A genetic screen identifies genes and sites involved in pilin antigenic variation in Neisseria gonorrhoeae

It has previously been shown that the frequency of pilin antigenic variation in Neisseria gonorrhoeae (the gonococcus, Gc) is regulated by iron availability. To identify factors involved in pilin variation in an iron-dependent or an iron-independent manner, we conducted a genetic screen of transposon-mutated gonococci using a pilus-dependent colony morphology phenotype to detect antigenic variation deficient mutants. Forty-six total mutants representing insertions in 30 different genes were shown to have reduced colony morphology changes resulting from impaired pilin variation. Five mutants exhibited an iron-dependent decrease in pilin variation, while the remaining 41 displayed an iron-independent decrease in pilin variation. Based on the levels of antigenic variation impairment, we defined the genes as being essential for, important for, or involved in antigenic variation. DNA repair and DNA transformation frequencies of each mutant were measured to determine whether other recombination-based processes were also affected in the mutants. Each mutant was placed into one of six classes based on their pilin variation, DNA repair and DNA transformation phenotypes. Among the many genes identified, recR is shown to be an additional member of the gonococcal RecF-like recombination pathway. In addition, recG and ruvA represent the first evidence that the processing of Holliday junctions is required for pilin antigenic variation. Moreover, two independent insertions in a non-coding region upstream of the pilE gene suggest that cis-acting sequences important for pilin variation are found in that region. Finally, insertions that effect expression of the thrB and thrC genes suggest that molecules in the threonine biosynthetic pathway are important for pilin variation. Many of the other genes identified in this genetic screen do not have an obvious role in pilin variation, DNA repair, or DNA transformation.     

Genome hyperevolution and the success of a parasite

The strategy of antigenic variation is to present a constantly changing population phenotype that enhances parasite transmission, through evasion of immunity arising within, or existing between, host animals. Trypanosome antigenic variation occurs through spontaneous switching among members of a silent archive of many hundreds of variant surface glycoprotein (VSG) antigen genes. As with such contingency systems in other pathogens, switching appears to be triggered through inherently unstable DNA sequences. The archive occupies subtelomeres, a genome partition that promotes hypermutagenesis and, through telomere position effects, singular expression of VSG. Trypanosome antigenic variation is augmented greatly by the formation of mosaic genes from segments of pseudo-VSG, an example of implicit genetic information. Hypermutation occurs apparently evenly across the whole archive, without direct selection on individual VSG, demonstrating second-order selection of the underlying mechanisms. Coordination of antigenic variation, and thereby transmission, occurs through networking of trypanosome traits expressed at different scales from molecules to host populations.     

Competition among serologically different clones of Trypanosoma brucei gambiense in vivo.

When different antigenic variant clones are injected in equal numbers into white mice one variant clone always replaces the other. This phenomenon appears to be a predictable one, even under conditions analogous to a chronic infection. It is hypothesized that a constant ratio is approached between the number of cells of different antigenic serotypes present in a single population, in such a manner that there is always a major antigenic variant and minor populations of different antigenic variants. It is further suggested that these ratios can undergo rapid changes in response to changes in the environment, e.g. nutritional status of the host, changes in body temperature, antibody synthesis, etc. The changes in these ratios are discussed in relation to the mechanism(s) of antigenic variation.     

Competition among Serologically Different Clones of Trypanosoma brucei gambiense in vivo*

SYNOPSIS. When different antigenic variant clones are injected in equal numbers into white mice one variant clone always replaces the other. This phenomenon appears to be a predictable one, even under conditions analogous to a chronic infection. It is hypothesized that a constant ratio is approached between the number of cells of different antigenic serotypes present in a single population, in such a manner that there is always a major antigenic variant and minor populations of different antigenic variants. It is further suggested that these ratios can undergo rapid changes in response to changes in the environment, e.g. nutritional status of the host, changes in body temperature, antibody synthesis, etc. The changes in these ratios are discussed in relation to the mechanism(s) of antigenic variation.     

The ecology of antigenic variation

A detailed molecular analysis using recombinant DNA technologies is extremely important to our understanding of the phenomena of antigenic variation in the African trypanosomes; however, by itself, it may not completely explain antigenic variation as it occurs in vivo. Several laboratories have demonstrated the ability of one variant population to replace another in vivo as well as the presence of heterogeneous populations of trypanosomes within an individual animal. These two phenomena do not permit us to explain antigen variation solely on the basis of the molecular regulation of variant antigen expression. In addition to studies in molecular biology, it will be necessary to define clearly the differences in growth rates of variant populations and the role of competition between these variants in a single anatomical site. It will also be necessary to determine the influence of various physiological environments on growth rates and the competition between the different variants of a single repertoire. It is concluded that the phenomenon of antigenic variation is a complex problem in ecology and population dynamics as well as molecular regulation. This paper is designated to examine a variety of the ecological parameters presumably involved in antigenic variation.     

The Ecology of Antigenic Variation1,2

A detailed molecular analysis using recombinant DNA technologies is extremely important to our understanding of the phenomena of antigenic variation in the African trypanosomes; however, by itself, it may not completely explain antigenic variation as it occurs in vivo. Several laboratories have demonstrated the ability of one variant population to replace another in vivo as well as the presence of heterogeneous populations of trypanosomes within an individual animal. These two phenomena do not permit us to explain antigen variation solely on the basis of the molecular regulation of variant antigen expression. In addition to studies in molecular biology, it will be necessary to define clearly the differences in growth rates of variant populations and the role of competition between these variants in a single anatomical site. It will also be necessary to determine the influence of various physiological environments on growth rates and the competition between the different variants of a single repertoire. It is concluded that the phenomenon of antigenic variation is a complex problem in ecology and population dynamics as well as molecular regulation. This paper is designated to examine a variety of the ecological parameters presumably involved in antigenic variation.     

用单克隆抗体研究鸡新城疫病毒抗原变异与流行病学的相关性

用19株抗鸡新城疫病毒(NDV)单克隆抗体(简称单抗)测定与14个NDV国际参考株和16个NDV国内分离株的反应性,将毒株分为a～h 8个群。该组单抗能较精细地测出流行病学上不同的毒株间的抗原变异,毒株分群显示了抗原变异与流行病学特征的相关性。     

Analysis of the Piv recombinase-related gene family of Neisseria gonorrhoeae

Neisseria gonorrhoeae (the gonococcus) is an obligate human pathogen and the causative agent of the disease gonorrhea. The gonococcal pilus undergoes antigenic variation through high-frequency recombination events between unexpressed pilS silent copies and the pilin expression locus pilE. The machinery involved in pilin antigenic variation identified to date is composed primarily of genes involved in homologous recombination. However, a number of characteristics of antigenic variation suggest that one or more recombinases, in addition to the homologous recombination machinery, may be involved in mediating sequence changes at pilE. Previous work has identified several genes in the gonococcus with significant identity to the pilin inversion gene (piv) from Moraxella species and transposases of the IS110 family of insertion elements. These genes were candidates for a recombinase system involved in pilin antigenic variation. We have named these genes irg for invertase-related gene family. In this work, we characterize these genes and demonstrate that the irg genes do not complement for Moraxella lacunata Piv invertase or IS492 MooV transposase activities. Moreover, by inactivation of all eight gene copies and overexpression of one gene copy, we conclusively show that these recombinases are not involved in gonococcal pilin variation, DNA transformation, or DNA repair. We propose that the irg genes encode transposases for two different IS110-related elements given the names ISNgo2 and ISNgo3. ISNgo2 is located at multiple loci on the chromosome of N. gonorrhoeae, and ISNgo3 is found in single and duplicate copies in the N. gonorrhoeae and Neisseria meningitidis genomes, respectively.     

Antigenic variation of influenza A virus nucleoprotein detected with monoclonal antibodies.

Monoclonal antibodies were used to study antigenic variation in the nucleoprotein of influenza A viruses. We found that the nucleoprotein molecule of the WSN/33 strain possesses at least five different determinants. Viruses of other influenza A virus subtypes showed antigenic variation in these nucleoprotein determinants, although changes in only one determinant were detected in H0N1 and animal strains. The nucleoprotein of human strains isolated from 1933 through 1979 could be divided into six groups, based on their reactivities with monoclonal antibodies; these groups did not correlate with any particular hemagglutinin or neuraminidase subtype. Our results indicate that antigenic variation in the nucleoproteins of influenza A viruses proceeds independently of changes in the viral surface antigens and suggest that point mutations and genetic reassortment may account for nucleoprotein variability.     

Differential roles of homologous recombination pathways in Neisseria gonorrhoeae pilin antigenic variation, DNA transformation and DNA repair

Neisseria gonorrhoeae (Gc) pili undergo antigenic variation when the amino acid sequence of the pilin protein is changed, aiding in immune avoidance and altering pilus expression. Pilin antigenic variation occurs by RecA-dependent unidirectional transfer of DNA sequences from a silent pilin locus to the expressed pilin gene through high-frequency recombination events that occur at limited regions of homology. We show that the Gc recQ and recO genes are essential for pilin antigenic and phase variation and DNA repair but are not involved in natural DNA transformation. This suggests that a RecF-like pathway of recombination exists in Gc. In addition, mutations in the Gc recB, recC or recD genes revealed that a Gc RecBCD pathway also exists and is involved in DNA transformation and DNA repair but not in pilin antigenic variation.     

Recombination among Protein II genes of Neisseria gonorrhoeae generates new coding sequences and increases structural variability in the Protein II family

Expression of Neisseria gonorrhoeae Protein II (P.II) is subject to phase variation and antigenic variation. The P.II proteins made by one strain possess both unique and conserved antigenic determinants. To study the mechanism of antigenic variation, we cloned several P.II genes, using as probes a panel of monoclonal antibodies (MAbs) specific for unique determinants. The DNA sequences of three P.II genes showed that they shared a conserved framework, with two short hypervariable (HV) regions being responsible for most of the differences among them. We demonstrated that unique epitopes recognized by the MAbs were at least partially encoded by one of the HV regions. Moreover, we found that reassortment of the two HV regions among P.II genes occurs, generating increased structural and antigenic variability in the P.II protein family.     

Shift in S-layer protein expression responsible for antigenic variation in Campylobacter fetus.

Campylobacter fetus strains possess regular paracrystalline surface layers (S-layers) composed of high-molecular-weight proteins and can change the size and crystalline structure of the predominant protein expressed. Polyclonal antisera demonstrate antigenic cross-reactivity among these proteins but suggest differences in epitopes. Monoclonal antibodies to the 97-kDa S-layer protein of Campylobacter fetus subsp. fetus strain 82-40LP showed three different reactivities. Monoclonal antibody 1D1 recognized 97-kDa S-layer proteins from all C. fetus strains studied; reactivity of monoclonal antibody 6E4 was similar except for epitopes in S-layer proteins from reptile strains and strains with type B lipopolysaccharide. Monoclonal antibody 2E11 only recognized epitopes on S-layer proteins from strains with type A lipopolysaccharide regardless of size. In vitro shift from a 97-kDa S-layer protein to a 127-kDa S-layer protein resulted in different reactivity, indicating that size change was accompanied by antigenic variation. To examine in vivo variation, heifers were genetically challenged with Campylobacter fetus subsp. venerealis strains and the S-layer proteins from sequential isolates were characterized. Analysis with monoclonal antibodies showed that antigenic reactivities of the S-layer proteins were varied, indicating that these proteins represent a system for antigenic variation.     

The effects of symmetry on the dynamics of antigenic variation

In the studies of dynamics of pathogens and their interactions with a host immune system, an important role is played by the structure of antigenic variants associated with a pathogen. Using the example of a model of antigenic variation in malaria, we show how many of the observed dynamical regimes can be explained in terms of the symmetry of interactions between different antigenic variants. The results of this analysis are quite generic, and have wider implications for understanding the dynamics of immune escape of other parasites, as well as for the dynamics of multi-strain diseases.     

Antigenic variation in foot-and-mouth disease: studies based on the virus neutralization reaction

The neutralization reaction is the most appropriate in vitro reference test system for assessing intratypic antigenic variation as it involves the antigenic determinants responsible for virus strain specificity and evoking protective antibody. Antigenic relationships determined in different neutralization test systems were independent of the system used and were assumed to truly reflect antigenic variation. The two-dimensional microneutralization test was found to be appropriate for foot and mouth disease (FMD) virus strain differentiation. To minimize test to test variation, comparisons are performed as matched pairs. The pooled variance of the test system is used to assess the significance of the relationships obtained. Antisera from convalescent animals were less specific than those from vaccinates. Serum quality seemed less critical for the virus neutralization than the complement fixation reaction. A system for FMD virus strain differentiation based on the use of the virus neutralization reaction taking into account the statistical and biological significance of observed r values is recommended.     

Mosaic VSGs and the Scale of Trypanosoma brucei Antigenic Variation

A main determinant of prolonged Trypanosoma brucei infection and transmission and success of the parasite is the interplay between host acquired immunity and antigenic variation of the parasite variant surface glycoprotein (VSG) coat. About 0.1% of trypanosome divisions produce a switch to a different VSG through differential expression of an archive of hundreds of silent VSG genes and pseudogenes, but the patterns and extent of the trypanosome diversity phenotype, particularly in chronic infection, are unclear. We applied longitudinal VSG cDNA sequencing to estimate variant richness and test whether pseudogenes contribute to antigenic variation. We show that individual growth peaks can contain at least 15 distinct variants, are estimated computationally to comprise many more, and that antigenically distinct ‘mosaic’ VSGs arise from segmental gene conversion between donor VSG genes or pseudogenes. The potential for trypanosome antigenic variation is probably much greater than VSG archive size; mosaic VSGs are core to antigenic variation and chronic infection.     

Antigenic variation and the murine immune response to Giardia lamblia

The protozoan parasite Giardia lamblia is an important causative agent of acute or chronic diarrhoea in humans and various animals. During infection, the parasite survives the hosts reactions by undergoing continuous antigenic variation of its major surface antigen, named VSP (variant surface protein). The VSPs form a unique family of cysteine-rich proteins that are extremely heterogeneous in size. The relevance of antigenic variation for the survival in the host has been most successfully studied by performing experimental infections in a combined mother/offspring mouse system and by using the G. lamblia clone GS/M-83-H7 (human isolate) as model parasite. In-vivo antigenic variation of G. lamblia clone GS/M-83-H7 is characterised by a diversification of the intestinal parasite population into a complex mixture of different variant antigen types. It could be shown that maternally transferred lactogenic anti-VSP IgA antibodies exhibit cytotoxic activity on the Giardia variant-specific trophozoites in suckling mice, and thus express a modulatory function on the proliferative parasite population characteristics. Complementarily, in-vitro as well as in-vivo experiments in adult animals indicated that non-immunological factors such as intestinal proteases may interfere into the process of antigen variation in that they favour proliferation of those variant antigen-type populations which resist the hostile physiological conditions within the intestine. These observations suggest that an interplay between immunological and physiological factors, rather than one of these two factor alone, modulates antigenic diversification of a G. lamblia population within an experimental murine host and thus influences the survival rate and strategy of the parasite.     

Surface antigen variability and variation in Giardia lamblia

Recent studies show that Giardia isolates are heterogeneous but fall into at least three groups as determined by a number of complementary techniques. Giardia undergoes surface antigenic variation, both in vitro, and in humans and other animal model infections. Many of the characteristics of antigenic variation and the proteins involved, called variant-specific surface proteins (VSPs), are unique. The sequences of five VSPs reveal a family of cysteine-rich proteins. Here Theodore Nash reviews the relationship between antigenic variation and Giardia heterogeneity.     

Pilin gene variation in Neisseria gonorrhoeae: reassessing the old paradigms

Neisseria gonorrhoeae displays considerable potential for antigenic variation as shown in human experimental studies. Various surface antigens can change either by antigenic variation using RecA-dependent recombination schemes (e.g. PilE antigenic variation) or, alternatively, through phase variation (on/off switching) in a RecA-independent fashion (e.g. Opa and lipooligosaccharide phase variation). PilE antigenic variation has been well documented over the years. However, with the availability of the N. gonorrhoeae FA1090 genome sequence, considerable genetic advances have recently been made regarding the mechanistic considerations of the gene conversion event, leading to an altered PilE protein. This review will compare the various models that have been presented and will highlight potential mechanistic problems that may constrain any genetic model for pilE gene variation.