa The Ruffords Foundation

Published
2017

135. Expansion of MHC-IIB Has Constrained the Evolution of MHC-IIA in Passerines.

Author

Ruesink-Bueno IL, Drews A, O'Connor EA, and Westerdahl H

Subjects
Animals, Genes, MHC Class II, Histocompatibility Antigens Class II genetics, Passeriformes genetics, Evolution, Molecular, Phylogeny, Selection, Genetic
Abstract

The major histocompatibility complex (MHC) is central in adaptive immunity, with the highly polymorphic MHC genes encoding antigen-presenting molecules. Two MHC class II (MHC-II) loci, DA1 and DA2, predate the radiation of extant birds and persist throughout much of the avian phylogeny. Within each locus, the MHC-II molecules are encoded by A-genes (DAA) and B-genes (DAB), which are arranged in A-B dyads. However, in passerines (order Passeriformes), the DA2 locus has been lost, and the ancestral A-B dyad at the DA1 locus has been replaced by a putatively single A-gene (DAA1) and an array of highly polymorphic B-genes (DAB1). In this study, we genotyped the DAA1 gene of 15 passerine species and confirmed that passerines possess just one copy of DAA1. We then compared selection patterns in DAA1 between passerines and nonpasserines and found that exon 2, which encodes the antigen-presenting domain, has been subject to weaker positive selection and stronger negative selection in passerines compared with nonpasserines. Additional comparisons showed that the patterns of selection in the passerine DAA1 gene are unlikely to be related to the loss of the DA2 locus. Instead, our findings suggest that the expansion of DAB1 (MHC-IIB) has imposed an evolutionary constraint on the passerine DAA1 (MHC-IIA) gene. We speculate that this constraint may be the result of each DAA1 chain forming heterodimers with many different DAB1 chains., (© The Author(s) 2024. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.)

Published
2024
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136. Improved haplotype resolution of highly duplicated MHC genes in a long-read genome assembly using MiSeq amplicons.

Author

Mellinger S, Stervander M, Lundberg M, Drews A, and Westerdahl H

Subjects
Animals, Haplotypes genetics, Histocompatibility Antigens Class I genetics, Genome, Genomics, Major Histocompatibility Complex genetics, Passeriformes genetics
Abstract

Long-read sequencing offers a great improvement in the assembly of complex genomic regions, such as the major histocompatibility complex (MHC) region, which can contain both tandemly duplicated MHC genes (paralogs) and high repeat content. The MHC genes have expanded in passerine birds, resulting in numerous MHC paralogs, with relatively high sequence similarity, making the assembly of the MHC region challenging even with long-read sequencing. In addition, MHC genes show rather high sequence divergence between alleles, making diploid-aware assemblers incorrectly classify haplotypes from the same locus as sequences originating from different genomic regions. Consequently, the number of MHC paralogs can easily be over- or underestimated in long-read assemblies. We therefore set out to verify the MHC diversity in an original and a haplotype-purged long-read assembly of one great reed warbler Acrocephalus arundinaceus individual (the focal individual) by using Illumina MiSeq amplicon sequencing. Single exons, representing MHC class I (MHC-I) and class IIB (MHC-IIB) alleles, were sequenced in the focal individual and mapped to the annotated MHC alleles in the original long-read genome assembly. Eighty-four percent of the annotated MHC-I alleles in the original long-read genome assembly were detected using 55% of the amplicon alleles and likewise, 78% of the annotated MHC-IIB alleles were detected using 61% of the amplicon alleles, indicating an incomplete annotation of MHC genes. In the haploid genome assembly, each MHC-IIB gene should be represented by one allele. The parental origin of the MHC-IIB amplicon alleles in the focal individual was determined by sequencing MHC-IIB in its parents. Two of five larger scaffolds, containing 6-19 MHC-IIB paralogs, had a maternal and paternal origin, respectively, as well as a high nucleotide similarity, which suggests that these scaffolds had been incorrectly assigned as belonging to different loci in the genome rather than as alternate haplotypes of the same locus. Therefore, the number of MHC-IIB paralogs was overestimated in the haploid genome assembly. Based on our findings we propose amplicon sequencing as a suitable complement to long-read sequencing for independent validation of the number of paralogs in general and for haplotype inference in multigene families in particular., Competing Interests: The authors declare there are no competing interests., (©2023 Mellinger et al.)

Published
2023
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137. The structure of songbird MHC class I reveals antigen binding that is flexible at the N-terminus and static at the C-terminus.

Author

Eltschkner S, Mellinger S, Buus S, Nielsen M, Paulsson KM, Lindkvist-Petersson K, and Westerdahl H

Subjects
Animals, Humans, Histocompatibility Antigens Class I, Peptides metabolism, Antigen Presentation, HLA Antigens, Songbirds genetics, Songbirds metabolism, Chiroptera
Abstract

Long-distance migratory animals such as birds and bats have evolved to withstand selection imposed by pathogens across the globe, and pathogen richness is known to be particularly high in tropical regions. Immune genes, so-called Major Histocompatibility Complex (MHC) genes, are highly duplicated in songbirds compared to other vertebrates, and this high MHC diversity has been hypothesised to result in a unique adaptive immunity. To understand the rationale behind the evolution of the high MHC genetic diversity in songbirds, we determined the structural properties of an MHC class I protein, Acar3, from a long-distance migratory songbird, the great reed warbler Acrocephalus arundinaceus (in short: Acar ). The structure of Acar3 was studied in complex with pathogen-derived antigens and shows an overall antigen presentation similar to human MHC class I. However, the peptides bound to Acar3 display an unusual conformation: Whereas the N-terminal ends of the peptides display enhanced flexibility, the conformation of their C-terminal halves is rather static. This uncommon peptide-binding mode in Acar3 is facilitated by a central Arg residue within the peptide-binding groove that fixes the backbone of the peptide at its central position, and potentially permits successful interactions between MHC class I and innate immune receptors. Our study highlights the importance of investigating the immune system of wild animals, such as birds and bats, to uncover unique immune mechanisms which may neither exist in humans nor in model organisms., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Eltschkner, Mellinger, Buus, Nielsen, Paulsson, Lindkvist-Petersson and Westerdahl.)

Published
2023
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138. Understanding the evolution of immune genes in jawed vertebrates.

Author

Vinkler M, Fiddaman SR, Těšický M, O'Connor EA, Savage AE, Lenz TL, Smith AL, Kaufman J, Bolnick DI, Davies CS, Dedić N, Flies AS, Samblás MMG, Henschen AE, Novák K, Palomar G, Raven N, Samaké K, Slade J, Veetil NK, Voukali E, Höglund J, Richardson DS, and Westerdahl H

Subjects
Animals, Vertebrates genetics, Evolution, Molecular, Immunity, Innate genetics, Adaptive Immunity genetics, Biological Evolution
Abstract

Driven by co-evolution with pathogens, host immunity continuously adapts to optimize defence against pathogens within a given environment. Recent advances in genetics, genomics and transcriptomics have enabled a more detailed investigation into how immunogenetic variation shapes the diversity of immune responses seen across domestic and wild animal species. However, a deeper understanding of the diverse molecular mechanisms that shape immunity within and among species is still needed to gain insight into-and generate evolutionary hypotheses on-the ultimate drivers of immunological differences. Here, we discuss current advances in our understanding of molecular evolution underpinning jawed vertebrate immunity. First, we introduce the immunome concept, a framework for characterizing genes involved in immune defence from a comparative perspective, then we outline how immune genes of interest can be identified. Second, we focus on how different selection modes are observed acting across groups of immune genes and propose hypotheses to explain these differences. We then provide an overview of the approaches used so far to study the evolutionary heterogeneity of immune genes on macro and microevolutionary scales. Finally, we discuss some of the current evidence as to how specific pathogens affect the evolution of different groups of immune genes. This review results from the collective discussion on the current key challenges in evolutionary immunology conducted at the ESEB 2021 Online Satellite Symposium: Molecular evolution of the vertebrate immune system, from the lab to natural populations., (© 2023 The Authors. Journal of Evolutionary Biology published by John Wiley & Sons Ltd on behalf of European Society for Evolutionary Biology.)

Published
2023
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139. Reciprocal positive effects on parasitemia between coinfecting haemosporidian parasites in house sparrows.

Author

Garcia-Longoria L, Magallanes S, Huang X, Drews A, Råberg L, Marzal A, Bensch S, and Westerdahl H

Subjects
Animals, Humans, Parasitemia veterinary, Coinfection epidemiology, Haemosporida, Malaria, Avian epidemiology, Parasites, Plasmodium, Sparrows parasitology
Abstract

Background: Hosts are often simultaneously infected with several parasite species. These co-infections can lead to within-host interactions of parasites, including mutualism and competition, which may affect both virulence and transmission. Birds are frequently co-infected with different haemosporidian parasites, but very little is known about if and how these parasites interact in natural host populations and what consequences there are for the infected hosts. We therefore set out to study Plasmodium and Haemoproteus parasites in house sparrows Passer domesticus with naturally acquired infections using a protocol where the parasitemia (infection intensity) is quantified by qPCR separately for the two parasites. We analysed infection status (presence/absence of the parasite) and parasitemia of parasites in the blood of both adult and juvenile house sparrows repeatedly over the season., Results: Haemoproteus passeris and Plasmodium relictum were the two dominating parasite species, found in 99% of the analyzed Sanger sequences. All birds were infected with both Plasmodium and Haemoproteus parasites during the study period. Seasonality explained infection status for both parasites in the adults: H. passeris was completely absent in the winter while P. relictum was present all year round. Among adults infected with H. passeris there was a positive effect of P. relictum parasitemia on H. passeris parasitemia and likewise among adults infected with P. relictum there was a positive effect of H. passeris parasitemia on P. relictum parasitemia. No such associations on parasitemia were seen in juvenile house sparrows., Conclusions: The reciprocal positive relationships in parasitemia between P. relictum and H. passeris in adult house sparrows suggests either mutualistic interactions between these frequently occurring parasites or that there is variation in immune responses among house sparrow individuals, hence some individuals suppress the parasitemia of both parasites whereas other individuals suppress neither. Our detailed screening of haemosporidian parasites over the season shows that co-infections are very frequent in both juvenile and adult house sparrows, and since co-infections often have stronger negative effects on host fitness than the single infection, it is imperative to use screening systems with the ability to detect multiple parasites in ecological studies of host-parasite interactions., (© 2022. The Author(s).)

Published
2022
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140. Not all birds have a single dominantly expressed MHC-I gene: Transcription suggests that siskins have many highly expressed MHC-I genes.

Author

Drews A and Westerdahl H

Subjects
Alleles, Animals, Birds, Evolution, Molecular, Exons genetics, Phylogeny, Genes, MHC Class II genetics, Selection, Genetic genetics
Abstract

Passerine birds belong to the most species rich bird order and are found in a wide range of habitats. The extremely polymorphic adaptive immune system of passerines, identified through their major histocompatibility complex class I genes (MHC-I), may explain some of this extreme radiation. Recent work has shown that passerines have higher numbers of MHC-I gene copies than other birds, but little is currently known about expression and function of these gene copies. Non-passerine birds have a single highly expressed MHC-I gene copy, a pattern that seems unlikely in passerines. We used high-throughput sequencing to study MHC-I alleles in siskins (Spinus spinus) and determined gene expression, phylogenetic relationships and sequence divergence. We verified between six and 16 MHC-I alleles per individual and 97% of these were expressed. Strikingly, up to five alleles per individual had high expression. Out of 88 alleles 18 were putatively non-classical with low sequence divergence and expression, and found in a single phylogenetic cluster. The remaining 70 alleles were classical, with high sequence divergence and variable degrees of expression. Our results contradict the suggestion that birds only have a single dominantly expressed MHC-I gene by demonstrating several highly expressed MHC-I gene copies in a passerine.

Published
2019
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141. The evolution of immunity in relation to colonization and migration.

Author

O'Connor EA, Cornwallis CK, Hasselquist D, Nilsson JÅ, and Westerdahl H

Subjects
Africa South of the Sahara, Animals, Europe, Phylogeny, Sequence Analysis, DNA, Songbirds immunology, Animal Distribution, Animal Migration, Evolution, Molecular, Major Histocompatibility Complex, Songbirds physiology
Abstract

Colonization and migration have a crucial effect on patterns of biodiversity, with disease predicted to play an important role in these processes. However, evidence of the effect of pathogens on broad patterns of colonization and migration is limited. Here, using phylogenetic analyses of 1,311 species of Afro-Palaearctic songbirds, we show that colonization events from regions of high (sub-Saharan Africa) to low (the Palaearctic) pathogen diversity were up to 20 times more frequent than the reverse, and that migration has evolved 3 times more frequently from African- as opposed to Palaearctic-resident species. We also found that resident species that colonized the Palaearctic from Africa, as well as African species that evolved long-distance migration to breed in the Palaearctic, have reduced diversity of key immune genes associated with pathogen recognition (major histocompatibility complex class I). These results suggest that changes in the pathogen community that occur during colonization and migration shape the evolution of the immune system, potentially by adjusting the trade-off between the benefits of extensive pathogen recognition and the costs of immunopathology that result from high major histocompatibility complex class I diversity.

Published
2018
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142. Sex differences in immune responses: Hormonal effects, antagonistic selection, and evolutionary consequences.

Author

Roved J, Westerdahl H, and Hasselquist D

Subjects
Animals, Estrogens physiology, Female, Humans, Male, Reproduction physiology, T-Lymphocytes, Helper-Inducer physiology, Testosterone physiology, Adaptive Immunity physiology, Biological Evolution, Immune System physiology, Sex Characteristics
Abstract

Males and females differ in both parasite load and the strength of immune responses and these effects have been verified in humans and other vertebrates. Sex hormones act as important modulators of immune responses; the male sex hormone testosterone is generally immunosuppressive while the female sex hormone estrogen tends to be immunoenhancing. Different sets of T-helper cells (Th) have important roles in adaptive immunity, e.g. Th1 cells trigger type 1 responses which are primarily cell-mediated, and Th2 cells trigger type 2 responses which are primarily humoral responses. In our review of the literature, we find that estrogen and progesterone enhance type 2 and suppress type 1 responses in females, whereas testosterone suppresses type 2 responses and shows an inconsistent pattern for type 1 responses in males. When we combine these patterns of generally immunosuppressive and immunoenhancing effects of the sex hormones, our results imply that the sex differences in immune responses should be particularly strong in immune functions associated with type 2 responses, and less pronounced with type 1 responses. In general the hormone-mediated sex differences in immune responses may lead to genetic sexual conflicts on immunity. Thus, we propose the novel hypothesis that sexually antagonistic selection may act on immune genes shared by the sexes, and that the strength of this sexually antagonistic selection should be stronger for type 2- as compared with type 1-associated immune genes. Finally, we put the consequences of sex hormone-induced effects on immune responses into behavioral and ecological contexts, considering social mating system, sexual selection, geographical distribution of hosts, and parasite abundance., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published
2017
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