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Target Concepts:
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Query: UMLS:C0024530 (
malaria
)
44,886
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We surveyed an Anopheles gambiae population in a West African
malaria
transmission zone for naturally occurring genetic loci that control mosquito infection with the human
malaria
parasite, Plasmodium falciparum. The strongest Plasmodium resistance loci cluster in a small region of chromosome 2L and each locus explains at least 89% of parasite-free mosquitoes in independent pedigrees. Together, the clustered loci form a genomic Plasmodium-resistance island that explains most of the genetic variation for
malaria
parasite infection of mosquitoes in nature. Among the candidate genes in this chromosome region, RNA interference knockdown assays confirm a role in Plasmodium resistance for Anopheles Plasmodium-responsive leucine-rich repeat 1 (APL1), encoding a
leucine-rich repeat protein
that is similar to molecules involved in natural pathogen resistance mechanisms in plants and mammals.
...
PMID:Natural malaria infection in Anopheles gambiae is regulated by a single genomic control region. 1664 60
Plasmodium falciparum and Schistosoma mansoni are often found in human coinfections, and cross-reactive antibodies to different components of the two parasites have been detected. In this work, we identified a cross-reactive S. mansoni gene product, referred to as SmLRR, that seems to belong to the
leucine-rich repeat protein
family. Comparative analysis of SmLRR revealed 57% similarity with a putative gene product encoded in the P. falciparum genome. Antibodies to SmLRR were found in experimental infections and in both S. mansoni- and P. falciparum-infected individuals. Correlative analysis of human anti-SmLRR responses in Kenya and Uganda suggested that
malaria
and schistosomiasis drive the immunoglobulin G3 (IgG3) and IgG4 isotypes, respectively, against SmLRR, suggesting that there is differential regulation of cross-reactive isotypes depending on the infection. In addition, the levels of anti-SmLRR IgG4, but not the levels of IgG3, correlated positively with the intensity of S. mansoni infection.
...
PMID:Identification of a novel antigen of Schistosoma mansoni shared with Plasmodium falciparum and evaluation of different cross-reactive antibody subclasses induced by human schistosomiasis and malaria. 1671 63
Plasmodium falciparum lines differ in their ability to infect mosquitoes. The Anopheles gambiae L3-5 refractory (R) line melanizes most Plasmodium species, including the Brazilian P. falciparum 7G8 line, but it is highly susceptible to some African P. falciparum strains such as 3D7, NF54, and GB4. We investigated whether these lines differ in their ability to evade the mosquito immune system. Silencing key components of the mosquito complement-like system [thioester-containing protein 1 (TEP1),
leucine-rich repeat protein
1, and Anopheles Plasmodium-responsive
leucine-rich repeat protein
1] prevented melanization of 7G8 parasites, reverting the refractory phenotype. In contrast, it had no effect on the intensity of infection with NF54, suggesting that this line is able to evade TEP1-mediated lysis. When R females were coinfected with a line that is melanized (7G8) and a line that survives (3D7), the coinfection resulted in mixed infections with both live and encapsulated parasites on individual midguts. This finding shows that survival of individual parasites is parasite-specific and not systemic in nature, because parasites can evade TEP1-mediated lysis even when other parasites are melanized in the same midgut. When females from an extensive genetic cross between R and susceptible A. gambiae (G3) mosquitoes were infected with P. berghei, encapsulation was strongly correlated with the TEP1-R1 allele. However, P. falciparum 7G8 parasites were no longer encapsulated by females from this cross, indicating that the TEP1-R1 allele is not sufficient to melanize this line. Evasion of the A. gambiae immune system by P. falciparum may be the result of parasite adaptation to sympatric mosquito vectors and may be an important factor driving
malaria
transmission.
...
PMID:Some strains of Plasmodium falciparum, a human malaria parasite, evade the complement-like system of Anopheles gambiae mosquitoes. 2262 29
Malaria
parasite ookinetes must traverse the vector mosquito midgut epithelium to transform into sporozoite-producing oocysts. The
Anopheles
innate immune system is a key regulator of this process, thereby determining vector competence and disease transmission. The role of
Anopheles
innate immunity factors as agonists or antagonists of
malaria
parasite infection has been previously determined using specific single
Anopheles
-
Plasmodium
species combinations. Here we show that the two C-type lectins CTL4 and CTLMA2 exert differential agonistic and antagonistic regulation of parasite killing in African and South American
Anopheles
species. The C-type lectins regulate both parasite melanization and lysis through independent mechanisms, and their implication in parasite melanization is dependent on infection intensity rather than mosquito-parasite species combination. We show that the
leucine-rich repeat protein
LRIM1 acts as an antagonist on the development of
Plasmodium
ookinetes and as a regulator of oocyst size and sporozoite production in the South American mosquito
Anopheles albimanus
Our findings explain the rare observation of human
Plasmodium falciparum
melanization and define a key factor mediating the poor vector competence of
Anopheles albimanus
for
Plasmodium berghei
and
Plasmodium falciparum
IMPORTANCE
Malaria
, one of the world's deadliest diseases, is caused by
Plasmodium
parasites that are vectored to humans by the bite of
Anopheles
mosquitoes. The mosquito's innate immune system is actively engaged in suppressing
Plasmodium
infection. Studies on mosquito immunity revealed multiple factors that act as either facilitators or inhibitors of
Plasmodium
infection, but these findings were mostly based on single
Anopheles
-
Plasmodium
species combinations, not taking into account the diversity of mosquito and parasite species. We show that the functions of CTL4 and CTLMA2 have diverged in different vector species and can be both agonistic and antagonistic for
Plasmodium
infection. Their protection against parasite melanization in
Anopheles gambiae
is dependent on infection intensity, rather than the mosquito-parasite combination. Importantly, we describe for the first time how LRIM1 plays an essential role in
Plasmodium
infection of
Anopheles albimanus
, suggesting it is a key regulator of the poor vector competence of this species.
...
PMID:Immune Regulation of
Plasmodium
Is
Anopheles
Species Specific and Infection Intensity Dependent. 2904
The
malaria
development in the mosquito midgut is a complex process that results in considerable parasite losses. The mosquito gut microbiota influences the outcome of pathogen infection in mosquitoes, but the underlying mechanisms through which gut symbiotic bacteria affect vector competence remain elusive. Here, we identified two
Serratia
strains (Y1 and J1) isolated from field-caught female
Anopheles sinensis
from China and assessed their effect on
Plasmodium
development in
An. stephensi
. Colonization of
An. stephensi
midgut by
Serratia
Y1 significantly renders the mosquito resistant to
Plasmodium berghei
infection, while
Serratia
J1 has no impact on parasite development. Parasite inhibition by
Serratia
Y1 is induced by the activation of the mosquito immune system. Genome-wide transcriptomic analysis by RNA-seq shows a similar pattern of midgut gene expression in response to
Serratia
Y1 and J1 in sugar-fed mosquitoes. However, 24 h after blood ingestion
, Serratia
Y1 modulates more midgut genes than
Serratia
J1 including the c-type lectins (CTLs), CLIP serine proteases and other immune effectors. Furthermore, silencing of several
Serratia
Y1-induced anti-
Plasmodium
factors like the thioester-containing protein 1 (TEP1), fibrinogen immunolectin 9 (FBN9) or
leucine-rich repeat protein
LRRD7 can rescue parasite oocyst development in the presence of
Serratia
Y1, suggesting that these factors modulate the
Serratia
Y1-mediated anti-
Plasmodium
effect. This study enhances our understanding of how gut bacteria influence mosquito-
Plasmodium
interactions.
...
PMID:A Gut Symbiotic Bacterium
Serratia marcescens
Renders Mosquito Resistance to
Plasmodium
Infection Through Activation of Mosquito Immune Responses. 3137 68
