TY - JOUR AB - Social insect colonies have evolved many collectively performed adaptations that reduce the impact of infectious disease and that are expected to maximize their fitness. This colony-level protection is termed social immunity, and it enhances the health and survival of the colony. In this review, we address how social immunity emerges from its mechanistic components to produce colony-level disease avoidance, resistance, and tolerance. To understand the evolutionary causes and consequences of social immunity, we highlight the need for studies that evaluate the effects of social immunity on colony fitness. We discuss the role that host life history and ecology have on predicted eco-evolutionary dynamics, which differ among the social insect lineages. Throughout the review, we highlight current gaps in our knowledge and promising avenues for future research, which we hope will bring us closer to an integrated understanding of socio-eco-evo-immunology. AU - Cremer, Sylvia AU - Pull, Christopher AU - Fürst, Matthias ID - 806 JF - Annual Review of Entomology SN - 1545-4487 TI - Social immunity: Emergence and evolution of colony-level disease protection VL - 63 ER - TY - JOUR AB - Animal social networks are shaped by multiple selection pressures, including the need to ensure efficient communication and functioning while simultaneously limiting disease transmission. Social animals could potentially further reduce epidemic risk by altering their social networks in the presence of pathogens, yet there is currently no evidence for such pathogen-triggered responses. We tested this hypothesis experimentally in the ant Lasius niger using a combination of automated tracking, controlled pathogen exposure, transmission quantification, and temporally explicit simulations. Pathogen exposure induced behavioral changes in both exposed ants and their nestmates, which helped contain the disease by reinforcing key transmission-inhibitory properties of the colony's contact network. This suggests that social network plasticity in response to pathogens is an effective strategy for mitigating the effects of disease in social groups. AU - Stroeymeyt, Nathalie AU - Grasse, Anna V AU - Crespi, Alessandro AU - Mersch, Danielle AU - Cremer, Sylvia AU - Keller, Laurent ID - 7 IS - 6417 JF - Science SN - 1095-9203 TI - Social network plasticity decreases disease transmission in a eusocial insect VL - 362 ER - TY - GEN AB - Dataset for manuscript 'Social network plasticity decreases disease transmission in a eusocial insect' Compared to previous versions: - raw image files added - correction of URLs within README.txt file AU - Stroeymeyt, Nathalie AU - Grasse, Anna V AU - Crespi, Alessandro AU - Mersch, Danielle AU - Cremer, Sylvia AU - Keller, Laurent ID - 13055 TI - Social network plasticity decreases disease transmission in a eusocial insect ER - TY - JOUR AB - Background: The phenomenon of immune priming, i.e. enhanced protection following a secondary exposure to a pathogen, has now been demonstrated in a wide range of invertebrate species. Despite accumulating phenotypic evidence, knowledge of its mechanistic underpinnings is currently very limited. Here we used the system of the red flour beetle, Tribolium castaneum and the insect pathogen Bacillus thuringiensis (Bt) to further our molecular understanding of the oral immune priming phenomenon. We addressed how ingestion of bacterial cues (derived from spore supernatants) of an orally pathogenic and non-pathogenic Bt strain affects gene expression upon later challenge exposure, using a whole-transcriptome sequencing approach. Results: Whereas gene expression of individuals primed with the orally non-pathogenic strain showed minor changes to controls, we found that priming with the pathogenic strain induced regulation of a large set of distinct genes, many of which are known immune candidates. Intriguingly, the immune repertoire activated upon priming and subsequent challenge qualitatively differed from the one mounted upon infection with Bt without previous priming. Moreover, a large subset of priming-specific genes showed an inverse regulation compared to their regulation upon challenge only. Conclusions: Our data demonstrate that gene expression upon infection is strongly affected by previous immune priming. We hypothesise that this shift in gene expression indicates activation of a more targeted and efficient response towards a previously encountered pathogen, in anticipation of potential secondary encounter. AU - Greenwood, Jenny AU - Milutinovic, Barbara AU - Peuß, Robert AU - Behrens, Sarah AU - Essar, Daniela AU - Rosenstiel, Philip AU - Schulenburg, Hinrich AU - Kurtz, Joachim ID - 1006 IS - 1 JF - BMC Genomics SN - 14712164 TI - Oral immune priming with Bacillus thuringiensis induces a shift in the gene expression of Tribolium castaneum larvae VL - 18 ER - TY - GEN AB - Lists of all differentially expressed genes in the different priming-challenge treatments (compared to the fully naïve control; xlsx file). Relevant columns include the following: sample_1 and sample_2 – treatment groups being compared; Normalised FPKM sample_1 and sample_2 – FPKM of samples being compared; log2(fold_change) – log2(FPKM sample 2/FPKM sample 1), i.e. negative means sample 1 upregulated compared with sample 2, positive means sample 2 upregulated compared with sample 1; cuffdiff test_statistic – test statistic of differential expression test; p_value – p-value of differential expression test; q_value (FDR correction) – adjusted P-value of differential expression test. (XLSX 598 kb) AU - Greenwood, Jenny AU - Milutinovic, Barbara AU - Peuß, Robert AU - Behrens, Sarah AU - Essar, Daniela AU - Rosenstiel, Philip AU - Schulenburg, Hinrich AU - Kurtz, Joachim ID - 9859 TI - Additional file 1: Table S1. of Oral immune priming with Bacillus thuringiensis induces a shift in the gene expression of Tribolium castaneum larvae ER - TY - GEN AU - Greenwood, Jenny AU - Milutinovic, Barbara AU - Peuß, Robert AU - Behrens, Sarah AU - Essar, Daniela AU - Rosenstiel, Philip AU - Schulenburg, Hinrich AU - Kurtz, Joachim ID - 9860 TI - Additional file 5: Table S3. of Oral immune priming with Bacillus thuringiensis induces a shift in the gene expression of Tribolium castaneum larvae ER - TY - JOUR AB - Infections with potentially lethal pathogens may negatively affect an individual’s lifespan and decrease its reproductive value. The terminal investment hypothesis predicts that individuals faced with a reduced survival should invest more into reproduction instead of maintenance and growth. Several studies suggest that individuals are indeed able to estimate their body condition and to increase their reproductive effort with approaching death, while other studies gave ambiguous results. We investigate whether queens of a perennial social insect (ant) are able to boost their reproduction following infection with an obligate killing pathogen. Social insect queens are special with regard to reproduction and aging, as they outlive conspecific non-reproductive workers. Moreover, in the ant Cardiocondyla obscurior, fecundity increases with queen age. However, it remained unclear whether this reflects negative reproductive senescence or terminal investment in response to approaching death. Here, we test whether queens of C. obscurior react to infection with the entomopathogenic fungus Metarhizium brunneum by an increased egg-laying rate. We show that a fungal infection triggers a reinforced investment in reproduction in queens. This adjustment of the reproductive rate by ant queens is consistent with predictions of the terminal investment hypothesis and is reported for the first time in a social insect. AU - Giehr, Julia AU - Grasse, Anna V AU - Cremer, Sylvia AU - Heinze, Jürgen AU - Schrempf, Alexandra ID - 914 IS - 7 JF - Royal Society Open Science SN - 20545703 TI - Ant queens increase their reproductive efforts after pathogen infection VL - 4 ER - TY - GEN AB - Egg laying rates and infection loads of C. obscurior queens AU - Giehr, Julia AU - Grasse, Anna V AU - Cremer, Sylvia AU - Heinze, Jürgen AU - Schrempf, Alexandra ID - 9853 TI - Raw data from ant queens increase their reproductive efforts after pathogen infection ER - TY - JOUR AB - Social insect societies are long-standing models for understanding social behaviour and evolution. Unlike other advanced biological societies (such as the multicellular body), the component parts of social insect societies can be easily deconstructed and manipulated. Recent methodological and theoretical innovations have exploited this trait to address an expanded range of biological questions. We illustrate the broadening range of biological insight coming from social insect biology with four examples. These new frontiers promote open-minded, interdisciplinary exploration of one of the richest and most complex of biological phenomena: sociality. AU - Kennedy, Patrick AU - Baron, Gemma AU - Qiu, Bitao AU - Freitak, Dalial AU - Helantera, Heikki AU - Hunt, Edmund AU - Manfredini, Fabio AU - O'Shea Wheller, Thomas AU - Patalano, Solenn AU - Pull, Christopher AU - Sasaki, Takao AU - Taylor, Daisy AU - Wyatt, Christopher AU - Sumner, Seirian ID - 734 IS - 11 JF - Trends in Ecology and Evolution SN - 01695347 TI - Deconstructing superorganisms and societies to address big questions in biology VL - 32 ER - TY - THES AB - Contagious diseases must transmit from infectious to susceptible hosts in order to reproduce. Whilst vectored pathogens can rely on intermediaries to find new hosts for them, many infectious pathogens require close contact or direct interaction between hosts for transmission. Hence, this means that conspecifics are often the main source of infection for most animals and so, in theory, animals should avoid conspecifics to reduce their risk of infection. Of course, in reality animals must interact with one another, as a bare minimum, to mate. However, being social provides many additional benefits and group living has become a taxonomically diverse and widespread trait. How then do social animals overcome the issue of increased disease? Over the last few decades, the social insects (ants, termites and some bees and wasps) have become a model system for studying disease in social animals. On paper, a social insect colony should be particularly susceptible to disease, given that they often contain thousands of potential hosts that are closely related and frequently interact, as well as exhibiting stable environmental conditions that encourage microbial growth. Yet, disease outbreaks appear to be rare and attempts to eradicate pest species using pathogens have failed time and again. Evolutionary biologists investigating this observation have discovered that the reduced disease susceptibility in social insects is, in part, due to collectively performed disease defences of the workers. These defences act like a “social immune system” for the colony, resulting in a per capita decrease in disease, termed social immunity. Our understanding of social immunity, and its importance in relation to the immunological defences of each insect, continues to grow, but there remain many open questions. In this thesis I have studied disease defence in garden ants. In the first data chapter, I use the invasive garden ant, Lasius neglectus, to investigate how colonies mitigate lethal infections and prevent them from spreading systemically. I find that ants have evolved ‘destructive disinfection’ – a behaviour that uses endogenously produced acidic poison to kill diseased brood and to prevent the pathogen from replicating. In the second experimental chapter, I continue to study the use of poison in invasive garden ant colonies, finding that it is sprayed prophylactically within the nest. However, this spraying has negative effects on developing pupae when they have had their cocoons artificially removed. Hence, I suggest that acidic nest sanitation may be maintaining larval cocoon spinning in this species. In the next experimental chapter, I investigated how colony founding black garden ant queens (Lasius niger) prevent disease when a co-foundress dies. I show that ant queens prophylactically perform undertaking behaviours, similar to those performed by the workers in mature nests. When a co-foundress was infected, these undertaking behaviours improved the survival of the healthy queen. In the final data chapter, I explored how immunocompetence (measured as antifungal activity) changes as incipient black garden ant colonies grow and mature, from the solitary queen phase to colonies with several hundred workers. Queen and worker antifungal activity varied throughout this time period, but despite social immunity, did not decrease as colonies matured. In addition to the above data chapters, this thesis includes two co-authored reviews. In the first, we examine the state of the art in the field of social immunity and how it might develop in the future. In the second, we identify several challenges and open questions in the study of disease defence in animals. We highlight how social insects offer a unique model to tackle some of these problems, as disease defence can be studied from the cell to the society. AU - Pull, Christopher ID - 819 SN - 2663-337X TI - Disease defence in garden ants ER -