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2. Crop pests and predators exhibit inconsistent responses to surrounding landscape composition

Author

Karp, DS, Chaplin-Kramer, R, Meehan, TD, Martin, EA, DeClerck, F, Grab, H, Gratton, C, Hunt, L, Larsen, AE, Martinez-Salinas, A, O'Rourke, ME, Rusch, A, Poveda, K, Jonsson, M, Rosenheim, JA, Schellhorn, NA, Tscharntke, T, Wratten, SD, Zhang, W, Iverson, AL, Adler, LS, Albrecht, M, Alignier, A, Angelella, GM, Anjum, MZ, Avelino, J, Batary, P, Baveco, JM, Bianchi, FJJA, Birkhofer, K, Bohnenblust, EW, Bommarco, R, Brewer, MJ, Caballero-Lopez, B, Carriere, Y, Carvalheiro, LG, Cayuela, L, Centrella, M, Cetkovic, A, Henri, DC, Chabert, A, Costamagna, AC, De la Mora, A, de Kraker, J, Desneux, N, Diehl, E, Diekoetter, T, Dormann, CF, Eckberg, JO, Entling, MH, Fiedler, D, Franck, P, van Veen, FJF, Frank, T, Gagic, V, Garratt, MPD, Getachew, A, Gonthier, DJ, Goodell, PB, Graziosi, I, Groves, RL, Gurr, GM, Hajian-Forooshani, Z, Heimpel, GE, Herrmann, JD, Huseth, AS, Inclan, DJ, Ingrao, AJ, Iv, P, Jacot, K, Johnson, GA, Jones, L, Kaiser, M, Kaser, JM, Keasar, T, Kim, TN, Kishinevsky, M, Landis, DA, Lavandero, B, Lavigne, C, Le Ralec, A, Lemessa, D, Letourneau, DK, Liere, H, Lu, Y, Lubin, Y, Luttermoser, T, Maas, B, Mace, K, Madeira, F, Mader, V, Cortesero, AM, Marini, L, Martinez, E, Martinson, HM, Menozzi, P, Mitchell, MGE, Miyashita, T, Molina, GAR, Molina-Montenegro, MA, O'Neal, ME, Opatovsky, I, Ortiz-Martinez, S, Nash, M, Ostman, O, Ouin, A, Pak, D, Paredes, D, Parsa, S, Parry, H, Perez-Alvarez, R, Perovic, DJ, Peterson, JA, Petit, S, Philpott, SM, Plantegenest, M, Plecas, M, Pluess, T, Pons, X, Potts, SG, Pywell, RF, Ragsdale, DW, Rand, TA, Raymond, L, Ricci, B, Sargent, C, Sarthou, J-P, Saulais, J, Schackermann, J, Schmidt, NP, Schneider, G, Schuepp, C, Sivakoff, FS, Smith, HG, Whitney, KS, Stutz, S, Szendrei, Z, Takada, MB, Taki, H, Tamburini, G, Thomson, LJ, Tricault, Y, Tsafack, N, Tschumi, M, Valantin-Morison, M, Mai, VT, van der Werf, W, Vierling, KT, Werling, BP, Wickens, JB, Wickens, VJ, Woodcock, BA, Wyckhuys, K, Xiao, H, Yasuda, M, Yoshioka, A, Zou, Y, Karp, DS, Chaplin-Kramer, R, Meehan, TD, Martin, EA, DeClerck, F, Grab, H, Gratton, C, Hunt, L, Larsen, AE, Martinez-Salinas, A, O'Rourke, ME, Rusch, A, Poveda, K, Jonsson, M, Rosenheim, JA, Schellhorn, NA, Tscharntke, T, Wratten, SD, Zhang, W, Iverson, AL, Adler, LS, Albrecht, M, Alignier, A, Angelella, GM, Anjum, MZ, Avelino, J, Batary, P, Baveco, JM, Bianchi, FJJA, Birkhofer, K, Bohnenblust, EW, Bommarco, R, Brewer, MJ, Caballero-Lopez, B, Carriere, Y, Carvalheiro, LG, Cayuela, L, Centrella, M, Cetkovic, A, Henri, DC, Chabert, A, Costamagna, AC, De la Mora, A, de Kraker, J, Desneux, N, Diehl, E, Diekoetter, T, Dormann, CF, Eckberg, JO, Entling, MH, Fiedler, D, Franck, P, van Veen, FJF, Frank, T, Gagic, V, Garratt, MPD, Getachew, A, Gonthier, DJ, Goodell, PB, Graziosi, I, Groves, RL, Gurr, GM, Hajian-Forooshani, Z, Heimpel, GE, Herrmann, JD, Huseth, AS, Inclan, DJ, Ingrao, AJ, Iv, P, Jacot, K, Johnson, GA, Jones, L, Kaiser, M, Kaser, JM, Keasar, T, Kim, TN, Kishinevsky, M, Landis, DA, Lavandero, B, Lavigne, C, Le Ralec, A, Lemessa, D, Letourneau, DK, Liere, H, Lu, Y, Lubin, Y, Luttermoser, T, Maas, B, Mace, K, Madeira, F, Mader, V, Cortesero, AM, Marini, L, Martinez, E, Martinson, HM, Menozzi, P, Mitchell, MGE, Miyashita, T, Molina, GAR, Molina-Montenegro, MA, O'Neal, ME, Opatovsky, I, Ortiz-Martinez, S, Nash, M, Ostman, O, Ouin, A, Pak, D, Paredes, D, Parsa, S, Parry, H, Perez-Alvarez, R, Perovic, DJ, Peterson, JA, Petit, S, Philpott, SM, Plantegenest, M, Plecas, M, Pluess, T, Pons, X, Potts, SG, Pywell, RF, Ragsdale, DW, Rand, TA, Raymond, L, Ricci, B, Sargent, C, Sarthou, J-P, Saulais, J, Schackermann, J, Schmidt, NP, Schneider, G, Schuepp, C, Sivakoff, FS, Smith, HG, Whitney, KS, Stutz, S, Szendrei, Z, Takada, MB, Taki, H, Tamburini, G, Thomson, LJ, Tricault, Y, Tsafack, N, Tschumi, M, Valantin-Morison, M, Mai, VT, van der Werf, W, Vierling, KT, Werling, BP, Wickens, JB, Wickens, VJ, Woodcock, BA, Wyckhuys, K, Xiao, H, Yasuda, M, Yoshioka, A, and Zou, Y

Abstract

The idea that noncrop habitat enhances pest control and represents a win-win opportunity to conserve biodiversity and bolster yields has emerged as an agroecological paradigm. However, while noncrop habitat in landscapes surrounding farms sometimes benefits pest predators, natural enemy responses remain heterogeneous across studies and effects on pests are inconclusive. The observed heterogeneity in species responses to noncrop habitat may be biological in origin or could result from variation in how habitat and biocontrol are measured. Here, we use a pest-control database encompassing 132 studies and 6,759 sites worldwide to model natural enemy and pest abundances, predation rates, and crop damage as a function of landscape composition. Our results showed that although landscape composition explained significant variation within studies, pest and enemy abundances, predation rates, crop damage, and yields each exhibited different responses across studies, sometimes increasing and sometimes decreasing in landscapes with more noncrop habitat but overall showing no consistent trend. Thus, models that used landscape-composition variables to predict pest-control dynamics demonstrated little potential to explain variation across studies, though prediction did improve when comparing studies with similar crop and landscape features. Overall, our work shows that surrounding noncrop habitat does not consistently improve pest management, meaning habitat conservation may bolster production in some systems and depress yields in others. Future efforts to develop tools that inform farmers when habitat conservation truly represents a win-win would benefit from increased understanding of how landscape effects are modulated by local farm management and the biology of pests and their enemies.

Published
2018

4. Organic farming affects the biological control of hemipteran pests and yields in spring barley independent of landscape complexity.

Author

Smith, H., Birkhofer, K., Arvidsson, F., Ehlers, D., Mader, V., and Bengtsson, J.

Subjects
ORGANIC farming, BIOLOGICAL pest control, APHIDS, SPIDERS, HOMOPTERA, DRYINIDAE, ECOSYSTEM services
Abstract

Context: Hemipteran pests cause significant yield losses in European cereal fields. It has been suggested that local management interventions to promote natural enemies are most successful in simple landscapes that are dominated by large arable fields. Objectives: We study how farming category (conventional, new and old organic fields) and landscape complexity affect pests, natural enemies and biological control services in spring barley. We further analyse if yields are related to pest infestation or biological control services. Methods: The amount of pasture and the length of field borders were used to define landscape complexity around barley fields in Southern Sweden. Arthropods were sampled with an insect suction sampler and predation and parasitism services were estimated by field observations and inspections of pest individuals. Results: Pest infestation was affected by landscape complexity, with higher aphid, but lower leafhopper numbers in more complex landscapes. Aphid predation was higher under organic farming and affected by effects on predator abundance and community composition independent of landscape complexity. Auchenorrhyncha parasitism was neither significantly affected by landscape complexity nor by farming category. Higher aphid predation rates and lower aphid densities were characteristic for organically managed fields with higher barley yields. Conclusions: Our results suggest that it is possible to increase both aphid biological control services and barley yield via local management effects on predator communities independent of landscape complexity. However, the success of such management practices is highly dependent on the pest and natural enemy taxa and the nature of the trophic interaction. [ABSTRACT FROM AUTHOR]

Published
2016
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6. Crop pests and predators exhibit inconsistent responses to surrounding landscape composition

Author

Karp, DS, Chaplin-Kramer, R, Meehan, TD, Martin, EA, DeClerck, F, Grab, H, Gratton, C, Hunt, L, Larsen, AE, Martínez-Salinas, A, O Rourke, ME, Rusch, A, Poveda, K, Jonsson, M, Rosenheim, JA, Schellhorn, NA, Tscharntke, T, Wratten, SD, Zhang, Wei, Iverson, AL, Adler, LS, Albrecht, M, Alignier, A, Angelella, GM, Anjum, MZ, Avelino, J, Batáry, P, Baveco, JM, Bianchi, FJJA, Birkhofer, K, Bohnenblust, EW, Bommarco, R, Brewer, MJ, Caballero-López, B, Carrière, Y, Carvalheiro, LG, Cayuela, L, Centrella, M, Ćetković, A, Henri, DC, Chabert, A, Costamagna, AC, De la Mora, A, de Kraker, J, Desneux, N, Diehl, E, Diekötter, T, Dormann, CF, Eckberg, JO, Entling, MH, Fiedler, D, Franck, P, van Veen, FJF, Frank, T, Gagic, V, Garratt, MPD, Getachew, A, Gonthier, DJ, Goodell, PB, Graziosi, I, Groves, RL, Gurr, GM, Hajian-Forooshani, Z, Heimpel, GE, Herrmann, JD, Huseth, AS, Inclán, DJ, Ingrao, AJ, Iv, P, Jacot, K, Johnson, GA, Jones, L, Kaiser, M, Kaser, JM, Keasar, T, Kim, TN, Kishinevsky, M, Landis, DA, Lavandero, B, Lavigne, C, Le Ralec, A, Lemessa, D, Letourneau, DK, Liere, H, Lu, Yanhui, Lubin, Y, Luttermoser, T, Maas, B, Mace, K, Madeira, F, Mader, V, Cortesero, AM, Marini, L, Martinez, E, Martinson, HM, Menozzi, P, Mitchell, MGE, Miyashita, T, Molina, GAR, Molina-Montenegro, MA, O'Neal, ME, Opatovsky, I, Ortiz-Martinez, S, Nash, M, Östman, Ö, Ouin, A, Pak, D, Paredes, D, Parsa, S, Parry, H, Perez-Alvarez, R, Perović, DJ, Peterson, JA, Petit, S, Philpott, SM, Plantegenest, M, Plećas, M, Pluess, T, Pons, X, Potts, SG, Pywell, RF, Ragsdale, DW, Rand, TA, Raymond, L, Ricci, B, Sargent, C, Sarthou, J-P, Saulais, J, Schäckermann, J, Schmitt, NP, Schneider, G, Schüepp, C, Sivakoff, FS, Smith, HG, Stack Whitney, K, Stutz, S, Szendrei, Z, Takada, MB, Taki, H, Tamburini, G, Thomson, LJ, Tricault, Y, Tsafack, N, Tschumi, M, Valantin-Morison, M, Van Trinh, M, van der Werf, W, Vierling, KT, Werling, BP, Wickens, JB, Wickens, VJ, Woodcock, BA, Wyckhuys, KAG, Xiao, Haijun, Yasuda, M, Yoshioka, A, and Zou Yi

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7. Prevalence and genetic diversity of avian haemosporidian parasites in wild bird species of the order Columbiformes.

Author

Schumm YR, Bakaloudis D, Barboutis C, Cecere JG, Eraud C, Fischer D, Hering J, Hillerich K, Lormée H, Mader V, Masello JF, Metzger B, Rocha G, Spina F, and Quillfeldt P

Subjects
Animal Migration, Animals, Bird Diseases parasitology, Columbidae parasitology, Cytochromes b genetics, Genetic Variation, Global Warming, Haemosporida classification, Haemosporida growth & development, Host Specificity, Mitochondria genetics, Multiplex Polymerase Chain Reaction veterinary, Phylogeny, Plasmodium genetics, Polymerase Chain Reaction veterinary, Prevalence, Protozoan Infections, Animal parasitology, Bird Diseases epidemiology, Columbiformes parasitology, Haemosporida genetics, Protozoan Infections, Animal epidemiology
Abstract

Diseases can play a role in species decline. Among them, haemosporidian parasites, vector-transmitted protozoan parasites, are known to constitute a risk for different avian species. However, the magnitude of haemosporidian infection in wild columbiform birds, including strongly decreasing European turtle doves, is largely unknown. We examined the prevalence and diversity of haemosporidian parasites Plasmodium, Leucocytozoon and subgenera Haemoproteus and Parahaemoproteus in six species of the order Columbiformes during breeding season and migration by applying nested PCR, one-step multiplex PCR assay and microscopy. We detected infections in 109 of the 259 screened individuals (42%), including 15 distinct haemosporidian mitochondrial cytochrome b lineages, representing five H. (Haemoproteus), two H. (Parahaemoproteus), five Leucocytozoon and three Plasmodium lineages. Five of these lineages have never been described before. We discriminated between single and mixed infections and determined host species-specific prevalence for each parasite genus. Observed differences among sampled host species are discussed with reference to behavioural characteristics, including nesting and migration strategy. Our results support previous suggestions that migratory birds have a higher prevalence and diversity of blood parasites than resident or short-distance migratory species. A phylogenetic reconstruction provided evidence for H. (Haemoproteus) as well as H. (Parahaemoproteus) infections in columbiform birds. Based on microscopic examination, we quantified parasitemia, indicating the probability of negative effects on the host. This study provides a large-scale baseline description of haemosporidian infections of wild birds belonging to the order Columbiformes sampled in the northern hemisphere. The results enable the monitoring of future changes in parasite transmission areas, distribution and diversity associated with global change, posing a potential risk for declining avian species as the European turtle dove.

Published
2021
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8. Crop pests and predators exhibit inconsistent responses to surrounding landscape composition.

Author

Karp DS, Chaplin-Kramer R, Meehan TD, Martin EA, DeClerck F, Grab H, Gratton C, Hunt L, Larsen AE, Martínez-Salinas A, O'Rourke ME, Rusch A, Poveda K, Jonsson M, Rosenheim JA, Schellhorn NA, Tscharntke T, Wratten SD, Zhang W, Iverson AL, Adler LS, Albrecht M, Alignier A, Angelella GM, Zubair Anjum M, Avelino J, Batáry P, Baveco JM, Bianchi FJJA, Birkhofer K, Bohnenblust EW, Bommarco R, Brewer MJ, Caballero-López B, Carrière Y, Carvalheiro LG, Cayuela L, Centrella M, Ćetković A, Henri DC, Chabert A, Costamagna AC, De la Mora A, de Kraker J, Desneux N, Diehl E, Diekötter T, Dormann CF, Eckberg JO, Entling MH, Fiedler D, Franck P, Frank van Veen FJ, Frank T, Gagic V, Garratt MPD, Getachew A, Gonthier DJ, Goodell PB, Graziosi I, Groves RL, Gurr GM, Hajian-Forooshani Z, Heimpel GE, Herrmann JD, Huseth AS, Inclán DJ, Ingrao AJ, Iv P, Jacot K, Johnson GA, Jones L, Kaiser M, Kaser JM, Keasar T, Kim TN, Kishinevsky M, Landis DA, Lavandero B, Lavigne C, Le Ralec A, Lemessa D, Letourneau DK, Liere H, Lu Y, Lubin Y, Luttermoser T, Maas B, Mace K, Madeira F, Mader V, Cortesero AM, Marini L, Martinez E, Martinson HM, Menozzi P, Mitchell MGE, Miyashita T, Molina GAR, Molina-Montenegro MA, O'Neal ME, Opatovsky I, Ortiz-Martinez S, Nash M, Östman Ö, Ouin A, Pak D, Paredes D, Parsa S, Parry H, Perez-Alvarez R, Perović DJ, Peterson JA, Petit S, Philpott SM, Plantegenest M, Plećaš M, Pluess T, Pons X, Potts SG, Pywell RF, Ragsdale DW, Rand TA, Raymond L, Ricci B, Sargent C, Sarthou JP, Saulais J, Schäckermann J, Schmidt NP, Schneider G, Schüepp C, Sivakoff FS, Smith HG, Stack Whitney K, Stutz S, Szendrei Z, Takada MB, Taki H, Tamburini G, Thomson LJ, Tricault Y, Tsafack N, Tschumi M, Valantin-Morison M, Van Trinh M, van der Werf W, Vierling KT, Werling BP, Wickens JB, Wickens VJ, Woodcock BA, Wyckhuys K, Xiao H, Yasuda M, Yoshioka A, and Zou Y

Subjects
Animals, Crops, Agricultural growth & development, Crops, Agricultural parasitology, Ecosystem, Models, Biological, Pest Control, Biological
Abstract

The idea that noncrop habitat enhances pest control and represents a win-win opportunity to conserve biodiversity and bolster yields has emerged as an agroecological paradigm. However, while noncrop habitat in landscapes surrounding farms sometimes benefits pest predators, natural enemy responses remain heterogeneous across studies and effects on pests are inconclusive. The observed heterogeneity in species responses to noncrop habitat may be biological in origin or could result from variation in how habitat and biocontrol are measured. Here, we use a pest-control database encompassing 132 studies and 6,759 sites worldwide to model natural enemy and pest abundances, predation rates, and crop damage as a function of landscape composition. Our results showed that although landscape composition explained significant variation within studies, pest and enemy abundances, predation rates, crop damage, and yields each exhibited different responses across studies, sometimes increasing and sometimes decreasing in landscapes with more noncrop habitat but overall showing no consistent trend. Thus, models that used landscape-composition variables to predict pest-control dynamics demonstrated little potential to explain variation across studies, though prediction did improve when comparing studies with similar crop and landscape features. Overall, our work shows that surrounding noncrop habitat does not consistently improve pest management, meaning habitat conservation may bolster production in some systems and depress yields in others. Future efforts to develop tools that inform farmers when habitat conservation truly represents a win-win would benefit from increased understanding of how landscape effects are modulated by local farm management and the biology of pests and their enemies., Competing Interests: The authors declare no conflict of interest., (Copyright © 2018 the Author(s). Published by PNAS.)

Published
2018
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9. Prevalence and genotyping of Trichomonas infections in wild birds in central Germany.

Author

Quillfeldt P, Schumm YR, Marek C, Mader V, Fischer D, and Marx M

Subjects
Animals, Animals, Wild classification, Animals, Wild parasitology, Bird Diseases parasitology, Birds classification, Birds parasitology, Genotype, Germany epidemiology, Prevalence, Species Specificity, Trichomonas classification, Trichomonas genetics, Trichomonas pathogenicity, Trichomonas Infections epidemiology, Trichomonas Infections parasitology, Bird Diseases epidemiology, Trichomonas Infections veterinary
Abstract

Avian trichomonosis is a widespread disease in columbids and other birds, caused by ingestion of the unicellular flagellate Trichomonas gallinae which proliferate primarily in the upper respiratory tracts. Studies using genetic analyses have determined some highly pathogenic lineages in birds, but the prevalence and distribution of potentially pathogenic and non-pathogenic T. gallinae lineages in wild birds is still not well known. We examined 440 oral swab samples of 35 bird species collected between 2015 and 2017 in Hesse, central Germany, for Trichomonas spp. infection and for determining the genetic lineages. Of these birds, 152 individuals were caught in the wild and 288 individuals were admitted from the wild to a veterinary clinic. The overall Trichomonas spp. prevalence was 35.6%. We observed significant differences between bird orders, with the highest prevalence in owls (58%) and columbids (50%), while other orders had slightly lower prevalences, with 36% in Accipitriformes, 28% in Falconiformes and 28% in Passeriformes. Among 71 successfully sequenced samples, we found 13 different haplotypes, including two previously described common lineages A/B (20 samples) and C/V/N (36 samples). The lineage A/B has been described as pathogenic, causing lesions and mortality in columbids, raptors and finches. This lineage was found in 11 of the 35 species, including columbids (feral pigeon, woodpigeon, stock dove), passerines (greenfinch, chaffinch, blackbird) and raptors (common kestrel, sparrowhawk, red kite, peregrine falcon and common buzzard). One new lineage (R) was found in a sample of a chaffinch. In conclusion, we found that the prevalence of Trichomonas spp. infection in wild birds was high overall, and the potentially pathogenic lineage A/B was widespread. Our findings are worrying, as epidemic outbreaks of trichomonosis have already been observed in Germany in several years and can have severe negative effects on bird populations. This disease may add to the multiple pressures that birds face in areas under high land-use intensity., Competing Interests: The authors have declared that no competing interests exist.

Published
2018
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10. Infrared saturation and phases of gauge theories with BRST symmetry.

Author

Mader V, Schaden M, Zwanziger D, and Alkofer R

Abstract

We investigate the infrared limit of the quantum equation of motion of the gauge boson propagator in various gauges and models with a BRST symmetry. We find that the saturation of this equation at low momenta distinguishes between the Coulomb, Higgs and confining phase of the gauge theory. The Coulomb phase is characterized by a massless gauge boson. Physical states contribute to the saturation of the transverse equation of motion of the gauge boson at low momenta in the Higgs phase, while the saturation is entirely due to unphysical degrees of freedom in the confining phase. This corollary to the Kugo-Ojima confinement criterion in linear covariant gauges also is sufficient for confinement in general covariant gauges with BRST and anti-BRST symmetry, maximal Abelian gauges with an equivariant BRST symmetry, non-covariant Coulomb gauge and in the Gribov-Zwanziger theory.

Published
2014
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