Immune Network Theory

Theoretical ideas have played a profound role in the development of idiotypic network theory. Mathematical models can help in the precise translation of speculative ideas into quantitative predictions. They can also help establish general principles and frameworks for thinking. Using the idea of shape space, criteria were introduced for evaluating the completeness and overlap in the antibody repertoire. Thinking about the distribution of clones in shape space naturally leads to considerations of stability and controllability. An immune system which is too stable will be sluggish and unresponsive to antigenic challenge; one which is unstable will be driven into immense activity by internal fluctuations. This led us to postulate that the immune system should be stable but not too stable. In many biological contexts the development of pattern requires both activation and inhibition but on different spatial scales. Similar ideas can be applied to shape space. The principle of short-range activation and long-range inhibition translates into specific activation and less specific inhibition. Application of this principle in model immune systems can lead to the stable maintenance of non-uniform distributions of clones in shape space. Thus clones which are useful and recognize antigen or internal images of antigen can be maintained at high population levels whereas less useful clones can be maintained at lower population levels. Pattern in shape space is a minimal requirement for a model. Learning and memory correspond to the development and maintenance of particular patterns in shape space. Representing antibodies by binary strings allows one to develop models in which the binary string acts as a tag for a specific molecule or clone. Thus models with huge numbers of cells and molecules can be developed and analyzed using computers. Using parallel computers or finite state models it should soon be feasible to study model immune systems with 10(5) or more elements. Although idiotypic networks were the focus of this paper, these modeling strategies are general and apply equally well to non-idiotypic models. Using bit string or geometric models of antibody combining sites, the affinity of interaction between any two molecules, and hence the connections in a model idiotypic network, can be determined. This approach leads to the prediction of a phase transition in the structure of idiotypic networks. On one side of the transition networks are small localized structures much as might be predicted by clonal selection and circuit ideas.(ABSTRACT TRUNCATED AT 400 WORDS)

[1]  R. J. Goldberg,et al.  A Theory of Antibody—Antigen Reactions. I. Theory for Reactions of Multivalent Antigen with Bivalent and Univalent Antibody2 , 1952 .

[2]  A. Turing The chemical basis of morphogenesis , 1952, Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences.

[3]  Ontogeny of the immune response in cold-blooded vertebrates. , 1973, Current topics in microbiology and immunology.

[4]  N K Jerne,et al.  Towards a network theory of the immune system. , 1973, Annales d'immunologie.

[5]  C. DeLisi A theory of precipitation and agglutination reactions in immunological systems. , 1974, Journal of theoretical biology.

[6]  N. K. Jerne,et al.  Clonal selection in a lymphocyte network. , 1974, Society of General Physiologists series.

[7]  Jerne Nk Towards a network theory of the immune system. , 1974 .

[8]  N. Klinman,et al.  The B Cell Specificity Repertoire: Its Relationship to Definable Subpopulations , 1975, Transplantation reviews.

[9]  G. Hoffmann A theory of regulation and self‐nonself discrimination in an immune network , 1975, European journal of immunology.

[10]  P. Richter,et al.  A network theory of the immune system , 1975, European journal of immunology.

[11]  C DeLisi,et al.  The kinetics of aggregation phenomena. I. Minimal models for patch formation of lymphocyte membranes. , 1976, Journal of theoretical biology.

[12]  J. Hiernaux,et al.  Some remarks on the stability of the idiotypic network. , 1977, Immunochemistry.

[13]  N. Sigal,et al.  The B-cell clonotype repertoire. , 1978, Advances in immunology.

[14]  Geoffrey W. Hoffmann,et al.  A Mathematical Model of the Stable States of a Network Theory of Self-Regulation , 1979 .

[15]  G. Oster,et al.  Theoretical studies of clonal selection: minimal antibody repertoire size and reliability of self-non-self discrimination. , 1979, Journal of theoretical biology.

[16]  G. Kelsoe,et al.  Reciprocal expansions of idiotypic and anti-idiotypic clones following antigen stimulation , 1979, Nature.

[17]  A. Perelson Receptor clustering on a cell surface. I. theory of receptor cross-linking by ligands bearing two chemically identical functional groups , 1980 .

[18]  G W Hoffmann,et al.  On network theory and H-2 restriction. , 1980, Contemporary topics in immunobiology.

[19]  J. Teale,et al.  Tolerance as an active process , 1980, Nature.

[20]  A Coutinho,et al.  The self-nonself discrimination and the nature and acquisition of the antibody repertoire. , 1980, Annales d'immunologie.

[21]  Individuality of Immune Systems: the Thousand Ways and One Way of Being Complete , 1981 .

[22]  H. Meinhardt Models of biological pattern formation , 1982 .

[23]  H. Kunkel,et al.  Anti-immunoglobulin antibodies. III. Properties of sequential anti- idiotypic antibodies to heterologous anti-gamma globulins. Detection of reactivity of anti-idiotype antibodies with epitopes of Fc fragments (homobodies) and with epitopes and idiotopes (epibodies) , 1982, The Journal of experimental medicine.

[24]  L. Segel,et al.  Models of the influence of predation on aspect diversity in prey populations , 1982, Journal of mathematical biology.

[25]  G W Hoffmann,et al.  Qualitative dynamics of a network model of regulation of the immune system: a rationale for the IgM to IgG switch. , 1982, Journal of Theoretical Biology.

[26]  N. K. Jerne,et al.  Recurrent idiotopes and internal images. , 1982, The EMBO journal.

[27]  F. L. Adler,et al.  Regulation of natural antiallotype antibody responses by idiotype network-induced auto-antiidiotypic antibodies , 1983, The Journal of experimental medicine.

[28]  H. Dintzis,et al.  Studies on the immunogenicity and tolerogenicity of T-independent antigens. , 1983, Journal of immunology.

[29]  N. K. Jerne,et al.  Idiotypic Networks and Other Preconceived Ideas , 1984, Immunological reviews.

[30]  A. Coutinho,et al.  From an Antigen‐Centered, Clonal Perspective of Immune Responses to an Organism‐Centered, Network Perspective of Autonomous Activity in a Self‐Referential Immune System , 1984, Immunological reviews.

[31]  Membrane and metabolic requirements for tolerance induction of neonatal B cells. , 1984, Journal of immunology.

[32]  S. Redner,et al.  Introduction To Percolation Theory , 2018 .

[33]  K. Bost,et al.  Regions of complementarity between the messenger RNAs for epidermal growth factor, transferrin, interleukin-2 and their respective receptors. , 1985, Biochemical and biophysical research communications.

[34]  H. Dintzis,et al.  Inhibition of anti-DNP antibody formation by high doses of DNP-polyacrylamide molecules; effects of hapten density and hapten valence. , 1985, Journal of immunology.

[35]  K. Bost,et al.  Similarity between the corticotropin (ACTH) receptor and a peptide encoded by an RNA that is complementary to ACTH mRNA. , 1985, Proceedings of the National Academy of Sciences of the United States of America.

[36]  F. Uher,et al.  Cooperativity between B lymphocyte membrane molecules: independent ligand occupancy and cross-linking of antigen receptors and Fc gamma receptors down-regulates B lymphocyte function. , 1986, Journal of immunology.

[37]  M. Cohn The concept of functional idiotype network for immune regulation mocks all and comforts none. , 1986, Annales de l'Institut Pasteur. Immunologie.

[38]  Alan S. Perelson,et al.  The immune system, adaptation, and machine learning , 1986 .

[39]  R. Riley,et al.  The affinity threshold for antigenic triggering differs for tolerance susceptible immature precursors vs mature primary B cells. , 1986, Journal of immunology.

[40]  M Cohn,et al.  The 'complete' idiotype network is an absurd immune system. , 1986, Immunology today.

[41]  H. Kohler,et al.  A Novel Chimeric Antibody with Circular Network Characteristics: Autobody a , 1986, Annals of the New York Academy of Sciences.

[42]  J. Kearney,et al.  Idiotypic network connectivity and a possible cause of myasthenia gravis , 1986, The Journal of experimental medicine.

[43]  G. Oster,et al.  A MODEL FOR SHELL PATTERNS BASED ON NEURAL ACTIVITY , 1986 .

[44]  M. Sporn,et al.  Transforming growth factor beta is an important immunomodulatory protein for human B lymphocytes. , 1986, Journal of immunology.

[45]  A. Coutinho,et al.  Antibody Repertoires of Normal BALB/c Mice: B Lymphocyte Populations Defined by State of Activation , 1986, Immunological reviews.

[46]  Irene Stadnyk,et al.  Schema Recombination in Pattern Recognition Problems , 1987, ICGA.

[47]  S. Kauffman,et al.  Adaptive Dynamic Networks as Models for the Immune System and Autocatalytic Sets , 1987, Annals of the New York Academy of Sciences.

[48]  Y. Shai,et al.  Anti-sense peptide recognition of sense peptides: direct quantitative characterization with the ribonuclease S-peptide system using analytical high-performance affinity chromatography. , 1987, Biochemistry.

[49]  K. Bost,et al.  Generation of idiotypic and anti-idiotypic antibodies by immunization with peptides encoded by complementary RNA: a possible molecular basis for the network theory. , 1987, Journal of immunology.

[50]  A. Abbas,et al.  Inhibition of B lymphocyte activation by interferon-gamma. , 1987, Journal of immunology.

[51]  R. J. Boer Symmetric idiotypic networks : connectance and switching, stability, and suppression , 1988 .

[52]  George Oster,et al.  Lateral inhibition models of developmental processes , 1988 .

[53]  R. J. Boer Extensive Percolation in Reasonable Idiotypic Networks , 1989 .

[54]  Albert Goldbeter,et al.  Cell to cell signalling : from experiments to theoretical models , 1989 .

[55]  Pauline Hogeweg,et al.  Memory but no suppression in low-dimensional symmetric idiotypic networks , 1989, Bulletin of mathematical biology.

[56]  P. Hogeweg,et al.  Stability of symmetric idiotypic networks--a critique of Hoffmann's analysis. , 1989, Bulletin of mathematical biology.

[57]  Gérard Weisbuch Dynamical Behavior of Discrete Models of Jerne’s Network , 1989 .

[58]  Alan S. Perelson,et al.  Shape space analysis of immune networks , 1989 .

[59]  P. Hogeweg,et al.  Unreasonable implications of reasonable idiotypic network assumptions. , 1989, Bulletin of mathematical biology.

[60]  A. Perelson Immune networks: A topological view , 1989 .

[61]  L. A. Segel,et al.  Some Reflections on Memory in Shape Space , 1989 .

[62]  G. Parisi A simple model for the immune network. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[63]  A. M. Turing,et al.  The chemical basis of morphogenesis , 1952, Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences.

[64]  Alan S. Perelson,et al.  A paradoxical instability caused by relatively short-range inhibition , 1990 .