Prevalence and gene characteristics of antibodies with cofactor-induced HIV-1 specificity.

The healthy immune repertoire contains a fraction of antibodies that bind to various biologically relevant cofactors, including heme. Interaction of heme with some antibodies results in induction of new antigen binding specificities and acquisition of binding polyreactivity. In vivo, extracellular heme is released as a result of hemolysis or tissue damage; hence the post-translational acquisition of novel antigen specificities might play an important role in the diversification of the immunoglobulin repertoire and host defense. Here, we demonstrate that seronegative immune repertoires contain antibodies that gain reactivity to HIV-1 gp120 upon exposure to heme. Furthermore, a panel of human recombinant antibodies was cloned from different B cell subpopulations, and the prevalence of antibodies with cofactor-induced specificity for gp120 was determined. Our data reveal that upon exposure to heme, ∼24% of antibodies acquired binding specificity for divergent strains of HIV-1 gp120. Sequence analyses reveal that heme-sensitive antibodies do not differ in their repertoire of variable region genes and in most of the molecular features of their antigen-binding sites from antibodies that do not change their antigen binding specificity. However, antibodies with cofactor-induced gp120 specificity possess significantly lower numbers of somatic mutations in their variable region genes. This study contributes to the understanding of the significance of cofactor-binding antibodies in immunoglobulin repertoires and of the influence that the tissue microenvironment might have in shaping adaptive immune responses.

Breaking the law: unconventional strategies for antibody diversification.

Antibodies are essential components of adaptive immunity. A typical antibody repertoire comprises an enormous diversity of antigen-binding specificities, which are generated by the genetic processes of recombination and mutation. Accumulating evidence suggests that the immune system can exploit additional strategies to diversify the repertoire of antigen specificities. These unconventional mechanisms exclusively target the antigen-binding sites of immunoglobulins and include the insertion of large amino acid sequences, post-translational modifications, conformational heterogeneity and use of nonprotein cofactor molecules. Here, we describe the different unconventional routes for diversification of antibody specificities. Furthermore, we highlight how the immune system has a much greater level of adaptability and plasticity than previously anticipated, which goes far beyond that encoded in the genome or generated by the acquisition of somatic mutations.

Conformational Plasticity in Broadly Neutralizing HIV-1 Antibodies Triggers Polyreactivity.

Human high-affinity antibodies to pathogens often recognize unrelated ligands. The molecular origin and the role of this polyreactivity are largely unknown. Here, we report that HIV-1 broadly neutralizing antibodies (bNAbs) are frequently polyreactive, cross-reacting with non-HIV-1 molecules, including self-antigens. Mutating bNAb genes to increase HIV-1 binding and neutralization also results in de novo polyreactivity. Unliganded paratopes of polyreactive bNAbs with improved HIV-1 neutralization exhibit a conformational flexibility, which contributes to enhanced affinity of bNAbs to various HIV-1 envelope glycoproteins and non-HIV antigens. Binding adaptation of polyreactive bNAbs to the divergent ligands mainly involves hydrophophic interactions. Plasticity of bNAbs' paratopes may, therefore, facilitate accommodating divergent viral variants, but it simultaneously triggers promiscuous binding to non-HIV-1 antigens. Thus, a certain level of polyreactivity can be a mark of adaptable antibodies displaying optimal pathogens' recognition.

Methods for Posttranslational Induction of Polyreactivity of Antibodies.

An antibody molecule that recognizes multiple unrelated antigens is defined as polyreactive. Polyreactivity is an intrinsic characteristic of immune repertoires. Degenerated antigen binding diversifies the repertoire of specificities, thus contributing to immune defense and immune regulation. Immune repertoire contains also a fraction of immunoglobulins, which acquire polyreactivity only following contact with various protein-destabilizing or pro-oxidative substances. Posttranslational induction of the antibody polyreactivity may have important repercussion for laboratory practice, as well as in cases of pathological conditions accompanied by liberation of large quantities of pro-oxidative substances such as heme, labile iron, or reactive oxygen species. Antibodies with induced polyreactivity have been demonstrated to exert pathogen neutralization and immune regulatory potential in inflammatory conditions, suggesting that this phenomenon may be exploited for design of therapeutic strategies. In this article, we provide description of the basic procedures for uncovering of the cryptic polyreactivity of antibodies by heme, ferrous ions, and acid pH solution.

Natural and Induced Antibody Polyreactivity.

Healthy immune repertoire contains a fraction of immunoglobulins that do not possess exquisite antigen specificity but are able to recognize numerous unrelated antigens with similar values of the binding affinity. These antibodies are referred to as polyreactive. Besides natural polyreactive antibodies immune repertoires contain antibodies that acquire polyreactivity post-translationally, upon structural changes in their variable regions. In this article we made an overview of the recent findings about antibody polyreactivity. After introduction of the concept, and description of the origin, functions, and molecular mechanisms of polyreactive antibodies, we discussed their role in autoimmunity, malignancy and infectious diseases. We made a parallel with similar data about antibodies with induced polyreactivity. This review highlights the importance of natural and acquired antibody polyreactivity in immune defense and surveillance and reveals their potential as a new type of therapeutics.