Examination of the immunoglobulin repertoire before and after Anthrax Vaccine Adsorbed immunization

Anthrax Vaccine Adsorbed (AVA) immunization protects against anthrax disease by eliciting a neutralizing antibody response. However, antigen-specific antibody concentrations are not observed in high quantities until three immunizations have been administered over six months. Even then, humoral responses to AVA do not provide long-term immunity without an annual booster. We followed six healthy volunteers over the five-dose, 18-month AVA schedule to characterize the genetics of the immunoglobulin repertoire during the vaccination series. Two tiers of data were collected: 1) Immunoglobulin variable region genes (IgVRG) from bulk sorted naïve, memory and plasmablast (PB) B cells and 2) single cell sorted and sequenced IgVRG from plasmablasts. Samples were collected prior to and one and two weeks following each immunization. Our initial analyses indicated that technical error, the variation introduced by biological sampling and standard sample preparation, resulted in skewed output, and we developed a model to better estimate quantitative values from Ig-seq. We also utilized unique molecular identifiers to correct for nucleotide errors and PCR over-amplification. Our analysis of IgVRG following AVA administration reveals that the population of peripheral PBs following primary immunization is not distinguishable from the pre-immune peripheral PB repertoire. These PBs have more somatic mutations than expected for newly activated and differentiated naïve B cells, and are unlikely to be vaccine-elicited. In contrast, PBs observed following the 2nd dose have low mutation frequencies that increase upon subsequent vaccination. These clones are more persistent than clones first observed following any other immunization, but still make up a very small proportion of the overall repertoire. At no time is the clonal repertoire consistently dominated by a few clones, and the total and plasmablast repertoires are highly transient, even after the elicitation of vaccine-specific antibodies. AVA immunization thus results in a polyclonal B cell response which is not dominated by one or a few highly specific, strongly-elicited clones. We conclude that primary immunization by AVA is not sufficiently immunogenic to elicit vaccine-responsive, class-switched PBs to the periphery, nor is complete AVA immunization able to sustain proliferation of individual clones, providing insight into why AVA may require regular boosts

Highly Pathogenic Avian Influenza A(H5N1) Virus Outbreak in New England Seals, United States

We report the spillover of highly pathogenic avian influenza A(H5N1) into marine mammals in the northeastern United States, coincident with H5N1 in sympatric wild birds. Our data indicate monitoring both wild coastal birds and marine mammals will be critical to determine pandemic potential of influenza A viruses

Emergence and radiation of distemper viruses in terrestrial and marine mammals

Canine distemper virus (CDV) and phocine distemper virus (PDV) are major pathogens to terrestrial and marine mammals. Yet little is known about the timing and geographical origin of distemper viruses and to what extent it was influenced by environmental change and human activities. To address this, we (i) performed the first comprehensive time-calibrated phylogenetic analysis of the two distemper viruses, (ii) mapped distemper antibody and virus detection data from marine mammals collected between 1972 and 2018, and (iii) compiled historical reports on distemper dating back to the eighteenth century. We find that CDV and PDV diverged in the early seventeenth century. Modern CDV strains last shared a common ancestor in the nineteenth century with a marked radiation during the 1930s–1950s. Modern PDV strains are of more recent origin, diverging in the 1970s–1980s. Based on the compiled information on distemper distribution, the diverse host range of CDV and basal phylogenetic placement of terrestrial morbilliviruses, we hypothesize a terrestrial CDV-like ancestor giving rise to PDV in the North Atlantic. Moreover, given the estimated timing of distemper origin and radiation, we hypothesize a prominent role of environmental change such as the Little Ice Age, and human activities like globalization and war in distemper virus evolution

Longitudinal analysis of pinnipeds in the northwest Atlantic provides insights on endemic circulation of phocine distemper virus

Phocine distemper virus (PDV) is a morbillivirus that circulates within pinnipeds in the North Atlantic. PDV has caused two known unusual mortality events (UMEs) in western Europe (1988, 2002), and two UMEs in the northwest Atlantic (2006, 2018). Infrequent cross-species transmission and waning immunity are believed to contribute to periodic outbreaks with high mortality in western Europe. The viral ecology of PDV in the northwest Atlantic is less well defined and outbreaks have exhibited lower mortality than those in western Europe. This study sought to understand the molecular and ecological processes underlying PDV infection in eastern North America. We provide phylogenetic evidence that PDV was introduced into northwest Atlantic pinnipeds by a single lineage and is now endemic in local populations. Serological and viral screening of pinniped surveillance samples from 2006 onward suggest there is continued circulation of PDV outside of UMEs among multiple species with and without clinical signs. We report six full genome sequences and nine partial sequences derived from harbour and grey seals in the northwest Atlantic from 2011 through 2018, including a possible regional variant. Work presented here provides a framework towards greater understanding of how recovering populations and shifting species may impact disease transmission