Skip to main content

Lund University Publications

LUND UNIVERSITY LIBRARIES

Avian malaria and the overlooked metabolic pathways underlying mosquito -Plasmodium interactions

Garcia-Longoria, Luz LU ; Berthomieu, Arnaud ; Hellgren, O. LU and Rivero, Ana (2025) In Royal Society Open Science 12(10).
Abstract

Avian malaria parasites pose a significant threat to conservation, affecting populations worldwide. Despite this, our understanding of factors influencing the transmission of avian Plasmodium parasites by vectors is limited to the study of mosquito immune responses. However, the complex life cycle of Plasmodium within the vector suggests that non-immune physiological and metabolic pathways may play equally, if not more, crucial roles in determining whether the parasite completes its development and successfully transmits to the next host. We review some of these pathways, uncovering a fragmented and contradictory body of knowledge. Through transcriptomic analysis of infected and uninfected mosquitoes at various stages of infection, we... (More)

Avian malaria parasites pose a significant threat to conservation, affecting populations worldwide. Despite this, our understanding of factors influencing the transmission of avian Plasmodium parasites by vectors is limited to the study of mosquito immune responses. However, the complex life cycle of Plasmodium within the vector suggests that non-immune physiological and metabolic pathways may play equally, if not more, crucial roles in determining whether the parasite completes its development and successfully transmits to the next host. We review some of these pathways, uncovering a fragmented and contradictory body of knowledge. Through transcriptomic analysis of infected and uninfected mosquitoes at various stages of infection, we identify differential expression of numerous metabolic pathways that are essential for Plasmodium development. These include genes involved in meeting the parasite's energetic needs, digestive enzymes facilitating midgut barrier traversal, and salivary enzymes enabling blood meal uptake, among others. This suggests that the parasite has evolved mechanisms to modulate these pathways, thereby enhancing and prolonging infection and transmission. Our findings emphasize the need for a broader, integrative approach to better understand the reciprocal selective pressures between malaria parasites and their vectors and to find novel targets for controlling parasite transmission and ultimately improving malaria control strategies.

(Less)
Please use this url to cite or link to this publication:
author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
avian malaria, Culex quinquefasciatus, Plasmodium relictum, RNA-seq, transcriptomic
in
Royal Society Open Science
volume
12
issue
10
article number
250542
publisher
Royal Society Publishing
external identifiers
  • pmid:41127797
  • scopus:105019400275
ISSN
2054-5703
DOI
10.1098/rsos.250542
language
English
LU publication?
yes
id
e78958e1-f84a-4f1f-8d83-d1cb989fa539
date added to LUP
2025-12-16 13:47:54
date last changed
2025-12-17 03:00:13
@article{e78958e1-f84a-4f1f-8d83-d1cb989fa539,
  abstract     = {{<p>Avian malaria parasites pose a significant threat to conservation, affecting populations worldwide. Despite this, our understanding of factors influencing the transmission of avian Plasmodium parasites by vectors is limited to the study of mosquito immune responses. However, the complex life cycle of Plasmodium within the vector suggests that non-immune physiological and metabolic pathways may play equally, if not more, crucial roles in determining whether the parasite completes its development and successfully transmits to the next host. We review some of these pathways, uncovering a fragmented and contradictory body of knowledge. Through transcriptomic analysis of infected and uninfected mosquitoes at various stages of infection, we identify differential expression of numerous metabolic pathways that are essential for Plasmodium development. These include genes involved in meeting the parasite's energetic needs, digestive enzymes facilitating midgut barrier traversal, and salivary enzymes enabling blood meal uptake, among others. This suggests that the parasite has evolved mechanisms to modulate these pathways, thereby enhancing and prolonging infection and transmission. Our findings emphasize the need for a broader, integrative approach to better understand the reciprocal selective pressures between malaria parasites and their vectors and to find novel targets for controlling parasite transmission and ultimately improving malaria control strategies.</p>}},
  author       = {{Garcia-Longoria, Luz and Berthomieu, Arnaud and Hellgren, O. and Rivero, Ana}},
  issn         = {{2054-5703}},
  keywords     = {{avian malaria; Culex quinquefasciatus; Plasmodium relictum; RNA-seq; transcriptomic}},
  language     = {{eng}},
  number       = {{10}},
  publisher    = {{Royal Society Publishing}},
  series       = {{Royal Society Open Science}},
  title        = {{Avian malaria and the overlooked metabolic pathways underlying mosquito -Plasmodium interactions}},
  url          = {{http://dx.doi.org/10.1098/rsos.250542}},
  doi          = {{10.1098/rsos.250542}},
  volume       = {{12}},
  year         = {{2025}},
}