Your search keyword '"Kayla C. King"' showing total 4 results

1. Genome dynamics across the evolutionary transition to endosymbiosis

Author

Stefanos Siozios, Pol Nadal Jimenez, Tal Azagi, Hein Sprong, Crystal L Frost, Steven R Parratt, Graeme Taylor, Laura Brettell, Kwee Chin Liew, Larry Croft, Kayla C King, Michael A Brockhurst, Václav Hypša, Eva Novakova, Alistair C Darby, and Gregory DD Hurst

Abstract

SummaryEndosymbiosis – where a microbe lives and replicates within a host – is an important contributor to organismal function that has accelerated evolutionary innovations and catalysed the evolution of complex life. The evolutionary processes associated with transitions to endosymbiosis, however, are poorly understood. Here, we use comparative genomics of the genusArsenophonusto reveal the complex processes that occur on evolution of an endosymbiotic lifestyle. We compared the genomes of 38 strains spanning diverse lifestyles from environmentally acquired infections to obligate inter-dependent endosymbionts. We observed recent endosymbionts had larger genome sizes than closely related environmentally acquired strains, consistent with evolutionary innovation and rapid gain of new function. Increased genome size was a consequence of prophage and plasmid acquisition including a cargo of type III effectors, and concomitant loss of CRISPR-Cas genome defence systems enabling mobile genetic element expansion. Persistent endosymbiosis was also associated with loss of type VI secretion, likely reflecting reduced microbe-microbe competition. Thereafter, the transition to stable endosymbiosis and vertical inheritance was associated with the expected relaxation of purifying selection, pseudogenisation of genes and reduction of metabolism, leading to genome reduction. However, reduced %GC that is typically considered a progressive linear process was observed only in obligate interdependent endosymbionts. We argue that a combination of the need for rapid horizontal gene transfer-mediated evolutionary innovation together with reduced phage predation in endosymbiotic niches drives loss of genome defence systems and rapid genome expansion upon adoption of endosymbiosis. These remodelling processes precede the reductive evolution traditionally associated with adaptation to endosymbiosis.

Published

2023

2. Interactions between insect vectors and plant pathogens span the parasitism-mutualism continuum

Author

Ma. Francesca M. Santiago, Kayla C. King, and Georgia C. Drew

Abstract

Plants infected with vector-borne pathogens can suffer severe negative consequences, but the extent to which phytopathogens affect the fitness of their vector hosts remains unclear. Evolutionary theory predicts that selection on vector-borne pathogens should favour low virulence or mutualistic phenotypes in the vector, traits facilitating effective transmission between plant hosts. Here, we use a multivariate meta-analytic approach on 115 effect sizes across 34 unique plant-vector-pathogen systems to quantify the overall effect of phytopathogens on vector host fitness. In support of theoretical models, we report that phytopathogens overall have a neutral fitness effect on vector hosts. However, the range of possible fitness outcomes are diverse and span the parasitism-mutualism continuum. Contrary to previous predictions we found no evidence that transmission strategy, or the direct effects and indirect (plant-mediated) effects, of phytopathogens have divergent fitness outcomes for the vector. We discuss these findings in the context of plant – pathogen – vector ecology.

Published

2022

3. Protective microbe enhances colonisation of a novel host species by modifying immune gene expression

Author

Suzanne A. Ford and Kayla C. King

Subjects

0303 health sciences, biology, 030306 microbiology, Host (biology), biology.organism_classification, Microbiology, Transcriptome, Colonisation, 03 medical and health sciences, Immune system, Gene, Pathogen, Caenorhabditis elegans, Bacteria, 030304 developmental biology

Abstract

Microbes that protect against infection inhabit hosts across the tree of life. It is unclear whether many protective microbes use or reduce the need for a host immune response, or how the immune system reacts when these microbes newly encounter a host species naturally and as part of a biocontrol strategy. We sequenced the transcriptome of a host (Caenorhabditis elegans) following its interaction with a non-native bacterium (Enterococcus faecalis) that has protective traits against the pathogen, Staphylococcus aureus. We show that microbe-mediated protection caused the differential expression of 1,557 genes, including the upregulation of many immune gene families conserved across the animal kingdom (e.g. lysozymes and c-type lectins). We found that this modulation of the host’s immune response was beneficial for both the protective microbe and the host. Given E. faecalis’ increased ability to resist lysozyme activity compared to S. aureus, our results indicate that the protective microbe could more easily invade and protect infected hosts by upregulating lysozyme genes. These results suggest that a protective microbe can exploit the host immune system even when introduced into a novel species. Microbes that protect via the host immune response in this way should favour continued investment into host immunity and avoid the evolution of host dependence.Author summaryOrganisms can be protected from infectious disease by the microbes they house. It is unclear, however, whether protective microbes affect the host immune response to infection, particularly in the early stages of symbiosis. In this study, we investigated the role of the host immune system in a novel protective interaction. We examined gene expression in a nematode after colonisation by a non-native microbe capable of suppressing the pathogen Staphylococcus aureus. The protective microbe altered the host immune response to infection in a way that it could exploit. By causing the host to increase the production of antimicrobials to which it itself is relatively resistant, the protective microbe was better able to colonise and defend infected hosts. These results indicate that protective microbes introduced into new host species can take advantage of the host immune system. Such a mechanism at the beginning of a protective symbiosis, formed either naturally or as part of a biocontrol strategy, could ensure continued investment in host-based defences over evolutionary time.

Published

2019

4. Diversity and disease: evidence for the monoculture effect beyond agricultural systems

Author

Charlotte Rafaluk-Mohr, Kayla C. King, and Alice K. E. Ekroth

Subjects

0106 biological sciences, 2. Zero hunger, 0303 health sciences, Genetic diversity, Ecology, Host (biology), business.industry, Outbreak, Virulence, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Infectious disease (medical specialty), Agriculture, Parasite hosting, Monoculture, business, human activities, 030304 developmental biology

Abstract

Human activities are greatly reducing the genetic diversity of species worldwide. Given the prediction that parasites better exploit less diverse host populations, many species could be vulnerable to disease outbreaks. However, the widespread nature of the ‘monoculture effect’ remains unclear outside agricultural systems. We conducted a meta-analysis of 22 studies, obtaining a total of 66 effect sizes, to directly test the biological conditions under which host genetic diversity limits infectious disease in populations. Overall, we found broad support for the monoculture effect across host and parasite species. The effect was independent of host range, host reproduction, parasite diversity, and the method by which the monoculture effect was recorded. Conversely, we found that parasite functional group, virulence, and empirical environment matters. Together, these results highlight the general susceptibility of genetically homogenous populations to infection. Consequently, this phenomenon could become increasingly common and alarming for at-risk populations due to human-driven declines in genetic diversity and shifts in parasite distributions.

Published

2019