Structure-Function Analysis of the Anopheles gambiae LRIM1/APL1C Complex and its Interaction with Complement C3-Like Protein TEP1

Povelones, Michael; Upton, Leanna M.; Sala, Katarzyna; Christophides, George K.

doi:10.1371/journal.ppat.1002023

Cited by 79 publications

(114 citation statements)

References 36 publications

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“…These interactions and the activity of chitinase, coupled with the digestive activity of plasmin on the ookinete surface (39), may result in a disruption of the PM structure, ultimately facilitating parasite invasion. After ookinetes cross the PM to invade midgut epithelial cells other proteins in mosquito hemolymph may perhaps interact with parasites and impact infection intensity (40,41). By extension, our model predicts that blocking FREP1 activity or interaction with Plasmodium parasites will significantly reduce the capacity for mosquitoes to transmit malaria.…”

Section: Discussionmentioning

confidence: 82%

Anopheles Midgut FREP1 Mediates Plasmodium Invasion

Zhang

Niu

Franca

et al. 2015

Journal of Biological Chemistry

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Background: The molecular mechanisms of Plasmodium invasion in mosquito midguts are not well understood. Results: The mosquito midgut peritrophic matrix protein FREP1 binds Plasmodia. Blocking parasite-FREP1 interactions or ablating FREP1 expression reduced P. falciparum infection in mosquitoes. Conclusion: FREP1 functions as a critical host factor that mediates Plasmodium invasion in mosquito midguts. Significance: Targeting FREP1 may inhibit Plasmodium transmission to mosquitoes and the spread of malaria.

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Section: Discussionmentioning

confidence: 82%

Anopheles Midgut FREP1 Mediates Plasmodium Invasion

Zhang

Niu

Franca

et al. 2015

Journal of Biological Chemistry

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“…We show that the LRR proteins APL1A and APL1C play a role in midgut antiviral defense against virus infection. The role of these molecules as protective factors against Plasmodium infection is well documented (34,36,(53)(54)(55). APL1C is a subunit, along with LRIM1 and Tep1, in a ternary immune complex with activity against rodent malaria parasites (34,35,56), whereas its paralog APL1A, but not APL1C, protects against P. falciparum infection (36).…”

Section: Discussionmentioning

confidence: 99%

Antiviral immunity of Anopheles gambiae is highly compartmentalized, with distinct roles for RNA interference and gut microbiota

Carissimo

Pondeville

McFarlane

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

142

178

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Arboviruses are transmitted by mosquitoes and other arthropods to humans and animals. The risk associated with these viruses is increasing worldwide, including new emergence in Europe and the Americas. Anopheline mosquitoes are vectors of human malaria but are believed to transmit one known arbovirus, o’nyong-nyong virus, whereas Aedes mosquitoes transmit many. Anopheles interactions with viruses have been little studied, and the initial antiviral response in the midgut has not been examined. Here, we determine the antiviral immune pathways of the Anopheles gambiae midgut, the initial site of viral infection after an infective blood meal. We compare them with the responses of the post-midgut systemic compartment, which is the site of the subsequent disseminated viral infection. Normal viral infection of the midgut requires bacterial flora and is inhibited by the activities of immune deficiency (Imd), JAK/STAT, and Leu-rich repeat immune factors. We show that the exogenous siRNA pathway, thought of as the canonical mosquito antiviral pathway, plays no detectable role in antiviral defense in the midgut but only protects later in the systemic compartment. These results alter the prevailing antiviral paradigm by describing distinct protective mechanisms in different body compartments and infection stages. Importantly, the presence of the midgut bacterial flora is required for full viral infectivity to Anopheles, in contrast to malaria infection, where the presence of the midgut bacterial flora is required for protection against infection. Thus, the enteric flora controls a reciprocal protection tradeoff in the vector for resistance to different human pathogens.

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“…Expression of three TEP genes (TEP1, TEP3, and TEP12) was significantly up-regulated by wounding. TEP1 and TEP3 cooperate to TGase2-mediated Killing of P. falciparum in A. gambiae promote phagocytosis of Gram-positive and Gram-negative bacteria (50) and in antiparasitic responses (51,52). TEP1 circulates in the mosquito hemolymph as a trimeric complex comprising two leucine-rich repeat proteins, APL1C and LRIM1 (53,54).…”

Section: Identification Of Wound Response Genes By Genome-widementioning

confidence: 99%

AP-1/Fos-TGase2 Axis Mediates Wounding-induced Plasmodium falciparum Killing in Anopheles gambiae

Nsango

Pompon

Xie

et al. 2013

Journal of Biological Chemistry

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Background: Wounding renders mosquitoes resistant to human malaria parasites. Results: Genome-wide transcriptional profiling identified 53 wound response genes, including two transglutaminases. Functional studies revealed the role of AP-1/TGase2 axis in the mosquito resistance to Plasmodium falciparum. Conclusion: AP-1/TGase2 is a new axis of the mosquito immune responses to malaria parasites. Significance: Multiple signaling pathways contribute to mosquito resistance to malaria and represent new potential targets for vector control interventions.

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Structure-Function Analysis of the Anopheles gambiae LRIM1/APL1C Complex and its Interaction with Complement C3-Like Protein TEP1

Cited by 79 publications

References 36 publications

Anopheles Midgut FREP1 Mediates Plasmodium Invasion

Anopheles Midgut FREP1 Mediates Plasmodium Invasion

Antiviral immunity of Anopheles gambiae is highly compartmentalized, with distinct roles for RNA interference and gut microbiota

AP-1/Fos-TGase2 Axis Mediates Wounding-induced Plasmodium falciparum Killing in Anopheles gambiae

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