The mechanism of antibody formation in mouse bone marrow

The bone marrow (BM) is the major production site of B lymphocytes. The newly formed small B lymphocytes migrate, after a maturation period of one or more days, to the peripheral lymphoid organs (spleen, lymph nodes, tonsils, etc.), where they can be activated by antigen (after which they can differentiate into antibody-forming cells) or die. According to this view, most of the immunoglobul in(lg)- and antibodyproducing eel ls are considered to be confined to the peripheral lymphoid organs. However, publications have appeared during the last ninety years presenting evidence that antibody formation can also take place in the BM (Chapter 3). This thesis further investigates this phenomenon with mice as experimental animals. After primary immunization of mice with thymus-dependent (TO) antigens, antibody formation almost exclusively takes place in the peripheral lymphoid organs. However, after secondary immunization with the same antigen, substantial numbers of antibody-producing plaqueforming eel ls (PFC) are found not only in the peripheral lymphoid organs, but also in the BM. The first phase of the secondary response, about 1 week of duration, is characterized by much higher numbers of PFC in the spleen and/or lymph nodes than in the BM. But after this first phase, the PFC response in the BM is much higher than in al 1 other lymphoid organs togethe

Discordant detection of avian influenza virus subtypes in time and space between poultry and wild birds; towards improvement of surveillance programs

Avian influenza viruses from wild birds can cause outbreaks in poultry, and occasionally infect humans upon exposure to infected poultry. Identification and characterization of viral reservoirs and transmission routes is important to develop strategies that prevent infection of poultry, and subsequently virus transmission between poultry holdings and to humans. Based on spatial, temporal and phylogenetic analyses of data generated as part of intense and large-scale influenza surveillance programs in wild birds and poultry in the Netherlands from 2006 to 2011, we demonstrate that LPAIV subtype distribution differed between wild birds and poultry, suggestive of host-range restrictions. LPAIV isolated from Dutch poultry were genetically most closely related to LPAIV isolated from wild birds in the Netherlands or occasionally elsewhere in Western Europe. However, a relatively long time interval was observed between the isolations of related viruses from wild birds and poultry. Spatial analyses provided evidence for mallards (Anas platyrhynchos) being more abundant near primary infected poultry farms. Detailed year-round investigation of virus prevalence and wild bird species distribution and behavior near poultry farms should be used to improve risk assessment in relation to avian influenza virus introduction and retarget avian influenza surveillance programs

Estimation of Transmission Parameters of H5N1 Avian Influenza Virus in Chickens

Despite considerable research efforts, little is yet known about key epidemiological parameters of H5N1 highly pathogenic influenza viruses in their avian hosts. Here we show how these parameters can be estimated using a limited number of birds in experimental transmission studies. Our quantitative estimates, based on Bayesian methods of inference, reveal that (i) the period of latency of H5N1 influenza virus in unvaccinated chickens is short (mean: 0.24 days; 95% credible interval: 0.099–0.48 days); (ii) the infectious period of H5N1 virus in unvaccinated chickens is approximately 2 days (mean: 2.1 days; 95%CI: 1.8–2.3 days); (iii) the reproduction number of H5N1 virus in unvaccinated chickens need not be high (mean: 1.6; 95%CI: 0.90–2.5), although the virus is expected to spread rapidly because it has a short generation interval in unvaccinated chickens (mean: 1.3 days; 95%CI: 1.0–1.5 days); and (iv) vaccination with genetically and antigenically distant H5N2 vaccines can effectively halt transmission. Simulations based on the estimated parameters indicate that herd immunity may be obtained if at least 80% of chickens in a flock are vaccinated. We discuss the implications for the control of H5N1 avian influenza virus in areas where it is endemic

Evolutionary Analysis of Inter-Farm Transmission Dynamics in a Highly Pathogenic Avian Influenza Epidemic

Phylogenetic studies have largely contributed to better understand the emergence, spread and evolution of highly pathogenic avian influenza during epidemics, but sampling of genetic data has never been detailed enough to allow mapping of the spatiotemporal spread of avian influenza viruses during a single epidemic. Here, we present genetic data of H7N7 viruses produced from 72% of the poultry farms infected during the 2003 epidemic in the Netherlands. We use phylogenetic analyses to unravel the pathways of virus transmission between farms and between infected areas. In addition, we investigated the evolutionary processes shaping viral genetic diversity, and assess how they could have affected our phylogenetic analyses. Our results show that the H7N7 virus was characterized by a high level of genetic diversity driven mainly by a high neutral substitution rate, purifying selection and limited positive selection. We also identified potential reassortment in the three genes that we have tested, but they had only a limited effect on the resolution of the inter-farm transmission network. Clonal sequencing analyses performed on six farm samples showed that at least one farm sample presented very complex virus diversity and was probably at the origin of chronological anomalies in the transmission network. However, most virus sequences could be grouped within clearly defined and chronologically sound clusters of infection and some likely transmission events between farms located 0.8–13 Km apart were identified. In addition, three farms were found as most likely source of virus introduction in distantly located new areas. These long distance transmission events were likely facilitated by human-mediated transport, underlining the need for strict enforcement of biosafety measures during outbreaks. This study shows that in-depth genetic analysis of virus outbreaks at multiple scales can provide critical information on virus transmission dynamics and can be used to increase our capacity to efficiently control epidemics

Getting More Out of Less - A Quantitative Serological Screening Tool for Simultaneous Detection of Multiple Influenza A Hemagglutinin-Types in Chickens

Current avian influenza surveillance in poultry primarily targets subtypes of interest for the veterinary sector (H5, H7). However, as virological and serological evidence suggest, surveillance of additional subtypes is important for public health as well as for the poultry industry. Therefore, we developed a protein microarray enabling simultaneous identification of antibodies directed against different HA-types of influenza A viruses in chickens. The assay successfully discriminated negative from experimentally and naturally infected, seropositive chickens. Sensitivity and specificity depended on the cut-off level used but ranged from 84.4% to 100% and 100%, respectively, for a cut off level of =1:40, showing minimal cross reactivity. As this testing platform is also validated for the use in humans, it constitutes a surveillance tool that can be applied in human-animal interface studies

Antigenicity of the peplomer protein of infectious bronchitis virus

To study the antigenic structure of the peplomer protein of the avian coronavirus infectious bronchitis virus, fragments from the peplomer gene were generated by restriction-enzyme cleavage or by limited DNase digestion and inserted in the Escherichia coli expression plasrnid pEX (Stanley and Luzio, 1984). The antigenicity of the expression products was tested using a number of polyclonal antisera and monoclonal antibodies. The polyclonal antisera recognized different sets of epitopes in the 1162-residue sequence. The N-terminal region of one of the two subunits, S2, was recognized by all polyclonal sera and by two monoclonal antibodies. This clearly immunodominant region contains at least two adjacent or overlapping epitopes, one of which has been localized within 18 residues. The epitopes found as antigenic pEX expression products do not coincide with the regions in the S1 subunit that have been found to contain hypervariable sequences. We suggest that these regions constitute conformation dependent neutralization epitopes that cannot be detected in the pEX system. The relevance of our finclings for vaccine development is discussed

Antigenicity of the peplomer protein of infectious bronchitis virus

To study the antigenic structure of the peplomer protein of the avian coronavirus infectious bronchitis virus, fragments from the peplomer gene were generated by restriction-enzyme cleavage or by limited DNase digestion and inserted in the Escherichia coli expression plasrnid pEX (Stanley and Luzio, 1984). The antigenicity of the expression products was tested using a number of polyclonal antisera and monoclonal antibodies. The polyclonal antisera recognized different sets of epitopes in the 1162-residue sequence. The N-terminal region of one of the two subunits, S2, was recognized by all polyclonal sera and by two monoclonal antibodies. This clearly immunodominant region contains at least two adjacent or overlapping epitopes, one of which has been localized within 18 residues. The epitopes found as antigenic pEX expression products do not coincide with the regions in the S1 subunit that have been found to contain hypervariable sequences. We suggest that these regions constitute conformation dependent neutralization epitopes that cannot be detected in the pEX system. The relevance of our finclings for vaccine development is discussed