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Increasing evidence for rapid evolution suggests that the maintenance of species diversity in ecological communities may be influenced by more than purely ecological processes. Classic theory shows that interspecific competition may select for traits that increase niche differentiation, weakening competition and thus promoting species coexistence. While empirical work has demonstrated trait evolution in response to competition, if and how evolution affects the dynamics of the competing species—the key step for completing the required eco-evolutionary feedback—has been difficult to resolve. Here, we show that evolution in response to interspecific competition feeds back to change the course of competitive population dynamics of aquatic plant species over 10–15 generations in the field. By manipulating selection imposed by heterospecific competitors in experimental ponds, we demonstrate that (i) interspecific competition drives rapid genotypic change, and (ii) this evolutionary change in one competitor, while not changing the coexistence outcome, causes the population trajectories of the two competing species to converge. In contrast to the common expectation that interspecific competition should drive the evolution of niche differentiation, our results suggest that genotypic evolution resulted in phenotypic changes that altered population dynamics by affecting the competitive hierarchy. This result is consistent with theory suggesting that competition for essential resources can limit opportunities for the evolution of niche differentiation. Our finding that rapid evolution regulates the dynamics of competing species suggests that ecosystems may rely on continuous feedbacks between ecology and evolution to maintain species diversity.

For millennia, humans have imposed strong selection on domesticated crops, resulting in drastically altered crop phenotypes compared with wild ancestors. Crop yields have increased, but a long-held hypothesis is that domestication has also unintentionally decreased plant defences against herbivores. To test this hypothesis, we conducted a phylogenetically controlled meta-analysis comparing insect herbivore resistance and putative plant defence traits between crops and their wild relatives. Our database included 2098 comparisons made across 73 crops in 89 studies. We found that domestication consistently reduced plant resistance to herbivores, although the magnitude of the effects varied across plant organs and depended on how resistance was measured. However, domestication had no consistent effects on the specific plant defence traits underlying resistance, including secondary metabolites and physical feeding barriers. The values of these traits sometimes increased and sometimes decreased during domestication. Consistent negative effects of domestication were observed only when defence traits were measured in reproductive organs or in the plant organ that was harvested. These results highlight the complexity of evolution under domestication and the need for an improved theoretical understanding of the mechanisms through which agronomic selection can influence the species interactions that impact both the yield and sustainability of our food systems. This article is part of the themed issue ‘Human influences on evolution, and the ecological and societal consequences’.

Cats represent a potential source of Coxiella burnetii, the aetiological agent of Q fever in humans. The prevalence and risk factors of C. burnetii infection in farm, pet and feral cats were studied in Quebec, Canada, using a cross-sectional study. Serum samples were tested using a specific enzyme-linked immunosorbent assay (ELISA) for the presence of antibodies against C. burnetii, whereas rectal swabs were assayed using real-time quantitative polymerase chain reaction (qPCR) for the molecular detection of the bacteria. Potential risk factors for farm cats were investigated using clinical examinations, questionnaires and results from a concurrent study on C. burnetii farm status. A total of 184 cats were tested: 59 from ruminant farms, 73 pets and 52 feral cats. Among farm cats, 2/59 (3.4%) were ELISA-positive, 3/59 (5.1%) were ELISA-doubtful and 1/59 (1.7%) was qPCR-positive. All pets and feral cats were negative to C. burnetii ELISA and qPCR. Farm cat positivity was associated with a positive C. burnetii status on the ruminant farm (prevalence ratio = 7.6, P = 0.03). Our results suggest that although pet and feral cats do not seem to pose a great C. burnetii risk to public health, more active care should be taken when in contact with cats from ruminant farms.

The consumption of plants by animals underlies important evolutionary and ecological processes in nature. Arthropod herbivory evolved approximately 415 Ma and the ensuing coevolution between plants and herbivores is credited with generating much of the macroscopic diversity on the Earth. In contemporary ecosystems, herbivory provides the major conduit of energy from primary producers to consumers. Here, we show that when averaged across all major lineages of vascular plants, herbivores consume 5.3% of the leaf tissue produced annually by plants, whereas previous estimates are up to 3.8× higher. This result suggests that for many plant species, leaf herbivory may play a smaller role in energy and nutrient flow than currently thought. Comparative analyses of a diverse global sample of 1058 species across 2085 populations reveal that models of stabilizing selection best describe rates of leaf consumption, and that rates vary substantially within and among major plant lineages. A key determinant of this variation is plant growth form, where woody plant species experience 64% higher leaf herbivory than non-woody plants. Higher leaf herbivory in woody species supports a key prediction of the plant apparency theory. Our study provides insight into how a long history of coevolution has shaped the ecological and evolutionary relationships between plants and herbivores.

Numerous management methods are deployed to try to mitigate the destructive impact of weedy and invasive populations. Yet, such management practices may cause these populations to inadvertently evolve in ways that have consequence on their invasiveness. To test this idea, we conducted a two‐step field mesocosm experiment; we evolved genetically diverse populations of the duckweed Lemna minor to targeted removal management and then tested the impact of that evolution in replicated invasions into experimental resident communities. We found that evolution in response to management increased invasiveness compared to populations evolved without management. This evolution in response to management had little effect on the impact of the invader on the resident species. These results illustrate the potential eco‐evolutionary consequences of management practices. Mitigating evolution to physical removal, in addition to pesticides, may be important to the long‐term success of integrated pest management.

Survivors of childhood cancer are at risk of subsequent neoplasms (SNs) associated with exposure to radiotherapy and chemotherapy, as well as with genetic predisposition. We aimed to estimate the relative contributions of these risk factors to the total SN burden in survivor populations. We analysed data from two retrospectively constructed cohorts with ongoing recruitment and prospective follow-up: the St Jude Lifetime Cohort (SJLIFE; 4401 participants; NCT00760656) and the Childhood Cancer Survivor Study (CCSS; 7943 participants; NCT01120353). We used multivariable piecewise-exponential models to calculate attributable fractions to assess the contributions of radiotherapy and chemotherapy exposures, genetic predisposition (comparing the top two tertiles with the lowest tertile of polygenic risk scores [PRSs] where the tertile is from external general population corresponding to SN outcome) and lifestyle factors (physical activity, smoking, alcohol consumption, obesity, and diet) to incident of the first occurrences of SNs as the primary outcome. The study was conducted between Jan 1, 2024, and Sept 30, 2024. Of the 12 344 survivors eligible for analysis, median attained age was 33·0 years (IQR 24·1–42·1) in SJLIFE and 36·0 years (29·5–43·6) in CCSS; 6127 (49·6%) were men and 6217 (50·4%) were women. Most patients were White (10 907 [88·4%]). The median follow-up from primary cancer diagnosis was 24·2 years (IQR 11·7–35·4) in SJLIFE (from Sept 13, 2007 to April 20, 2020) and 28·0 years (8·9–37·2) in CCSS (from Jan 1, 1975 to Dec 31, 2023). Cancer treatments and genetic risk jointly contributed to a substantial proportion of incident SN cases with attributable fractions ranging from 30% (95% CI 6–49; sarcoma) to 92% (89–94; meningioma). Higher exposure levels of radiotherapy contributed most, particularly in older (≥35 years; SJLIFE proportion of SNs 44·7% [95% CI 41·9–47·5]) compared with younger (<35 years; 40·0% [37·1–43·3]) follow-up age periods. Elevated genetic risk based on the PRSs accounted for a notable proportion, ranging from 1% (95% CI 0–7; meningioma) to 52% (39–62; thyroid cancer), surpassing contributions of chemotherapies, ranging from 3% (1–6; SMNs) to 35% (19–49; sarcoma). Lifestyle factors contributed negligibly. Cancer treatments and genetic predisposition are primary contributors to the risk of SNs in childhood cancer survivors, and lifestyle factors seem to have a minimal effect. These results highlight the crucial need to consider both treatment history and genetic factors in developing effective risk assessment and surveillance strategies for this vulnerable population. US National Institutes of Health and the American Lebanese Syrian Associated Charities.

Telomere length is associated with risk for thyroid subsequent malignant neoplasm in survivors of childhood cancer. Here, we investigated associations between thyroid subsequent malignant neoplasm and inherited variation in telomere maintenance genes. We used RegulomeDB to annotate the functional impact of variants mapping to 14 telomere maintenance genes among 5,066 five-or-more year survivors who participate in the Childhood Cancer Survivor Study (CCSS) and who are longitudinally followed for incidence of subsequent cancers. Hazard ratios for thyroid subsequent malignant neoplasm were calculated for 60 putatively functional variants with minor allele frequency ≥1% in or near telomere maintenance genes. Functional impact was further assessed by measuring telomere length in leukocyte subsets. The minor allele at Protection of Telomeres-1 (POT1) rs58722976 was associated with increased risk for thyroid subsequent malignant neoplasm (adjusted HR = 6.1, 95% CI: 2.4, 15.5, P = 0.0001; Fisher's exact P = 0.001). This imputed SNP was present in three out of 110 survivors who developed thyroid cancer vs. 14 out of 4,956 survivors who did not develop thyroid cancer. In a subset of 83 survivors with leukocyte telomere length data available, this variant was associated with longer telomeres in B lymphocytes (P = 0.004). Using a functional variant approach, we identified and confirmed an association between a low frequency intronic regulatory POT1 variant and thyroid subsequent malignant neoplasm in survivors of childhood cancer. These results suggest that intronic variation in POT1 may affect key protein binding interactions that impact telomere maintenance and genomic integrity.

As natural disasters become more frequent due to climate change, understanding the biological impact of these ecological catastrophes on wild populations becomes increasingly pertinent. Fluctuating asymmetry (FA), or random deviations from bilateral symmetry, is reflective of developmental instability and has long been positively associated with increases in environmental stress. This study investigates craniofacial FA in a population of free‐ranging rhesus macaques (Macaca mulatta) that has experienced multiple Category 3 hurricanes since the colony's inception on Cayo Santiago, including 275 individuals from ages 9 months to 31 years (F = 154; M = 121). Using geometric morphometrics to quantify FA and a linear mixed‐effect model for analysis, we found that sex, age, and decade of birth did not influence the amount of FA in the individuals included in the study, but the developmental stage at which individuals experienced these catastrophic events greatly impacted the amount of FA exhibited (p = .001). Individuals that experienced these hurricanes during fetal life exhibited greater FA than any other post‐natal developmental period. These results indicate that natural disasters can be associated with developmental disruption that results in long‐term effects if occurring during the prenatal period, possibly due to increases in maternal stress‐related hormones. Resumen A medida que los desastres naturales se vuelven más frecuentes debido al cambio climático, entender el impacto biológico de estas catástrofes ecológicas en poblaciones silvestres va en aumento pertinente. La asimetría fluctuante (AF), o desviaciones aleatorias de simetría bilateral, es reflejo de inestabilidad durante el desarrollo y se ha asociado positivamente con incrementos en estrés ambiental durante mucho tiempo. Este estudio investiga AF craneofacial en una población de macacos rhesus (Macaca mulatta) en libertad que ha experimentado múltiples huracanes categoría 3 desde el inicio de la colonia en Cayo Santiago, e incluye 275 individuos de 9 meses a 31 años de edad (F = 154; M = 121). Usando morfometría geométrica para cuantificar AF y un modelo lineal de efectos mixtos para análisis, encontramos que el sexo, la edad y la década de nacimiento no influyeron en la cantidad de AF en los individuos incluidos en el estudio, pero la etapa de desarrollo en la que los individuos experimentaron estos eventos catastróficos impactó altamente la cantidad de AF exhibida (p = .001). Los individuos que experimentaron estos huracanes durante el período fetal exhibieron mayor AF que cualquier otro período de desarrollo posnatal. Estos resultados indican que los desastres naturales pueden asociarse con trastornos del desarrollo que tienen efectos a largo plazo si ocurren durante el período prenatal, posiblemente debido al aumento de hormonas maternas relacionadas con el estrés. Fluctuating asymmetry (FA), or random deviations from symmetry, can be used as a proxy for developmental instability, and anthropogenic and natural disruptions have been associated with increased levels of FA. In this study, we investigate the effect of demographic variables (age, sex, and decade of birth) and hurricane experience on FA in a model primate taxon: rhesus macaques (Macaca mulatta) to better understand the impact major ecological catastrophes have on skeletal development. Individuals that experienced a hurricane event in utero exhibited higher levels of FA than juvenile or adult individuals that experienced that same event, which could be due to increased maternal stress hormones such as glucocorticoids that can disrupt fetal development.

The domestication of crops is among the most important innovations in human history. Here, we test the hypothesis that cultivation and artificial selection for increased productivity of crops reduced plant defenses against herbivores. We compared the performance of two economically important generalist herbivores – the leaf‐chewing beet armyworm (Spodoptera exigua) and the phloem‐feeding green peach aphid (Myzus persicae) – across 29 crop species and their closely related wild relatives. We also measured putative morphological and chemical defensive traits and correlated them with herbivore performance. We show that, on average, domestication significantly reduced resistance to S. exigua, but not M. persicae, and that most independent domestication events did not cause differences in resistance to either herbivore. In addition, we found that multiple plant traits predicted resistance to S. exigua and M. persicae, and that domestication frequently altered the strength and direction of correlations between these traits and herbivore performance. Our results show that domestication can alter plant defenses, but does not cause strong allocation tradeoffs as predicted by plant defense theory. These results have important implications for understanding the evolutionary ecology of species interactions and for the search for potential resistance traits to be targeted in crop breeding.

Understanding how natural selection drives evolution is a key challenge in evolutionary biology. Most studies of adaptation focus on how a single environmental factor, such as increased temperature, affects evolution within a single species. The biological relevance of these experiments is limited because nature is infinitely more complex. Most species are embedded within communities containing many species that interact with one another and the physical environment. To understand the evolutionary significance of such ecological complexity, experiments must test the evolutionary impact of interactions among multiple species during adaptation. Here we highlight an experiment that manipulates species composition and tracks evolutionary responses within each species, while testing for the mechanisms by which species interact and adapt to their environment. We also discuss limitations of previous studies of adaptive evolution and emphasize how an experimental evolution approach can circumvent such shortcomings. Understanding how community composition acts as a selective force will improve our ability to predict how species adapt to natural and human-induced environmental change.