Biomphalaria snails are instrumental in transmission of the human blood fluke Schistosoma mansoni. With the World Health Organization's goal to eliminate schistosomiasis as a global health problem by 2025, there is now renewed emphasis on snail control. Here, we characterize the genome of Biomphalaria glabrata, a lophotrochozoan protostome, and provide timely and important information on snail biology. We describe aspects of phero-perception, stress responses, immune function and regulation of gene expression that support the persistence of B. glabrata in the field and may define this species as a suitable snail host for S. mansoni. We identify several potential targets for developing novel control measures aimed at reducing snail-mediated transmission of schistosomiasis.
Despite evidence that γδ T cells play an important role during malaria, their precise role remains unclear. During murine malaria induced by Plasmodium chabaudi infection and in human P. falciparum infection, we found that γδ T cells expanded rapidly after resolution of acute parasitemia, in contrast to αβ T cells that expanded at the acute stage and then declined. Single-cell sequencing showed that TRAV15N-1 (Vδ6.3) γδ T cells were clonally expanded in mice and had convergent complementarity-determining region 3 sequences. These γδ T cells expressed specific cytokines, M-CSF, CCL5, CCL3, which are known to act on myeloid cells, indicating that this γδ T cell subset might have distinct functions. Both γδ T cells and M-CSF were necessary for preventing parasitemic recurrence. These findings point to an M-CSF-producing γδ T cell subset that fulfills a specialized protective role in the later stage of malaria infection when αβ T cells have declined.
Malaria, the disease caused byPlasmodiumspp. infection, remains a major global cause of morbidity and mortality. Host protection from malaria relies on immune-driven resistance mechanisms that killPlasmodium. However, these mechanisms are not sufficient per se to avoid the development of severe forms of disease. This is accomplished instead via the establishment of disease tolerance to malaria, a defense strategy that does not targetPlasmodiumdirectly. Here we demonstrate that the establishment of disease tolerance to malaria relies on a tissue damage-control mechanism that operates specifically in renal proximal tubule epithelial cells (RPTEC). This protective response relies on the induction of heme oxygenase-1 (HMOX1; HO-1) and ferritin H chain (FTH) via a mechanism that involves the transcription-factor nuclear-factor E2-related factor-2 (NRF2). As it accumulates in plasma and urine during the blood stage ofPlasmodiuminfection, labile heme is detoxified in RPTEC by HO-1 and FTH, preventing the development of acute kidney injury, a clinical hallmark of severe malaria.
Cardiac specification models are widely utilized to provide insight into the expression and function of homologous genes and structures in humans. In Drosophila, contractions of the alary muscles control hemolymph inflow and support the cardiac tube, however embryonic development of these muscles remain largely understudied. We found that alary muscles in Drosophila embryos appear as segmental pairs, attaching dorsally at the seven-up (svp) expressing pericardial cells along the cardiac dorsal vessel, and laterally to the body wall. Normal patterning of alary muscles along the dorsal vessel was found to be a function of the Bithorax Complex genes abdominal-A (abd-A) and Ultrabithorax (Ubx) but not of the orphan nuclear receptor gene svp. Ectopic expression of either abd-A or Ubx resulted in an increase in the number of alary muscle pairs from seven to ten, and also produced a general elongation of the dorsal vessel. A single knockout of Ubx resulted in a reduced number of alary muscles, and double knockouts of both Ubx and abd-A prevented alary muscles from developing normally and from attaching to the dorsal vessel. These studies demonstrate an additional facet of muscle development that depends upon the Hox genes, and define for the first time mechanisms that impact development of this important subset of muscles.
Cell surface heparan sulfate (HS) is an important co-receptor for many cytokines, chemokines, and growth factors. Here we report that splenic murine B cells express very little HS, and that upon infection with either gammaherpesvirus (MHV68) or betaherpesvirus (MCMV), HS is rapidly upregulated at the surface of B cells. HS upregulation was not observed in mice deficient for the type-I IFN (IFN-I) receptor. Additionally, treatment of wild-type mice with the IFN-I inducer polyinosine polycytidylic acid (poly I:C) triggered HS expression at the B cell surface. Similarly, incubation of purified splenic B cells with IFN-I, TLR ligands, or B cell receptor stimulators ex vivo resulted in a drastic increase in HS surface expression. We found that IFN-I induced an increase in the surface expression of HS-modified syndecan 4 as well as that of an unidentified HSPG. Finally, IFN-I treatment increased B cell responsiveness to APRIL, a cytokine involved in B cell survival and T cell-independent B cell responses. Enzymatic removal of HS from IFN-I treated B cells inhibited APRIL signaling. Altogether, our results indicate that upon herpesvirus infection in mice, HS is rapidly upregulated at the surface of B cells due to the action of IFN-I, potentially increasing B cell responsiveness to cytokines. Induction of HS expression at the B cell surface by stimulators of the innate immune response is likely playing a key role in the development of a robust immune response.
The original version of this Article contained an error in the spelling of the author Leon Di Stefano, which was incorrectly given as Leon di Stephano. This has now been corrected in both the PDF and HTML versions of the Article.
In 2016, there were 216 million malaria cases – 445,000 of which resulted in deaths. Despite overwhelming evidence that γδ T cells strongly respond during malaria infection and vaccination, their functional and phenotypic characteristics remain the least understood facets of the adaptive immune response. Therefore, we studied the role of these cells in human and mouse malaria. In both Plasmodium falciparum-infected subjects and in P. chabaudi-infected mice, we found γδ T cells expanding rapidly after resolution of acute parasitemia, in contrast to αβ T cells that expanded at the acute stage and then declined. Silencing the murine γδ T cells led to recurrent rounds of Plasmodium parasitemia. Single-cell T cell receptor sequencing of the expanded mouse cells revealed oligoclonal γδ T cells restricted to the TRAV15N-1 (Vδ6.3) V-region and converging complementarity-determining region 3 (CDR3) motifs. Also, RNA-seq of the expanded γδ T cells showed an unexpected transcriptional profile characterized by myeloid-modulating factors, previously unseen in γδ T cells. The expanded TRAV15N-1 γδ T cells abundantly produced M-CSF, which was necessary for preventing parasitemic recurrence. Interestingly, αβ T cells were the major source of M-CSF during acute infection, while γδ T cells filled that role during the post-acute stage. We have uncovered a novel γδ T cell subset that fills a protective role in the late stage of malaria. These cells could provide the mechanism for other observed correlations between γδ T cell and myeloid activity in cancer and infectious disease.
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