Local and global density have distinct and parasite-dependent effects on infection in wild sheep

Gregory F. Albery; Amy R. Sweeny; Yolanda Corripio-Miyar; Mike J. Evans; Adam D. Hayward; Josephine M. Pemberton; Jill G. Pilkington; Daniel H. Nussey

doi:10.1017/S0031182025100383

Local and global density have distinct and parasite-dependent effects on infection in wild sheep

Published online by Cambridge University Press: 01 July 2025

Gregory F. Albery ,

Amy R. Sweeny

Yolanda Corripio-Miyar ,

Mike J. Evans ,

Adam D. Hayward

Josephine M. Pemberton ,

Jill G. Pilkington and

Daniel H. Nussey

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Gregory F. Albery*: Affiliation:
School of Natural Sciences, Trinity College Dublin, Dublin, Republic of Ireland
Amy R. Sweeny*: Affiliation:
Institute of Ecology and Evolution, University of Edinburgh, Edinburgh, UK
Yolanda Corripio-Miyar: Affiliation:
Moredun Research Institute, Pentland Science Park, Penicuik, UK
Mike J. Evans: Affiliation:
Institute of Ecology and Evolution, University of Edinburgh, Edinburgh, UK
Adam D. Hayward: Affiliation:
Moredun Research Institute, Pentland Science Park, Penicuik, UK
Josephine M. Pemberton: Affiliation:
Institute of Ecology and Evolution, University of Edinburgh, Edinburgh, UK
Jill G. Pilkington: Affiliation:
Institute of Ecology and Evolution, University of Edinburgh, Edinburgh, UK
Daniel H. Nussey: Affiliation:
Institute of Ecology and Evolution, University of Edinburgh, Edinburgh, UK
*: Corresponding authors: Amy R. Sweeny; Email: amyr.sweeny@gmail.com; Gregory F. Albery; Email: gfalbery@gmail.com
Corresponding authors: Amy R. Sweeny; Email: amyr.sweeny@gmail.com; Gregory F. Albery; Email: gfalbery@gmail.com

Article contents

Abstract
Introduction
Materials and methods
Results
Discussion
Supplementary material
Data availability
Author contributions
Financial support
Ethical standards
Footnotes
References

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Abstract

High density should drive greater parasite exposure. However, evidence linking density with infection generally uses density proxies or measures of population size, rather than measures of individuals per space within a continuous population. We used a long-term study of wild sheep to link within-population spatiotemporal variation in host density with individual parasite counts. Although four parasites exhibited strong positive relationships with local density, these relationships were mostly restricted to juveniles and faded in adults. Furthermore, one ectoparasite showed strong negative relationships across all age classes. In contrast, population size – a measure of global density – had limited explanatory power, and its effects did not remove those of spatial density, but were distinct. These results indicate that local and global density can exhibit diverse and contrasting effects on infection within populations. Spatial measures of within-population local density may provide substantial additional insight to temporal metrics based on population size, and investigating them more widely could be revealing.

Keywords

density dependence disease ecology mammal parasites spatial modelling ungulate

Information

Type: Research Article
Information: Parasitology , First View , pp. 1 - 9

DOI: https://doi.org/10.1017/S0031182025100383 [Opens in a new window]
Creative Commons: This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright: © The Author(s), 2025. Published by Cambridge University Press.

Introduction

An animal’s infection status is driven by its exposure to pathogens, in concert with its susceptibility to infection once exposed (Sweeny and Albery, Reference Sweeny and Albery2022). Individuals living in areas of greater population density generally encounter each other more frequently, resulting in a higher per capita exposure rate that drives greater prevalence of directly transmitted parasites (McCallum et al., Reference McCallum, Barlow and Hone2001; Lloyd-Smith et al., Reference Lloyd-Smith, Cross, Briggs, Daugherty, Getz, Latto, Sanchez, Smith and Swei2005; Wilson and Cotter, Reference Wilson and Cotter2009; Hopkins et al., Reference Hopkins, Fleming-Davies, Belden and Wojdak2020). Additionally, when density drives individuals to share the same space at higher rates, it could likewise drive higher indirect contact rates, leading to greater prevalence of indirectly transmitted parasites. However, density–contact relationships (and therefore density-infection relationships) are likely to differ substantially for parasites of different transmission modes (Hopkins et al., Reference Hopkins, Fleming-Davies, Belden and Wojdak2020): for example, individuals may be more likely to avoid direct contact while nevertheless sharing space, which could drive more positive density dependence of indirectly than directly transmitted pathogens (Albery et al., Reference Albery, Becker, Firth, Moor, Ravindran, Silk, Sweeny, Wal, Webber, Allen, Babayan, Barve, Begon, Birtles, Block, Block, Bradley, Budischak, Buesching, Burthe, Carlisle, Caselle, Cattuto, Chaine, Chapple, Cheney, Clutton-Brock, Collier, Curnick, Delahay, Farine, Fenton, Ferretti, Feyrer, Fielding, Foroughirad, Frere, Gardner, Geffen, Godfrey, Graham, Hammond, Henrich, Heurich, Hopwood, Ilany, Jackson, Jackson, Jacoby, Jacoby, Ježek, Kirkpatrick, Klamm, Klarevas-Irby, Knowles, Koren, Krzyszczyk, Kusch, Lambin, Lane, Leirs, Leu, Lyon, MacDonald, Madsen, Mann, Manser, Mariën, Massawe, McDonald, Morelle, Mourier, Newman, Nussear, Nyaguthii, Ogino, Ozella, Packer, Papastamatiou, Paterson, Payne, Pedersen, Pemberton, Pinter-Wollman, Planes, Raulo, Rodríguez-Muñoz, Rudd, Sabuni, Sah, Schallert, Sheldon, Shizuka, Sih, Sinn, Sluydts, Spiegel, Telfer, Thomason, Tickler, Tregenza, VanderWaal, Walmsley, Walters, Wanelik, Whitehead, Wielgus, Wilson-Aggarwal, Wohlfeil and Bansal2025). Alternatively, animals may be able to more easily identify areas of environmental parasite transmission than of infected conspecifics, which would drive the reverse. Identifying these relationships is important for accurately modelling disease dynamics in many contexts (Hu et al., Reference Hu, Nigmatulina and Eckhoff2013; Hopkins et al., Reference Hopkins, Fleming-Davies, Belden and Wojdak2020), and can influence the choice of available interventions. For example, where a disease is transmitted by density-independent interactions, culling the host is unlikely to be effective in reducing its prevalence (Morters et al., Reference Morters, Restif, Hampson, Cleaveland, Wood and Conlan2013).

Nevertheless, despite a great many studies that employ density dependence functions (reviewed in Hopkins et al., Reference Hopkins, Fleming-Davies, Belden and Wojdak2020), there exist relatively few empirical examples of density driving greater infection in individual wild animals. Much existing evidence is phenomenologically derived or relies on between-species comparisons (e.g. Cote and Poulin, Reference Cote and Poulin1995; Rifkin et al., Reference Rifkin, Nunn and Garamszegi2012; Patterson and Ruckstuhl, Reference Patterson and Ruckstuhl2013), which can be fraught with compensatory evolutionary changes, e.g. in social structure (Poulin and Filion, Reference Poulin and Filion2021). More simply, much of this evidence uses metrics like population size (Coltman et al., Reference Coltman, Pilkington, Smith, Pemberton and Josephine1999; Body et al., Reference Body, Ferte, Gaillard, Delorme, Klein, Gilot-Fromont, Fert??, Gaillard, Delorme, Klein, Gilot-Fromont, Body, Ferté, Gaillard, Delorme, Klein and Gilot-Fromont2011), or social connectedness metrics like group size (Cote and Poulin, Reference Cote and Poulin1995). While social contact rates will often correlate positively with density (Davis et al., Reference Davis, Abbasi, Shah, Telfer, Begon and Davis2015; Borremans et al., Reference Borremans, Reijniers, Hughes, Godfrey, Gryseels, Makundi and Leirs2017; Albery et al., Reference Albery, Morris, Morris, Pemberton, Clutton‐Brock, Nussey and Firth2021a), social and spatial behaviour can differ inherently and can break this expectation in complex ways, such that using ‘purely social’ metrics may not detect effects of density (i.e. ‘individuals per space’) per se. As such, it is unclear whether population density drives infection within animal systems.

Investigating density itself (i.e., individuals per space, rather than measures of pure sociality) is important because there are a variety of reasons to expect that density will not show a positive relationship with infection (Albery et al., Reference Albery, Newman, Bright Ross, Macdonald, Bansal and Buesching2020; Albery, Reference Albery2022). For example, habitat selection likely causes individuals to inhabit areas with abundant resources, which creates a positive relationship between nutrition and density; if nutrition results in improved immune resistance (Becker and Hall, Reference Becker and Hall2014), this could drive a negative relationship with parasite count – unless the availability of the added resources is cancelled out by greater competition (Albery, Reference Albery2022; Hasik et al., Reference Hasik, Butt, Maris, Morris, Morris, Turner, Pemberton and Albery2024). Reciprocally, competition for resources in a given area is likely to be better approximated by global density, as measured by population size, such that fitting population size as a metric picks up competition for resources more than (or over and above) greater contact rates. These and related processes (see Albery et al., Reference Albery, Newman, Bright Ross, Macdonald, Bansal and Buesching2020; Albery, Reference Albery2022) could manifest differently for different parasites or host groups within a given population, but such variation in relationships has never been shown and has rarely been investigated. In European badgers (Meles meles), social contact metrics showed no relationship with any of the five investigated parasites, but a within-population socio-spatial density metric showed a consistent negative linear relationship with four parasites of different transmission modes and host specificities (Albery et al., Reference Albery, Newman, Bright Ross, Macdonald, Bansal and Buesching2020). This negative density dependence was the likely result of parasite avoidance behaviours in space (Buck et al., Reference Buck, Weinstein and Young2018; Weinstein et al., Reference Weinstein, Buck and Young2018). While other studies have shown that density–infection relationships can depend on the timescale at which they are examined (Stewart Merrill et al., Reference Stewart Merrill, Cáceres, Gray, Laird, Schnitzler and Buck2022), as well as other complex patterns of risk (Buck et al., Reference Buck, Hechinger, Wood, Stewart, Kuris and Lafferty2017a), few studies have investigated whether density–infection trends diverge across multiple parasites. Understanding why these varied trends might occur is important for understanding how and why parasites regulate spatiotemporal population distributions (Albery, Reference Albery2022). If density drives infections, which then influence behaviour and fitness, this process could ultimately feed back to determine who dies where, thereby shaping the distribution of the population in space and time.

The Soay sheep (Ovis aries) of St Kilda have been studied since 1985, with individual-based measurements of behaviour, life history, and parasitism throughout this time (Clutton-Brock and Pemberton, Reference Clutton-Brock and Pemberton2004). The population descend from early European domestic sheep that were introduced to the island of Soay thousands of years ago, have experienced minimal human management since then, and currently live unmanaged (‘wild’) on Hirta in the St Kilda archipelago (Clutton-Brock and Pemberton, Reference Clutton-Brock and Pemberton2004). They host a diversity of gastrointestinal parasites, all of which have some environmental phase in between hosts and achieve reinfection through reingestion (Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004; Hayward et al., Reference Hayward, Behnke, Childs, Corripio-Miyar, Fenton, Fraser, Kenyon, McNeilly, Pakeman, Pedersen, Pemberton, Sweeny, Wilson and Pilkington2022). They also host sheep keds (Melophagus ovinus): wingless ectoparasitic flies that achieve transmission through direct contact (Small, Reference Small2005). Of these parasites, strongyle nematodes are the most important in that they exert strong fitness costs at all life stages (Coltman et al., Reference Coltman, Pilkington, Smith, Pemberton and Josephine1999; Leivesley et al., Reference Leivesley, Bussière, Pemberton, Pilkington, Wilson and Hayward2019). Strongyle infection dynamics in the sheep are broadly thought to be driven by population density, where high numbers of grazing sheep produce larger numbers of infectious larvae to be ingested, which then results in greater exposure and therefore greater infection (Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004). This mechanism has been linked with greater parasite infection in lambs in high-density years (Hayward et al., Reference Hayward, Pilkington, Pemberton and Kruuk2010, Reference Hayward, Behnke, Childs, Corripio-Miyar, Fenton, Fraser, Kenyon, McNeilly, Pakeman, Pedersen, Pemberton, Sweeny, Wilson and Pilkington2022), and is thought to regulate the population by driving worse condition and greater mortality in these years (Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004). Nevertheless, the remaining parasites in the population have yet to be successfully linked with population density (Hayward et al., Reference Hayward, Behnke, Childs, Corripio-Miyar, Fenton, Fraser, Kenyon, McNeilly, Pakeman, Pedersen, Pemberton, Sweeny, Wilson and Pilkington2022), and strongyles have not been linked with within-year density metrics or aligned with spatial host distributions. Rather, all density analyses have been carried out by linking total population size with infection in a given year, with only one density value applied across the population per year (Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004). As such, it remains to be seen how strongyles are driven by density on finer spatiotemporal scales, and whether the density trends are ubiquitous or specific to strongyles. Notably, a previous study found a strong positive correlation between vegetation quality and strongyle count in lambs, which could be linked to greater density in higher-quality areas (Wiersma et al., Reference Wiersma, Pakeman, Bal, Pilkington, Pemberton, Nussey and Sweeny2023).

Here, we use 25 years of data in this wild population to examine how a spatial measure of local density drives individual-level infection prevalence and intensity across a range of host age classes, when accounting for global density as approximated by population size. We expected local density to be broadly positively correlated with infection through its association with greater direct and indirect contact rates, driving greater exposure, and that these effects would be differentiable from – and additional to – positive effects of global density.

Materials and methods

Study population and parasitology

The Soay sheep are an isolated and unmanaged population that has been monitored since 1985 on the St. Kilda archipelago (57°49′N, 08°34′W, 65 km NW of the Outer Hebrides, Scotland) (Clutton-Brock and Pemberton, Reference Clutton-Brock and Pemberton2004). Individuals in the Village Bay area of the largest island, Hirta, are individually marked each year and followed longitudinally, with over 95% of individuals in this area being marked at any time (Clutton-Brock et al., Reference Clutton-Brock, Price, Albon and Jewell1992). Each spring, lambs are caught shortly after birth in April (typically within a week), marked with unique ear tags, and weighed. In August, as many individuals as possible are caught in corral traps over a 2-week period, with 50–60% of the resident Village Bay sheep population captured each year (Clutton-Brock and Pemberton, Reference Clutton-Brock and Pemberton2004). Each year, 30 population censuses are carried out by experienced field workers (10 each in spring, summer, and autumn); our dataset comprised 961 such censuses. During censuses, fieldworkers follow established routes noting the identity, spatial location (to nearest 100 m OS grid square), behaviour and group membership of individual sheep.

Gastrointestinal parasites were quantified using a modified McMaster technique (Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004) to enumerate faecal egg counts (FEC, nematodes) or faecal oocyst counts (FOC, protozoans). FEC measures via McMaster techniques have been shown to correlate well to parasite burden in Soay Sheep (Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004). FEC/FOC was performed on faecal samples collected in August of each year rectally when animals are captured for morphological measurements and sampling, or from observed defecation within several days of capture where rectal samples could not be obtained. Samples were stored at 4°C until processing which occurred within several weeks of sample collection. Parasite communities of Soay sheep are comprised primarily of gastrointestinal parasites and resemble those of domestic sheep, with the exception of Haemonchus contortus. Strongyle nematodes are the dominant group within the Soay parasite fauna, of which there are six known species present in the population, Teladorsagia circumcincta, Trichostrongylus axei, Tricholostrongylous virtrinus, Chabertia ovina, Bunostomum trignonocephalum, and Strongyloides papillosus. Due to morphological similarities in gastrointestinal nematode eggs which are very difficult or impossible to distinguish, eggs of these species are grouped as a single ‘strongyle’ FEC count within each sample, with the exception of S. papillosus, which is morphologically distinguishable and recorded as present or absent. Soay sheep are also commonly infected with the apicomplexan genus Eimiera. Oocysts present in samples from the 11 known species infecting Soay sheep are indistinguishable by eye and grouped as one ‘coccidia’ FOC. Eggs of additional GI helminths Nematodirus spp., Capillaria longipes, and Trichuris ovis are quantified as distinct FECs and the cestode Moniezia expansa is scored as present or absent. Although strongyles and coccidia are ubiquitous across age classes and the most common parasite taxa, other taxa are often present at very low prevalence (e.g. T. ovis and C. longipes) or only present in specific age categories (e.g. Nematodirus spp. in lambs). In addition to gastrointestinal parasites, Soay sheep host the wingless ecotoparasitic fly Melophagus ovinus (keds). At each August capture when faecal samples were collected, ked counts were enumerated for each individual via a visual inspection and 1 minute standardized search of the wool on the abdominal region of the animal. FEC/FOC and ked count data used in this study were collected from 1993 to 2017.

Density measures

We calculated a local density metric for each individual, using all observations of each individual in each year. Our measure of local density followed a method previously described in badgers and deer (Albery et al., Reference Albery, Morris, Morris, Pemberton, Clutton‐Brock, Nussey and Firth2021a, Reference Albery, Clutton-brock, Morris, Morris, Pemberton, Nussey and Firth2022a), as well as a recent meta-analysis of spatial and social behaviour across wild animal systems (Albery et al., Reference Albery, Becker, Firth, Moor, Ravindran, Silk, Sweeny, Wal, Webber, Allen, Babayan, Barve, Begon, Birtles, Block, Block, Bradley, Budischak, Buesching, Burthe, Carlisle, Caselle, Cattuto, Chaine, Chapple, Cheney, Clutton-Brock, Collier, Curnick, Delahay, Farine, Fenton, Ferretti, Feyrer, Fielding, Foroughirad, Frere, Gardner, Geffen, Godfrey, Graham, Hammond, Henrich, Heurich, Hopwood, Ilany, Jackson, Jackson, Jacoby, Jacoby, Ježek, Kirkpatrick, Klamm, Klarevas-Irby, Knowles, Koren, Krzyszczyk, Kusch, Lambin, Lane, Leirs, Leu, Lyon, MacDonald, Madsen, Mann, Manser, Mariën, Massawe, McDonald, Morelle, Mourier, Newman, Nussear, Nyaguthii, Ogino, Ozella, Packer, Papastamatiou, Paterson, Payne, Pedersen, Pemberton, Pinter-Wollman, Planes, Raulo, Rodríguez-Muñoz, Rudd, Sabuni, Sah, Schallert, Sheldon, Shizuka, Sih, Sinn, Sluydts, Spiegel, Telfer, Thomason, Tickler, Tregenza, VanderWaal, Walmsley, Walters, Wanelik, Whitehead, Wielgus, Wilson-Aggarwal, Wohlfeil and Bansal2025). This approach uses a kernel density estimator with the package `adehabitathr`, taking individuals’ annual centroids and fitting a two-dimensional smoother to the distribution of the data (Calenge, Reference Calenge2019). Individuals are then assigned a local density value based on their annual location on this kernel. This variable therefore represents, for each individual, how many other individuals live in its proximity (i.e. individuals per space) in a way that varies predictably across the population and between years.

Models

Our dataset included 6739 annual measures of 3231 individual sheep, spread across 25 years (1993–2017). We conducted the analysis using R version 4.2.3 (R Core Team, 2020). Due to low prevalence, we investigated Nematodirus only in lambs and Capillaria only in lambs and yearlings (i.e. not in adults). Due to some substantial overdispersion in counts, we excluded outliers that were greater than a given value for several parasites (Strongyles – 2500, Strongyloides – 400, Coccidia – 20,000).

Spatial heterogeneity models

First, to examine spatial patterns of infection, we fitted generalized linear mixed models (GLMMs) using the Integrated Nested Laplace Approximation (INLA) in R (Lindgren et al., Reference Lindgren, Rue and Lindstrom2011; Lindgren and Rue, Reference Lindgren and Rue2015), which is well-suited to identifying spatial autocorrelation and mapping the spatial distribution of wildlife disease (Albery et al., Reference Albery, Becker, Kenyon, Nussey and Pemberton2019, Reference Albery, Sweeny, Becker and Bansal2022b). We examined each parasite as a count-based response variable with a negative binomial distribution, except the rarer Capillaria and Nematodirus, for which we used a binomial distribution investigating binary infection status. We fitted explanatory variables including Sex (two levels: F and M) and Age Category (three levels: Lamb, Yearling, and Adult), with random effects of Individual and Year. To quantify spatial autocorrelation, we fitted a stochastic partial differentiation equation (SPDE) effect, which models samples’ similarity that emerges from their proximity in space. We fitted this effect and compared the fit of the model with and without the effect using deviance information criterion (DIC); a value of 2ΔDIC was taken to denote competitive models – i.e. if adding the SPDE effect reduced DIC by more than 2, it was taken to be significantly spatially autocorrelated. For those parasites with significant spatial heterogeneity, we plotted the distribution of the SPDE effect in space to identify hot- and coldspots of infection.

Density models

To identify density-related changes in parasite burden and determine their probable causes, we fitted another selection of GLMMs. These model sets each investigated a different host group: lambs, yearlings, adults, or the population as a whole. We fitted a fixed effect of Sex (two levels: F and M) with random effects of Individual and Year. For the adult models, we included Reproductive Status (Factor with 3 levels: Non-Reproductive Female, Reproductive Female, and Male, instead of Sex); and Age (continuous). For the overall models, we fitted age category (three levels: Lamb, Yearling, and Adult). Finally, we added two measures of density: individual, spatially defined local density (continuous, standardized to have a mean of 0 and a standard deviation of 1), and population-level measures of global density, defined as the population size in the village bay the following year (continuous, range 211–672, standardized to have a mean of 0 and a standard deviation of 1). Comparing the fit and significance of these two variables would allow us to differentiate effects of local and global density on infection.

Results

All effect estimates and credibility intervals are given in Supplementary Material. Our spatial INLA models found strong spatial autocorrelation in four parasites overall (Figure 1): strongyles (ΔDIC = 6.70); coccidia (ΔDIC = 26.16); Nematodirus (ΔDIC = 10.39), and keds (ΔDIC = 34.17). Neither Strongyloides nor Capillaria were spatially autocorrelated (ΔDIC < 2). Their spatial distributions are displayed in Figure 1. Broadly, there were relatively discordant patterns of the four parasites, but strongyles and Nematodirus were generally concentrated in the northeast corner of the population (Figure 1A, C), while coccidia were more concentrated in the southeast (Figure 1B) and keds stood out especially with a strong gradient towards the southwest (Figure 1D).

Figure 1. Spatial distributions of four spatially autocorrelated parasites, displayed using the two-dimensional distribution of the stochastic partial differentiation equation (SPDE) effect from the spatial models including year, sex, age, and random effects of individual and year. Darker colours represent greater parasite count (A, B, D) or prevalence (C), in log- (A, B, D) or logistic (C) units from the mean. Points represent individual average locations based on the population censuses; points are transparent to minimise overplotting. The black line represents the approximate border of the study area.

Fitting individuals’ local density as a fixed effect (overall density distribution displayed in Figure 2A), parasites revealed different relationships with density across age classes (see Figure 2B for all coefficients and P-values). The 3/6 parasites were positively associated with density in lambs (coccidia, strongyles, and Nematodirus), 2/5 in yearlings (Capillaria and coccidia), and 1/4 in adults (coccidia) (Figure 3). Additionally, counts of keds were negatively correlated with density overall and across all age classes (Figure 2B; Figure 4).

Figure 2. (A) Sheep density distribution across the population in space, displayed as an average across the study period. The x and y axes are in easting and northings; 1 unit = 100 m. Darker red colours correspond to greater sheep density in relative units of individuals per space; white contours have been added for clarification. The black line represents the approximate border of the study area, to be aligned with the INLA fields in Figure 1. (B) Tile plot depicting the effect sizes for density-infection relationships across parasites and age categories. Tiles are coloured according to the relative positive (pink) or negative (blue) values; a missing tile means the combination was not tested due to low prevalence. Numbers denote the effect size on the log-link scale, with 95% credibility intervals in brackets, and P-values. Opaque writing denotes significant effects (i.e., their credibility intervals did not overlap with zero); transparent writing denotes non-significant effects. (C) Effect of global density on parasite count were generally harder to detect than those of local density. Points represent the mean for each effect estimate; error bars denote 95% credibility intervals. All estimates are given on the link scale. Opaque error bars denote estimates that were significant (i.e., their credibility intervals did not overlap with zero); transparent estimates overlap with zero. All effect estimates are given in units of standard deviation.

Figure 3. Positive relationships between density and infection in soay sheep across multiple age categories and parasites. Taken from our density GLMMS, the dark black line represents the mean of the posterior distribution for the age effect estimate; the light grey lines are 100 random draws from the posterior to represent uncertainty. The density effect estimate, credibility intervals, and P-values are given at the top of each panel. The points represent individual samples, with transparency to help visualize overplotting. The y-axis (A, D-F) represents counts of eggs or oocysts per gram and has been log10-transformed; 0-counts (which are not possible to display on this logged scale) are displayed at the bottom of the graph. The y-axis (B-C) represents binary infection status (0/1).

Figure 4. Negative density effects on counts of wingless ectoparasites (keds, melophaga ovinus) in A) lambs; B) yearlings; and C) adult sheep. Taken from our density glmms, the dark black line represents the mean of the posterior distribution for the age effect estimate; the light grey lines are 100 random draws from the posterior to represent uncertainty. The density effect estimate, credibility intervals, and p values are given at the top of each panel. The points represent individual samples, with transparency to help visualize overplotting. The y axis represents counts of keds, and has been log10-transformed; 0-counts (which are not possible to display on this logged scale) are displayed at the bottom of the graph.

In contrast, global density (as approximated by population size the year before sampling) only significantly affected strongyles, in adults (Estimate 0.109; 95% CI 0.014, 0.204; P = 0.0241) and lambs (0.183; 0.007, 0.359; P = 0.042) but not yearlings (0.092; −0.02, 0.205; P = 0.11). Notably, none of these effects removed the effects of local density (see Figure 2C for model estimates); in fact, fitting global density caused the negative effect of local density on ked infection to become significantly negative in lambs. On the contrary, global density’s effect on strongyle infection was additional to local density’s effect in lambs, and provided the only positive density effect on adult infection except for coccidia. Taken together, these results imply that global density and local density are not interchangeable, but complementary sources of information.

Discussion

As expected, we uncovered strong, largely positive relationships between population density and parasite infection in wild Soay sheep, but with density effects differing substantially across both parasite taxon and host age class. Population density likely drives greater helminth infection by driving greater indirect contact: that is, if more individuals are inhabiting and shedding parasites in higher-density areas, the parasites will achieve a higher concentration on the pasture, thereby driving greater individual-level exposure in these areas. This corroborates prior knowledge concerning the role of population density in driving infection in this population via greater environmental exposure (Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004; Hayward et al., Reference Hayward, Behnke, Childs, Corripio-Miyar, Fenton, Fraser, Kenyon, McNeilly, Pakeman, Pedersen, Pemberton, Sweeny, Wilson and Pilkington2022) – and offers an explanation for the previously observed positive correlation between strongyle count in lambs and preferred vegetation, which is likely to coincide with areas of high host density (Wiersma et al., Reference Wiersma, Pakeman, Bal, Pilkington, Pemberton, Nussey and Sweeny2023). However, our use of individual-level (spatial) density metrics allowed us to pick up much finer-scale relationships between density and infection, and thereby detected several more such relationships than previous studies. This demonstrates the value of considering the socio-spatial structuring of a population when examining density–infection interactions (e.g. Albery et al., Reference Albery, Newman, Bright Ross, Macdonald, Bansal and Buesching2020), rather than focussing solely on variation in population size. Furthermore, while 4/6 parasites showed one or more strong positive relationships with density in lambs or yearlings, there was far weaker evidence of positive density-dependent infection in adults, and ectoparasitic biting fly (‘ked’, M. ovinus) counts showed unexpected negative correlations with density. Overall, these results serve to demonstrate that socio-spatial measures of population density can influence parasite infection differently across different host and parasite categories within the same population. More generally applying this methodology across spatially distributed animal populations (e.g. as previously shown in badgers (Albery et al., Reference Albery, Newman, Bright Ross, Macdonald, Bansal and Buesching2020)), could uncover generalities and contingencies in the factors shaping density–infection relationships (Albery, Reference Albery2022), allowing us to better understand the mechanisms driving divergent density-infection trends across parasites like these.

Our findings support the role of spatiotemporally heterogeneous population distributions in determining the landscape of infection, and specifically in driving higher burdens in more-social individuals (Altizer et al., Reference Altizer, Nunn, Thrall, Gittleman, Antonovics, Cunningham, Dobson, Ezenwa, Jones, Pedersen, Poss and Pulliam2003). If parasites have fitness costs, as they are known to in this population (Coltman et al., Reference Coltman, Pilkington, Smith, Pemberton and Josephine1999; Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004; Leivesley et al., Reference Leivesley, Bussière, Pemberton, Pilkington, Wilson and Hayward2019), these parasites will likely play an important role regulating the sheep population in space. That is, if density drives higher parasite count and parasites negatively impact fitness, density ultimately drives its own sink factor, determining who dies where. Future studies could attempt to link density and infection with fitness directly to test this spatially explicit population regulation – e.g. via structural equation modelling, which has previously shown that parasites regulate individual reproductive fitness in a similar way in this population (Leivesley et al., Reference Leivesley, Bussière, Pemberton, Pilkington, Wilson and Hayward2019). They could further examine whether density-infection relationships depend on resource availability, which should be reduced in higher-density areas and years in this population; this combined exacerbation of exposure and susceptibility will likely exponentially influence parasite count and disproportionately limit the population’s size and density (Wilson et al., Reference Wilson, Grenfell, Pilkington, Boyd, Gulland, Clutton-Brock and Pemberton2004; Wiersma et al., Reference Wiersma, Pakeman, Bal, Pilkington, Pemberton, Nussey and Sweeny2023).

There are several possible explanations for our observation of more positive density-infection relationships in lambs and yearlings than in adults: first, because young individuals have naïve immune systems they are generally highly susceptible to infection, which likely leaves exposure as the main contributor to parasite count (Albery, Reference Albery2022). In contrast, between-individual variation in immunity could be complicating relationships between density (i.e. exposure) and infection in older individuals (Albery et al., Reference Albery, Newman, Bright Ross, Macdonald, Bansal and Buesching2020; Albery, Reference Albery2022). Alternatively, a similar pattern could arise because young individuals are particularly vulnerable to stresses associated with higher density-like greater resource competition, reducing their immune resistance and therefore driving greater parasite count (Becker and Hall, Reference Becker and Hall2014). This may be supported by the previously observed positive correlation between strongyle count in lambs and high-quality vegetation, which is likely to coincide with areas of high host density (Wiersma et al., Reference Wiersma, Pakeman, Bal, Pilkington, Pemberton, Nussey and Sweeny2023). Alternatively, age-related differences in density–infection patterns could arise through demographic processes linked to those described above: in higher-density areas, heavily infected lambs may die more quickly (Coltman et al., Reference Coltman, Pilkington, Smith, Pemberton and Josephine1999), leaving behind more resistant lambs and therefore producing a less positive relationship between density and infection at the population level in older individuals (i.e. ‘selective disappearance’ (van de Pol and Verhulst, Reference van de Pol and Verhulst2006)). These findings suggest that density-dependent trends might manifest preferentially for vulnerable (immunologically weaker) classes of hosts, rather than appearing evenly across a population.

Only protozoan coccidia showed consistently positive relationships with density across age categories. Although this could be slightly surprising given that coccidia are generally regarded as more important parasites of juveniles, particularly in ruminants (Chartier and Paraud, Reference Chartier and Paraud2012), coccidia intensities generally peak across the population in Spring, when lamb density is greatest (Sweeny et al., Reference Sweeny, Corripio-Miyar, Bal, Hayward, Pilkington, McNeilly, Nussey and Kenyon2022), and independently of the sex and reproductive status effects evident in helminth infections (Hayward et al., Reference Hayward, Pilkington, Wilson, McNeilly and Watt2019). This observation suggests a combination of lifelong incomplete resistance to infection, such that oocyst concentration on the pasture is a central determinant of individuals’ parasite counts, leading to higher counts in the context of high exposure rates (i.e. in higher-density areas). Although parasite counts are relatively consistent in individuals within and across years, coccidia infections tend to be less repeatable and chronic than nematode infections (Clutton-Brock and Pemberton, Reference Clutton-Brock and Pemberton2004; Sweeny et al., Reference Sweeny, Corripio-Miyar, Bal, Hayward, Pilkington, McNeilly, Nussey and Kenyon2022). We therefore believe that it is more likely that incomplete resistance and density-driven exposure persist over the lifespan and lead to recrudescence, rather than infections becoming established in early life and persisting. In addition, compared to other parasites, coccidia may be more strongly linked to reduced condition in higher-density areas across all host groups, or their transmission could be more efficient in areas of higher density due to vegetation composition or microclimate, for example. The fitness and condition impacts of coccidia have only rarely been examined in this population (Craig et al., Reference Craig, Tempest, Pilkington and Pemberton2008), but we may be able to interrogate these mechanisms in the future – particularly if combined with analyses of vegetation composition and socio-spatial behaviour (Wiersma et al., Reference Wiersma, Pakeman, Bal, Pilkington, Pemberton, Nussey and Sweeny2023). Altogether, the role of coccidia in density-dependent regulation of this population could be stronger than previously anticipated.

Contrasting with strongyles and coccidia, we observed consistently negative density effects on counts of ectoparasitic ked flies, which begs explanation, particularly given that direct-contact-transmitted pathogens like keds are generally expected to correlate positively with density (Cote and Poulin, Reference Cote and Poulin1995; Lloyd-Smith et al., Reference Lloyd-Smith, Cross, Briggs, Daugherty, Getz, Latto, Sanchez, Smith and Swei2005; Albery, Reference Albery2022). Because parasite transmission networks are often spatially structured (Albery et al., Reference Albery, Kirkpatrick, Firth and Bansal2021b), the distribution of environmental factors could influence the way that the sheep interact and transmit keds. For example, sheep may prefer areas with less wind, such that greater wind exposure in lower-density areas drives sheep to more often huddle together or shelter in enclosed spaces. This would lead to higher direct transmission rates per capita in low-density areas, producing the observed density–infection relationship. Additionally, at higher densities individuals may paradoxically decrease their direct contact rates or grouping tendencies (Albon et al., Reference Albon, Staines, Guinness and Clutton-Brock1992); along these lines, this divergence in direct and indirect transmission rates with increasing density agrees with our findings elsewhere, which demonstrated stronger indirect than direct transmission is likely to manifest across a range of wild animal systems (Albery et al., Reference Albery, Becker, Firth, Moor, Ravindran, Silk, Sweeny, Wal, Webber, Allen, Babayan, Barve, Begon, Birtles, Block, Block, Bradley, Budischak, Buesching, Burthe, Carlisle, Caselle, Cattuto, Chaine, Chapple, Cheney, Clutton-Brock, Collier, Curnick, Delahay, Farine, Fenton, Ferretti, Feyrer, Fielding, Foroughirad, Frere, Gardner, Geffen, Godfrey, Graham, Hammond, Henrich, Heurich, Hopwood, Ilany, Jackson, Jackson, Jacoby, Jacoby, Ježek, Kirkpatrick, Klamm, Klarevas-Irby, Knowles, Koren, Krzyszczyk, Kusch, Lambin, Lane, Leirs, Leu, Lyon, MacDonald, Madsen, Mann, Manser, Mariën, Massawe, McDonald, Morelle, Mourier, Newman, Nussear, Nyaguthii, Ogino, Ozella, Packer, Papastamatiou, Paterson, Payne, Pedersen, Pemberton, Pinter-Wollman, Planes, Raulo, Rodríguez-Muñoz, Rudd, Sabuni, Sah, Schallert, Sheldon, Shizuka, Sih, Sinn, Sluydts, Spiegel, Telfer, Thomason, Tickler, Tregenza, VanderWaal, Walmsley, Walters, Wanelik, Whitehead, Wielgus, Wilson-Aggarwal, Wohlfeil and Bansal2025). However, that study showed a saturating positive effect of density on contact in this population specifically, rather than a decrease, so our observation of a negative density–infection trend (rather than a negative one) invites further explanation.

In some scenarios, negative density trends can emerge through encounter-dilution effects, where larger groups subdivide a given burden of mobile parasites – particularly biting insects – such that each individual has fewer parasites (Mooring and Hart, Reference Mooring and Hart1992; Buck et al., Reference Buck, Hechinger, Wood, Stewart, Kuris, Buck, Hechinger, Wood, Stewart, Kuris and Lafferty2017b). This is possible in this case, but given that the keds are not mobile (i.e. without wings) and reside on the sheep themselves, this seems unlikely. Instead, environmental drivers in a given area could drive both lower density and higher ked count. Keds spend much of their lifespan on the skin of the sheep, and they regularly fall off hosts and reside in the environment waiting to encounter another, both of which could leave them relatively exposed to the elements (Small, Reference Small2005); ked transmission is known to be temperature dependent, supporting this explanation (Tetley, Reference Tetley1958). Sheep may even avoid living in areas that support high ked count due to a desire to avoid infection, driving a negative correlation between density and infection (Weinstein et al., Reference Weinstein, Buck and Young2018; Albery et al., Reference Albery, Newman, Bright Ross, Macdonald, Bansal and Buesching2020). Similarly, ked numbers could be brought down in high-density areas by keds’ natural enemies: keds might be eaten by birds (Evans, Reference Evans1950), which may result in lower counts in high-density areas if the birds are more likely to inhabit these areas. The keds are also known to transmit (i.e. to host) Trypanosoma melophagium blood parasites in this population, and keds elsewhere have been known to transmit bluetongue virus (Luedke et al., Reference Luedke, Jochim and Bowne1965) and Bartonella bacteria (Werszko et al., Reference Werszko, Asman, Witecka, Steiner-Bogdaszewska, Szewczyk, Kuryło, Wilamowski and Karbowiak2021). If these parasites exist at higher prevalence in high-density areas, and have a fitness cost for the vectors, which is fairly common (Chomel et al., Reference Chomel, Boulouis, Breitschwerdt, Kasten, Vayssier-Taussat, Birtles, Koehler and Dehio2009; Sisterson, Reference Sisterson2009), they could present a second-degree cost of density for keds; however, highly complex density interactions could arise from this lower intensity of vector infection if they are driven by higher prevalence of their vectored pathogens. Ultimately, future studies of further (internal, rather than ectoparasitic) directly transmitted pathogens, or mapping the distribution of multiple types of between-sheep contacts and their relationships with density, could help to differentiate between these explanations.

Overall, this study provides compelling evidence that relationships between local density and infection can be strongly contrasting between directly and indirectly transmitted parasites and in hosts of different age classes, and that global and local density have distinct effects on infection. Facilitated by more common within-population formulations of such density variables (e.g. Albery et al., Reference Albery, Newman, Bright Ross, Macdonald, Bansal and Buesching2020, Reference Albery, Morris, Morris, Pemberton, Clutton‐Brock, Nussey and Firth2021a, Reference Albery, Morris, Morris, Kenyon, McBean, Pemberton, Nussey and Firth2022c), ecological studies should more often consider that host and parasite biology might introduce strong variation in density–infection relationships, investigating and untangling such contingencies.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0031182025100383.

Data availability

Data and code for the analyses in this manuscript are available on GitHub at https://github.com/gfalbery/SheepDensityInfection.

Acknowledgements

The authors acknowledge the National Trust for Scotland for support of this study on St Kilda, and QinetiQ and Kilda Cruises for logistical support.

Author contributions

G.F.A. conceived the study. J.M.P. and J.G.P. led coordination of fieldwork and data collection on St. Kilda. G.F.A. and A.R.S. analysed data with input from D.H.N., G.F.A. and A.R.S. led writing of the manuscript with input from all authors. All data for this study was collected on St Kilda. The Soay sheep project is highly engaged with the local National Trust of Scotland members stationed on St Kilda for all activities and work carried out on the island and regular provides annual reports and results for the wider public.

Financial support

A.R.S. was supported by a large NERC grant NE/R016801/1. G.F.A. acknowledges funding from NSF DEB-2211287 and WAI (CBR00730). Field data collection has been supported principally by NERC over many years, with some funding from the Wellcome Trust.

Ethical standards

All sampling was carried out in accordance with UK Home Office regulations under Project Licence PP4825594.

Footnotes

†

Shared lead authorship

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Figure 4. Negative density effects on counts of wingless ectoparasites (keds, melophaga ovinus) in A) lambs; B) yearlings; and C) adult sheep. Taken from our density glmms, the dark black line represents the mean of the posterior distribution for the age effect estimate; the light grey lines are 100 random draws from the posterior to represent uncertainty. The density effect estimate, credibility intervals, and p values are given at the top of each panel. The points represent individual samples, with transparency to help visualize overplotting. The y axis represents counts of keds, and has been log10-transformed; 0-counts (which are not possible to display on this logged scale) are displayed at the bottom of the graph.