The mucosal immune system forms the largest part of the entire immune system, containing about three-quarters of all lymphocytes and producing grams of secretory IgA daily to protect the mucosal surface from pathogens. To evoke the mucosal immune response, antigens on the mucosal surface must be transported across the epithelial barrier into organized lymphoid structures such as Peyer's patches. This function, called antigen transcytosis, is mediated by specialized epithelial M cells. The molecular mechanisms promoting this antigen uptake, however, are largely unknown. Here we report that glycoprotein 2 (GP2), specifically expressed on the apical plasma membrane of M cells among enterocytes, serves as a transcytotic receptor for mucosal antigens. Recombinant GP2 protein selectively bound a subset of commensal and pathogenic enterobacteria, including Escherichia coli and Salmonella enterica serovar Typhimurium (S. Typhimurium), by recognizing FimH, a component of type I pili on the bacterial outer membrane. Consistently, these bacteria were colocalized with endogenous GP2 on the apical plasma membrane as well as in cytoplasmic vesicles in M cells. Moreover, deficiency of bacterial FimH or host GP2 led to defects in transcytosis of type-I-piliated bacteria through M cells, resulting in an attenuation of antigen-specific immune responses in Peyer's patches. GP2 is therefore a previously unrecognized transcytotic receptor on M cells for type-I-piliated bacteria and is a prerequisite for the mucosal immune response to these bacteria. Given that M cells are considered a promising target for oral vaccination against various infectious diseases, the GP2-dependent transcytotic pathway could provide a new target for the development of M-cell-targeted mucosal vaccines.
mazonas state reported the first confirmed SARS-CoV-2 case in Manaus, the state capital, in March 2020 in a traveler returning from Europe 1 . By late February 2021, >306,000 laboratory-confirmed cases and more than 10,400 deaths in Amazonas had been reported 2 . The COVID-19 epidemic in Amazonas is, at the time of writing, characterized by two exponentially growing curves of cases (Fig. 1a). Epidemiological data from surveillance of severe acute respiratory illness (SARI) and burials indicate that the first wave of the epidemic started in March 2020 and peaked around early May 2020, when the number of cases dropped and then remained roughly stable from June to November 2020. However, in mid-December the number of cases started to grow exponentially, establishing the second wave of the epidemic.A new SARS-CoV-2 VOC, designated P.1 and also knowns as N501Y.V3, recently emerged in Manaus. Lineage P.1 was first detected in four travelers returning to Japan from Amazonas state on 2 January 2021 (ref. 3 ) and was soon recognized as an emergent lineage in Manaus 4 . The VOC P.1 harbors 21 lineage-defining mutations, including ten in the Spike protein (L18F, T20N, P26S, D138Y, R190S, K417T, E484K, N501Y, H655Y and T1027I). The emergence of P.1 was touted as one of the putative causes of the second wave of COVID-19 in Manaus 5 . However, the precise relationship between circulating SARS-CoV-2 variants and epidemic dynamics in Amazonas remains unclear due to the paucity of viral sequences sampled in this Brazilian state before December 2020. Results Evidence of successive SARS-CoV-2 lineage replacements in Amazonas.To acquire a more in-depth understanding of the genetic diversity of SARS-CoV-2 variants circulating in Amazonas state since the early epidemic, we generated 250 SARS-CoV-2 high-quality, whole-genome sequences from individuals living in 25 municipalities, between 16 March 2020 and 13 January 2021 (Fig. 1a,b). Viral sequences were generated at FIOCRUZ Amazônia, which is part of both the Amazonas state health genomics network (REGESAM) and the consortium FIOCRUZ COVID-19 Genomics Surveillance Network of the Brazilian Ministry of Health (http:// www.genomahcov.fiocruz.br/). Our genomic survey revealed that most sequences were classified into five lineages:
4 of both GALT and nasopharynx-associated lymphoid tissue, which act as a major inductive site for Ag-specific mucosal immune responses (1, 2). Recently, we also identified M cells in the small intestinal villous epithelium, at effector sites far from the FAE, suggesting that Ag sampling via villous M cells may be responsible for induction of systemic Ag-specific immune responses, such as IgG production via the oral route (3). Still missing, however, were a characterization of the shared and distinctive traits of Peyer's patches (PPs) and villous M cells and a better understanding of the immunological nature of each.Recent comprehensive gene expression analyses using microdissected FAE or whole cells dissociated from the FAE identified genes specifically expressed by PP M cells (4 -6). Similar data, however, have not been available for villous M cells, in part because sufficient numbers of M cells are difficult to isolate from the surrounding intestinal epithelial cells (IECs). In mice, lectin Ulex europaeus agglutinin-1 (UEA-1) possessing affinity for ␣ (1, 2) fucose has been routinely used for the detection of such M cells (3, 7). UEA-1, however, does not alone suffice to identify M cells because it also reacts to goblet cells (3). Our laboratory has recently succeeded in distinguishing M cells from goblet cells by developing a mAb (NKM 16-2-4 mAb) that specifically reacts to murine PP and villous M cells but not goblet cells and IECs (8). Furthermore, our recent separate studies have demonstrated that oral administration of cholera toxin (CT) as mucosal adjuvant resulted in the induction of NKM 16-2-4 mAb ϩ and UEA-1 ϩ M-like cells, which have pocket structure and Ag uptake ability, in the duodenal villous epithelium (Terahara et al., submitted for publication). These recent advances in our understanding of M cells allowed us to define gene expression profiles capable of distinguishing PP M cells, CT-induced villous M-like cells, and IECs. Materials and Methods AnimalsBALB/c mice were purchased from Japan SLC. These mice were maintained under specific pathogen-free conditions in horizontal flow cabinets in our experimental animal facility at the University of Tokyo. Following a previously established protocol (9, 10), CT (List Biologic Laboratories) was dissolved in PBS (20 g/mouse) and then orally administered to BALB/c mice. Two days after CT administration, mice were used for experiments. All animal experiments were approved by the Animal Care and Use Committee of University of Tokyo. Lectins and Abs for the detection of M cellsThe following fluorescence-conjugated lectins and Abs were used for the identification of PP and villous M cells by FACS and histochemistry: PEconjugated UEA-1 (Biogenesis), rhodamine-conjugated UEA-1 (Vector
The Northern Brazilian state of Amazonas is one of the most heavily affected country regions by the COVID-19 epidemic and experienced two exponential growing waves in early and late 2020. Through a genomic epidemiology study based on 250 SARS-CoV-2 genomes from different Amazonas municipalities sampled between March 2020 and January 2021 we revealed that the first exponential growth phase was driven mostly by the dissemination of lineage B.1.195 which was gradually replaced by lineage B.1.1.28. The second wave coincides with the emergence of the variant of concern (VOC) P.1 which evolved from a local B.1.1.28 clade in late November and rapidly replaced the parental lineage in less than two months. Our findings support that successive lineage replacements in Amazonas were driven by a complex combination of variable levels of social distancing measures and the emergence of a more transmissible VOC P.1 virus. These data provide unique insights to understanding the mechanisms that underlie the COVID-19 epidemic waves and the risk of disseminating SARS-CoV-2 VOC P.1 in Brazil and potentially worldwide.
BACKGROUNDInfection with Zika virus (ZIKV) manifests in a broad spectrum of disease ranging from mild illness to severe neurological complications and little is known about Zika immunopathogenesis.OBJECTIVESTo define the immunologic biomarkers that correlate with acute ZIKV infection.METHODSWe characterized the levels of circulating cytokines, chemokines, and growth factors in 54 infected patients of both genders at five different time points after symptom onset using microbeads multiplex immunoassay; comparison to 100 age-matched controls was performed for statistical analysis and data mining.FINDINGSZIKV-infected patients present a striking systemic inflammatory response with high levels of pro-inflammatory mediators. Despite the strong inflammatory pattern, IL-1Ra and IL-4 are also induced during the acute infection. Interestingly, the inflammatory cytokines IL-1β, IL-13, IL-17, TNF-α, and IFN-γ; chemokines CXCL8, CCL2, CCL5; and the growth factor G-CSF, displayed a bimodal distribution accompanying viremia. While this is the first manuscript to document bimodal distributions of viremia in ZIKV infection, this has been documented in other viral infections, with a primary viremia peak during mild systemic disease and a secondary peak associated with distribution of the virus to organs and tissues.MAIN CONCLUSIONSBiomarker network analysis demonstrated distinct dynamics in concurrence with the bimodal viremia profiles at different time points during ZIKV infection. Such a robust cytokine and chemokine response has been associated with blood-brain barrier permeability and neuroinvasiveness in other flaviviral infections. High-dimensional data analysis further identified CXCL10, a chemokine involved in foetal neuron apoptosis and Guillain-Barré syndrome, as the most promising biomarker of acute ZIKV infection for potential clinical application.
Antibodies to human T-cell lymphotropic virus-1 and 2 (HTLV-1
BackgroundMulti-drug resistant forms of Pseudomonas aeruginosa (MDRPA) are a major source of nosocomial infections and when discharged into streams and rivers from hospital wastewater treatment plants (HWWTP) they are known to be able to persist for extended periods. In the city of Manaus (Western Brazilian Amazon), the effluent of three HWWTPs feed into the urban Mindu stream which crosses the city from its rainforest source before draining into the Rio Negro. The stream is routinely used by Manaus residents for bathing and cleaning (of clothes as well as domestic utensils) and, during periods of flooding, can contaminate wells used for drinking water.Results16S rRNA metagenomic sequence analysis of 293 cloned PCR fragments, detected an abundance of Pseudomonas aeruginosa (P. aeruginosa) at the stream’s Rio Negro drainage site, but failed to detect it at the stream’s source. An array of antimicrobial resistance profiles and resistance to all 14 tested antimicrobials was detected among P. aeruginosa cultures prepared from wastewater samples taken from water entering and being discharged from a Manaus HWWTP. Just one P. aeruginosa antimicrobial resistance profile, however, was detected from cultures made from Mindu stream isolates. Comparisons made between P. aeruginosa isolates’ genomic DNA restriction enzyme digest fingerprints, failed to determine if any of the P. aeruginosa found in the Mindu stream were of HWWTP origin, but suggested that Mindu stream P. aeruginosa are from diverse origins. Culturing experiments also showed that P. aeruginosa biofilm formation and the extent of biofilm formation produced were both significantly higher in multi drug resistant forms of P. aeruginosa.ConclusionsOur results show that a diverse range of MDRPA are being discharged in an urban stream from a HWWTP in Manaus and that P. aeruginosa strains with ampicillin and amikacin can persist well within it.
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