Passive immunization with polyclonal hyper immunoglobulin (HIG) therapy represents a proven strategy by transferring immunoglobulins to patients to confer immediate protection against a range of pathogens including infectious agents and toxins. Distinct from active immunization, the protection is passive and the immunoglobulins will clear from the system; therefore, administration of an effective dose must be maintained for prophylaxis or treatment until a natural adaptive immune response is mounted or the pathogen/agent is cleared. The current review provides an overview of this technology, key considerations to address different pathogens, and suggested improvements. The review will reflect on key learnings from development of HIGs in the response to public health threats due to Zika, influenza, and severe acute respiratory syndrome coronavirus 2.
Dendritic cells (DCs) are professional antigen presenting cells (APCs) capable of linking innate and adaptive immunity during infection. After recognition of pathogen-associated molecular patterns (PAMPs), DCs can engulf, process and present bacteria-derived antigens on MHC molecules to T cells. Because of the key role that DCs play on the initiation of innate and adaptive immunity, alterations in their function could render the host susceptible to bacterial dissemination. Consistent with this notion, is the observation that several pathogenic bacteria have evolved mechanisms to impair the DC capacity to prime naïve T cells. One of such bacteria is Salmonella enterica serovar Typhimurium, which causes a typhoid-like disease in mice and gastroenteritis in humans. Recent studies have shown that virulent Salmonella can use intestinal DCs to spread inside the host, evading T cell priming. The avoidance of T cell recognition by Salmonella is in large part achieved by the activity of gene products encoded on Salmonella Pathogenicity Islands -1 and - 2. The understanding of some of the remarkable molecular virulence mechanisms displayed by Salmonella has contributed to the design of new vaccines capable of inducing protective immunity against this pathogen in mouse models. Here we describe recent data underscoring the virulence mechanisms used by Salmonella to exploit DC function and discuss strategies based on this new knowledge aimed at the design of new efficient and safe vaccines against this pathogen.
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