berghei infection [17]. Thus, it is likely that the decrease in P. berghei infectivity following OXR1 silencing is due to an increase in ROS. The unexpected observation that OXR1 silencing does not affect P. falciparum infection suggests that either this parasite species is less susceptible to oxidative stress or
that the ingestion of human blood results in less accumulation of ROS in the mosquito. GSTs play an important role as antioxidants and are involved in the detoxification of xenobiotics. GSTs of the epsilon and delta class have been extensively find more studied for their role in insecticide resistance in mosquitoes [18]. The GST-Theta1 (GSTT1) null genotype in human males is highly associated to increased risk of basal cell carcinoma of the skin [19]. Furthermore, in diabetics, the deletion of one copy of the GSTT1 gene is associated with elevated markers of inflammation and lipid peroxidation [20]. Therefore, silencing of GSTT1 and GSTT2 could result in increased lipid peroxidation, Eltanexor in vivo which is expected to be deleterious to P. berghei; however, it is not clear why reducing GSTT2 expression enhances P. falciparum infection. Susceptibility of An. stephensi (Nijmegen Sda500
strain) and An. PD0332991 datasheet gambiae (G3) to P. yoelii infection The observed differences in the effect of silencing specific An. gambiae (G3 strain) genes on P. berghei and P. falciparum infection may reflect the degree of compatibility between these two parasite species and the mosquito strain used. Alternatively, mosquitoes may trigger different sets of effector genes in response to different Plasmodium species. To explore these possibilities, we evaluated the responses of two mosquito species that differ in their susceptibility to the same Plasmodium parasite. The susceptibility of An. stephensi (Nijmegen Sda500), a strain highly susceptible to P. falciparum infection [8], and An. gambiae (G3) females to P. yoelii infection was compared by feeding them on
the same infected mouse. An. stephensi is highly susceptible to P. yoelii infection, as no melanized parasites are observed and the median number of live oocysts is 51-fold higher than in An. Oxymatrine gambiae (Figure 3A, C and Table 2). In contrast, An. gambiae (G3) is partially refractory and has two distinct phenotypes (Figure 3B). In approximately half of the mosquitoes, all parasites are melanized, while in the other half, parasite lysis appears to be the main defense response, as no melanizations are observed (Figure 3C, D). Interestingly, the prevalence of mixed phenotypes–that is, mosquitoes in which both live and melanized parasites are observed–is low (10%; Table 2). These results are in agreement with a previous report in which susceptibility of An. gambiae (G3) and An. stephensi (Pakistan) to P. yoelii infection was compared [21]. Figure 3 Susceptibility of An. stephensi (Nijmegen Sda500) and An. gambiae (G3) to P. yoelii infection. An. stephensi and An. gambiae mosquitoes were fed on the same P. yoelii-infected mouse.