How to Make a Non-Antigenic Protein (Auto) Antigenic: Molecular Complementarity Alters Antigen Processing and Activates Adaptive-Innate Immunity Synergy

Root‐Bernstein, Robert

doi:10.2174/1871520615666150716105057

Cited by 15 publications

(21 citation statements)

References 170 publications

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“…What, then could be the molecular mechanism for the sense-antisense complementarity at the protein/peptide level? Since sense and antisense peptides can interact with each other with increased probability, [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] one can assume the presence of some binding specificity. This specificity was described as "amphipathic recognition" for a hydrophilic-hydrophobic mechanism of sense-antisense peptide binding.…”

Section: Methodsmentioning

confidence: 99%

“…Curiously enough, what seems to be entirely nucleic acid-specific sense-antisense complementarity has found its way into the protein world too. In fact, multiple studies indicated that sense and antisense peptides can interact with each other with increased probability, [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] with the length of known interacting sense-antisense peptides being varied between 4 and 19 amino acids. [17][18][19] Here, the amino acid sequence of a sense peptide is encoded by the nucleotide sequence (read 5 0 !…”

Section: Introductionmentioning

confidence: 99%

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Intrinsic disorder in protein sense‐antisense recognition

Dayhoff

Regenmortel

Uversky

2020

J of Molecular Recognition

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In addition to the well‐established sense‐antisense complementarity abundantly present in the nucleic acid world and serving as a basic principle of the specific double‐helical structure of DNA, production of mRNA, and genetic code‐based biosynthesis of proteins, sense‐antisense complementarity is also present in proteins, where sense and antisense peptides were shown to interact with each other with increased probability. In nucleic acids, sense‐antisense complementarity is achieved via the Watson‐Crick complementarity of the base pairs or nucleotide pairing. In proteins, the complementarity between sense and antisense peptides depends on a specific hydropathic pattern, where codons for hydrophilic and hydrophobic amino acids in a sense peptide are complemented by the codons for hydrophobic and hydrophilic amino acids in its antisense counterpart. We are showing here that in addition to this pattern of the complementary hydrophobicity, sense and antisense peptides are characterized by the complementary order‐disorder patterns and show complementarity in sequence distribution of their disorder‐based interaction sites. We also discuss how this order‐disorder complementarity can be related to protein evolution.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Intrinsic disorder in protein sense‐antisense recognition

Dayhoff

Regenmortel

Uversky

2020

J of Molecular Recognition

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“…Additional examples of enhanced immunogenicity and autoimmunity associated with complementary antigen complexes are reviewed in [ 136 ]. These include a diphtheria toxin-antitoxin (antibody) complex that induces an autoimmune polyneuritis similar to Guillain-Barré syndrome [ 137 , 138 , 139 ], the induction anti-insulin antibodies in type 1 diabetes by an insulin-glucagon complex [ 140 ] and improved antigen presentation to macrophages and dendritic cells by heat shock protein-viral antigen complexes [ 141 ].…”

Section: Toll-like Receptor Activation In Autoimmune Diseasementioning

confidence: 99%

“…In sum, for a number of AD with well-defined animal models and/or molecular targets, including two AD featured here—AM and MS—evidence exists that initiating antigens exhibit complementarity towards each other by binding directly to each other and/or by inducing immune responses that have idiotype–anti-idiotype characteristics. Notably, antigen presenting cells are known to process such antigen complexes differently than are their individual antigenic components (reviewed in [ 136 ]). Antigenic complexes are more stable than their components to proteolytic and oxidative degradation and thus more likely to be perceived by the immune system as antigenic; they are digested into different fragments by the proteasome than are their individual components; and such complexes can be perceived by the immune system as distinctly novel antigens that differ significantly from their individual components [ 136 ].…”

Section: Toll-like Receptor Activation In Autoimmune Diseasementioning

confidence: 99%

Synergistic Activation of Toll-Like and NOD Receptors by Complementary Antigens as Facilitators of Autoimmune Disease: Review, Model and Novel Predictions

Root‐Bernstein

2020

IJMS

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Persistent activation of toll-like receptors (TLR) and nucleotide-binding oligomerization domain-containing proteins (NOD) in the innate immune system is one necessary driver of autoimmune disease (AD), but its mechanism remains obscure. This study compares and contrasts TLR and NOD activation profiles for four AD (autoimmune myocarditis, myasthenia gravis, multiple sclerosis and rheumatoid arthritis) and their animal models. The failure of current AD theories to explain the disparate TLR/NOD profiles in AD is reviewed and a novel model is presented that explains innate immune support of persistent chronic inflammation in terms of unique combinations of complementary AD-specific antigens stimulating synergistic TLRs and/or NODs. The potential explanatory power of the model is explored through testable, novel predictions concerning TLR- and NOD-related AD animal models and therapies.

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“…It is well known that molecules to which the immune system is tolerant can be made antigenic through chemical or physical alteration and that non-antigens can be made antigenic by chemically coupling them to an antigen or hapten (e.g., Landsteiner and van der Scheer, 1936;Eisen, et al, 1952). The formation of complementary antigen complexes can have the same effects (reviewed in Root- Bernstein, 2015).…”

Section: Act Altered Antigen Processing and The Abrogation Of "Self-mentioning

confidence: 99%

<strong>A General Theory of Autoimmune Disease Causation: Integrating Innate and Adaptive Immunity, Altered Antigen Processing, Sex and Genetic Predispositions, and Microbiome Effects</strong>

Root‐Bernstein¹

2019

Preprint

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Current theories of autoimmunity are diverse, sometimes contradictory, and suffer from incompleteness. Although substantial evidence exists that adaptive and innate immunity, sex, genetic predisposition, and the microbiome all play essential roles in autoimmune disease etiologies and pathogenesis, and that antigen processing is altered during disease induction, no existing theory integrates all of these factors through a single, coherent mechanism. In an attempt to focus the field on the need to elucidate such an integrative mechanism, I propose one possibility here that, if nothing else, helps to identify the nature of the problems that need to be addressed. My theory is that autoimmune diseases are induced by normal immunological responses to unique pairs of complementary antigens, at least one of which is a molecular mimic of a host target.  Each antigen in the complementary pair induces a complementary immune response (T or B cell); although each immune response is idiotypic in origin, the antigenic complementarity results in what appears to be an idiotype-anti-idiotype relationship between the responses. Additionally, because of the antigenic complementarity, each immune response mimics one of antigens, abrogating the distinction between self and non-self. If at least one of the antigens mimics a host antigen, then the resulting immunological civil war spreads to a host tissue. Complementary antigens also alter antigen processing so that antigens that would normally be proteolytically digested are presented by the major histocompatibility complex (MHC) to T and B cell receptors inducing a cross-reactive immune response. The resulting civil war is supported by the innate immune system due to the complementarity of the initiating antigens.. Complementary antigens stimulate synergistic toll-like receptors (TLR) and/or nucleotide-binding oligomerization receptors (NOD) resulting in up-regulation of cytokine production and further stimulation of the adaptive immune response. Because the immune responses (e.g., antibodies) mimic the initiating antigens, this synergistic activation of innate immunity becomes chronic. Additionally, TLR and NOD function are highly sensitive to sex hormones, some becoming up-regulated and some down-regulated in the presence of either testosterone or estrogens. This sensitivity explains how sex modifies susceptibility to autoimmune diseases. Genetic mutations in TLR, NOD and MHC further alter antigen presentation and the degree to which antigens stimulate an immune response explaining how genetics also modifies susceptibility. Finally, sex hormones also alter the host microbiome, which in turn modulates autoimmune disease risk by shaping the immunological nature of self and by mediating susceptibility to microbial infection.  Moreover, it appears that the microbiome camouflages itself from the immune system by mimicking the host antigenic repertoire; the mimicry between the antigens of the microbiome and the host results in selective attacks on microbiome constituents concomitant with any autoimmune attack on host tissues. This antigenic complementarity theory thereby integrates all major elements known to affect, or be affected by, autoimmune diseases and provides a set of testable implications.

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How to Make a Non-Antigenic Protein (Auto) Antigenic: Molecular Complementarity Alters Antigen Processing and Activates Adaptive-Innate Immunity Synergy

Cited by 15 publications

References 170 publications

Intrinsic disorder in protein sense‐antisense recognition

Intrinsic disorder in protein sense‐antisense recognition

Synergistic Activation of Toll-Like and NOD Receptors by Complementary Antigens as Facilitators of Autoimmune Disease: Review, Model and Novel Predictions

<strong>A General Theory of Autoimmune Disease Causation: Integrating Innate and Adaptive Immunity, Altered Antigen Processing, Sex and Genetic Predispositions, and Microbiome Effects</strong>

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