TY - JOUR
T1 - Closing the gap in the Janzen–Connell hypothesis
T2 - What determines pathogen diversity?
AU - Bruijning, Marjolein
AU - Metcalf, C. Jessica E.
AU - Visser, Marco D.
N1 - Publisher Copyright: © 2023 The Authors. Ecology Letters published by John Wiley & Sons Ltd.
PY - 2024/1
Y1 - 2024/1
N2 - The high tree diversity in tropical forests has long been a puzzle to ecologists. In the 1970s, Janzen and Connell proposed that tree species (hosts) coexist due to the stabilizing actions of specialized enemies. This Janzen–Connell hypothesis was subsequently supported by theoretical studies. Yet, such studies have taken the presence of specialized pathogens for granted, overlooking that pathogen coexistence also requires an explanation. Moreover, stable ecological coexistence does not necessarily imply evolutionary stability. What are the conditions that allow Janzen–Connell effects to evolve? We link theory from community ecology, evolutionary biology and epidemiology to tackle this question, structuring our approach around five theoretical frameworks. Phenomenological Lotka–Volterra competition models provide the most basic framework, which can be restructured to include (single- or multi-)pathogen dynamics. This ecological foundation can be extended to include pathogen evolution. Hosts, of course, may also evolve, and we introduce a coevolutionary model, showing that host–pathogen coevolution can lead to highly diverse systems. Our work unpacks the assumptions underpinning Janzen–Connell and places theoretical bounds on pathogen and host ecology and evolution. The five theoretical frameworks taken together provide a stronger theoretical basis for Janzen–Connell, delivering a wider lens that can yield important insights into the maintenance of diversity in these increasingly threatened systems.
AB - The high tree diversity in tropical forests has long been a puzzle to ecologists. In the 1970s, Janzen and Connell proposed that tree species (hosts) coexist due to the stabilizing actions of specialized enemies. This Janzen–Connell hypothesis was subsequently supported by theoretical studies. Yet, such studies have taken the presence of specialized pathogens for granted, overlooking that pathogen coexistence also requires an explanation. Moreover, stable ecological coexistence does not necessarily imply evolutionary stability. What are the conditions that allow Janzen–Connell effects to evolve? We link theory from community ecology, evolutionary biology and epidemiology to tackle this question, structuring our approach around five theoretical frameworks. Phenomenological Lotka–Volterra competition models provide the most basic framework, which can be restructured to include (single- or multi-)pathogen dynamics. This ecological foundation can be extended to include pathogen evolution. Hosts, of course, may also evolve, and we introduce a coevolutionary model, showing that host–pathogen coevolution can lead to highly diverse systems. Our work unpacks the assumptions underpinning Janzen–Connell and places theoretical bounds on pathogen and host ecology and evolution. The five theoretical frameworks taken together provide a stronger theoretical basis for Janzen–Connell, delivering a wider lens that can yield important insights into the maintenance of diversity in these increasingly threatened systems.
KW - Janzen–Connell hypothesis
KW - SIS model
KW - adaptive dynamics
KW - host–parasite coevolution
KW - modern coexistence theory
UR - http://www.scopus.com/inward/record.url?scp=85173495483&partnerID=8YFLogxK
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U2 - 10.1111/ele.14316
DO - 10.1111/ele.14316
M3 - Article
C2 - 37787147
SN - 1461-023X
VL - 27
JO - Ecology letters
JF - Ecology letters
IS - 1
M1 - e14316
ER -