Fact-checked by Grok 2 weeks ago

Major histocompatibility complex

The major histocompatibility complex (MHC) is a cluster of tightly linked genes on in humans (known as the or HLA system) that encode highly polymorphic cell-surface glycoproteins crucial for the adaptive . These proteins bind short fragments derived from intracellular or extracellular proteins, including those from pathogens, and present them on the surface of antigen-presenting cells or other nucleated cells to T lymphocytes, enabling the to distinguish self from non-self and mount targeted responses against infections, tumors, and foreign tissues. The term "major histocompatibility complex" originated from studies on tissue transplantation, where MHC molecules were identified as the primary determinants of graft rejection due to their role in allorecognition. MHC molecules are divided into three classes, but classes I and II are the most prominent in . Class I MHC molecules, comprising , HLA-B, and in humans, are expressed constitutively on nearly all nucleated cells and platelets; they primarily present endogenous peptides (typically 8–10 long) generated from cytosolic proteins to + cytotoxic T cells, triggering the elimination of infected or malignant cells. In contrast, class II MHC molecules (, HLA-DQ, and HLA-DP) are mainly expressed on professional antigen-presenting cells such as dendritic cells, macrophages, and B cells; they display exogenous peptides (13–25 ) endocytosed from the extracellular environment to CD4+ helper T cells, which then orchestrate broader immune activation including and . The extraordinary polymorphism of MHC genes—more than 43,000 alleles documented for class I and II loci as of October 2025—ensures population-level diversity in peptide-binding specificities, enhancing resistance to diverse pathogens but also contributing to autoimmune diseases and transplant incompatibility. Beyond antigen presentation, the MHC region encompasses over 200 genes, including those involved in immune regulation, such as complement components, , and cytokines, making it a key genomic hub for immunity and disease susceptibility. Variations in MHC alleles are associated with outcomes in infectious diseases (e.g., progression), autoimmunity (e.g., ), and responses, underscoring their clinical significance. Evolutionary pressures from pathogens have driven MHC diversity, with balancing selection maintaining in many species.

Overview

Definition and general role

The major histocompatibility complex (MHC) is a cluster of genes that encode highly polymorphic cell surface proteins essential for the adaptive immune response. These proteins, known as MHC molecules, bind and present fragments derived from intracellular or extracellular proteins on the surface of antigen-presenting cells and other nucleated cells, enabling recognition by T lymphocytes. The primary role of MHC molecules is to facilitate immune surveillance by distinguishing self-peptides from those derived from pathogens, tumors, or other foreign entities, thereby triggering targeted immune responses while maintaining tolerance to the host's own tissues. This process allows T cells to detect and eliminate infected or abnormal cells, forming a cornerstone of immunity. In humans, the MHC is located on the short arm of and is referred to as the (HLA) complex, encompassing genes that exhibit extensive allelic variation to enhance population-level resistance. Evolutionarily, MHC genes are conserved across all jawed vertebrates, underscoring their fundamental importance in immune function from to mammals.

Nomenclature across species

In humans, the major histocompatibility complex (MHC) is designated as the (HLA) , with class I genes named HLA-A, HLA-B, and HLA-C, while class II genes are designated HLA-DR, HLA-DQ, and HLA-DP. The for HLA alleles follows a standardized format established by the (WHO) Nomenclature for Factors of the HLA , where alleles are denoted as, for example, HLA-A*02:01; the locus name precedes an asterisk, followed by a two-digit group number (indicating serological specificity), a two-digit allele-specific sequence number, and optional additional digits for synonymous mutations or intronic variations. This , updated periodically through reports, ensures unique identification of over 43,000 known alleles as of September 2025, facilitating clinical and research applications in transplantation and disease association studies. In , the MHC is termed H-2, with class I loci designated H-2K, H-2D, and H-2L, and class II loci as I-A and I-E subregions containing paired alpha and beta genes (e.g., H2-Aa/H2-Ab1 for I-A). nomenclature aligns with designations, such as H-2^b for the strain, where specific alleles like or D^b are assigned based on serological and genetic distinctions, coordinated by comparative MHC to maintain consistency across models. This framework supports immunological research in inbred strains, emphasizing variability in immune responses. Non-mammalian species exhibit distinct MHC reflecting evolutionary divergence. In chickens, the primary MHC region is the B locus (also called MHC-B), encompassing class I (BF) and class II (BL) genes within a compact ~92 kb segment, with haplotypes named numerically (e.g., B^2, B^12) based on serological and genetic profiling; a secondary Y locus (Rfp-Y) includes additional class I and II genes denoted similarly (e.g., Y^8). In teleost , such as salmonids, classical class I genes are named UBA (UBA001-like), while class II comprises DAA (alpha) and (beta) pairs, with using prefixes like Sasa- for Salmo salar followed by locus and allele digits (e.g., Sasa-UBA0301); this system, guided by international committees, accounts for dispersed gene organization unlike the linked mammalian clusters. These conventions, harmonized through efforts like the Comparative MHC Committee, enable cross-species comparisons of allelic diversity.

History

Early discoveries

The early investigations into what would later be known as the major histocompatibility complex (MHC) began with studies on in experimental animals. In 1948, Peter Gorer identified a major in mice, designated H-2, through serological analysis of erythrocytes and its association with tumor transplantation outcomes. Gorer's work demonstrated that H-2 acted as a blood group-like that influenced the or of transplanted , establishing a genetic basis for in mice. This discovery highlighted the role of specific loci in governing immune responses to foreign , laying foundational groundwork for understanding . Building on these animal models, researchers extended similar observations to humans during the , focusing on reactions following blood transfusions. Jean Dausset reported the presence of leukocyte-specific antibodies in sera from polytransfused patients, describing the first , initially termed MAC (later identified as HLA-A2), which caused of from approximately 60% of unrelated individuals. Dausset's serological studies revealed that these antigens were inherited in a Mendelian fashion and were distinct from groups, linking them to transfusion-related immune reactions and foreshadowing their importance in human tissue matching. This work paralleled Gorer's findings and confirmed the existence of a comparable system in humans. In the 1960s, Baruj Benacerraf's experiments in uncovered genetic factors controlling to specific , termed immune response (Ir) genes. Using inbred strains, Benacerraf demonstrated that responsiveness to synthetic polypeptides like poly-L-lysine (PLL) was governed by genes linked to loci, with strain 13 mounting strong antibody responses while strain 2 did not, despite equivalent exposure. These Ir genes were shown to map to the MHC equivalent (GPL-A), indicating that molecules influenced the ability to generate adaptive . This genetic linkage bridged with immune regulation, suggesting MHC products played a direct role in -specific immunity. Initial evidence for MHC restriction in T cell responses emerged in 1974 from studies by Rolf Zinkernagel and Peter Doherty, who observed that cytotoxic T cells from virus-infected mice only recognized and killed target cells if they shared the same H-2 haplotype. This finding provided early indication that T cell activation required compatibility between antigen-presenting cells and responders at the MHC level, a precursor to broader understandings of immune recognition. These discoveries collectively established the MHC's central role in transplantation and immunity through mid-20th-century experimentation.

Key conceptual developments

In 1974, Rolf Zinkernagel and Peter Doherty demonstrated that T cell-mediated cytotoxicity against virus-infected cells is restricted by the (MHC), revealing that T cells recognize viral antigens only when presented by MHC molecules matching those on the infected cell surface. This discovery of fundamentally altered understanding of adaptive immunity, showing that T cell specificity depends on both foreign and self-MHC context, and earned them the 1996 Nobel Prize in Physiology or Medicine. During the 1980s, advances in enabled the of MHC genes, allowing precise identification of I and II distinctions at the level. Seminal work isolated the first HLA I cDNA sequences, such as HLA-A2, confirming the polymorphic nature of these genes and their expression patterns. Concurrently, of mouse and II genes, including I-A and HLA-DR loci, elucidated their heterodimeric structure and tissue-specific roles, paving the way for functional studies on pathways. The 1990s brought structural insights through , with the first MHC-peptide-T cell receptor (TCR) complex structures illuminating the molecular basis of recognition. Building on the 1987 HLA-A2 , which revealed a peptide-binding groove formed by α1 and α2 helices, subsequent complexes like HLA-A2 with peptide and TCR demonstrated how anchor in the groove while TCR contacts both MHC and , explaining specificity and . These findings resolved how MHC diversity influences immune surveillance and alloreactivity, influencing design and transplant . Post-2020, (cryo-EM) has advanced visualization of non-classical MHC structures, capturing dynamic complexes previously intractable by crystallography. For instance, cryo-EM structures of co-receptor with non-classical MHC-Ib molecules like have shown unique binding modes that modulate and T cell responses, highlighting roles in and cancer. This technique has integrated with classical studies to reveal conformational flexibility in peptide loading and TCR engagement for non-polymorphic MHCs.

Genetic basis

Gene organization and loci

The human major histocompatibility complex (MHC), designated as the (HLA) complex, resides on the short arm of at cytogenetic band 6p21.3. This genomic segment spans approximately 4 megabases (Mb) and encompasses over 220 genes, many of which contribute to immune function. The HLA complex is structured into three principal regions arrayed linearly from the telomeric to centromeric direction: the class I region, the intervening class III region, and the class II region. This organization reflects evolutionary conservation, with the class I and II regions primarily encoding antigen-presenting molecules, while the class III region houses diverse immune regulators. The class I region, located at the telomeric extremity, contains the classical HLA-A, HLA-B, and loci, which are highly polymorphic and encode transmembrane glycoproteins expressed on nearly all nucleated cells for presenting endogenous peptides to cytotoxic T cells. Adjacent non-classical class I genes, including , HLA-F, and , exhibit lower polymorphism and specialized expression patterns, such as on cells for HLA-G. These loci are clustered within about 1.5 , flanked by framework genes that maintain regional integrity. The class II region, positioned centromerically, spans roughly 1 Mb and includes subregions for , , and HLA-DP heterodimers, each formed by paired alpha and beta chains. The DR subregion features a single HLA-DRA gene and multiple HLA-DRB genes (up to four functional ones per ), enabling diverse DR molecule formation; the DQ subregion comprises HLA-DQA1 and ; and the DP subregion includes HLA-DPA1 and HLA-DPB1. These genes are expressed mainly on antigen-presenting cells like dendritic cells and B cells. Interposed between the class I and II regions, the class III region covers about 0.8 Mb and encodes over 60 genes unrelated to , including complement components , C4A, C4B, and properdin factor B, as well as cytokines like (TNF) and lymphotoxin-alpha. These genes support innate immunity through inflammation and opsonization pathways but do not directly bind or present antigens. In other species, such as the , the MHC equivalent, known as the H-2 complex, occupies chromosome 17 and mirrors the human tripartite layout, with class I loci (H2-K, H2-D, H2-L) telomerically, class III genes centrally (including complement and TNF homologs), and class II loci (I-A and I-E subregions) centromerically. Certain mouse haplotypes display inversions within the class II region, contributing to haplotype diversity and recombination patterns.

Polymorphism and allelic diversity

The major histocompatibility complex (MHC) represents the most polymorphic genetic region in the genomes of s, with thousands of alleles documented across its loci, enabling diverse immune responses to pathogens. In humans, the (HLA) system within the MHC has over 42,996 documented alleles as of the latest IPD-IMGT/HLA Database release in October 2025, encompassing 29,475 class I alleles and 13,521 class II alleles. This extraordinary allelic diversity far exceeds that of other families, reflecting evolutionary pressures to recognize a wide array of antigens. The generation of MHC polymorphism arises primarily through point mutations, gene conversion events, and recombination between paralogous sequences within the MHC region. Point mutations introduce single nucleotide changes in coding regions, particularly in peptide-binding domains, while gene conversion transfers sequence segments from non-expressed pseudogenes to functional loci, homogenizing or diversifying alleles. Recombination, including meiotic crossing-over, further reshuffles haplotypes, contributing to novel combinations. These mechanisms are amplified by balancing selection, where favors the maintenance of multiple alleles in populations to counter pathogen-driven pressures, preventing fixation of any single variant. A key outcome of this polymorphism is the , whereby individuals carrying two different alleles at an MHC locus can bind and present a broader repertoire of peptides to T cells compared to homozygotes, enhancing recognition and immune efficacy. This advantage promotes allelic diversity by increasing survival rates against diverse infections, as evidenced in population genetic models. Population-level differences in MHC allelic frequencies underscore the role of local selection pressures, with certain haplotypes showing adaptive value in specific ethnic groups. For instance, the HLA-B*57 allele is more prevalent in African populations and confers protection against HIV progression by restricting viral replication through targeted peptide presentation. Recent whole-genome sequencing studies from 2023 to 2025 have revealed novel polymorphisms and haplotype structures in Asian populations, such as expanded diversity in Han Chinese MHC regions linked to long-read sequencing data, highlighting regional adaptations to endemic pathogens.

Molecular structure

MHC class I molecules

MHC class I molecules are heterodimeric cell surface proteins composed of a polymorphic heavy chain, also known as the α chain, non-covalently associated with the invariant light chain β2-microglobulin (β2m). The heavy chain consists of three extracellular domains: α1, α2, and α3. The α1 and α2 domains, each comprising approximately 90 , fold into a platform of β-sheets topped by α-helices that form a closed-ended peptide-binding groove. This groove accommodates antigenic peptides derived from intracellular proteins, enabling presentation to + T cells. The α3 domain, structurally similar to an immunoglobulin-like fold, interacts with the coreceptor on T cells, while β2m stabilizes the overall complex and is essential for proper folding and transport to the cell surface. The peptide-binding groove of molecules is tailored to bind short peptides, typically 8-10 in length, with specific motifs determined by anchor residues at positions 2 and the that fit into pockets A and F of the groove, respectively. These anchors provide allele-specific binding specificity, allowing diverse peptides to be presented while ensuring stability of the MHC-peptide complex through hydrogen bonds and van der Waals interactions with conserved residues in the groove. Variations in groove architecture across alleles influence the of bound peptides, contributing to immune against pathogens and tumors. Classical MHC class I molecules in humans, encoded by the HLA-A, HLA-B, and HLA-C genes, are highly polymorphic and expressed constitutively on the surface of nearly all nucleated cells. This broad expression enables these molecules to survey cytosolic proteomes for signs of infection or malignancy, presenting peptides to cytotoxic T lymphocytes for targeted elimination of compromised cells. In contrast, non-classical MHC class I molecules, such as , HLA-F, , and MR1, exhibit limited polymorphism and specialized functions. primarily presents leader peptides from other MHC molecules to inhibit natural killer () cells via CD94/NKG2 receptors, while plays a key immunosuppressive role at the maternal-fetal interface by engaging inhibitory receptors like LILRB1. HLA-F has emerging roles in immune modulation, potentially presenting peptides to γδ T cells or cells. MR1, a monomorphic molecule structurally related to classical MHC class I, uniquely presents small microbial metabolites, such as precursors from bacteria like , to mucosal-associated invariant T (MAIT) cells, linking innate and adaptive immunity at mucosal sites. Recent structural studies have advanced understanding of non-classical MHC class I functions, including cryo-EM analyses of MR1 in complex with antigens and T cell receptors, revealing dynamic conformational changes that facilitate metabolite recognition and immune activation. For instance, high-resolution structures highlight how MR1 accommodates diverse ligands through a flexible binding cleft, distinct from peptide-binding in classical molecules.

MHC class II molecules

MHC class II molecules are heterodimeric glycoproteins composed of non-covalently associated α and β polypeptide chains, each with a molecular weight of approximately 30-35 . The α chain consists of two extracellular domains (α1 and α2), a transmembrane region, and a short cytoplasmic tail, while the β chain has analogous domains (β1 and β2, transmembrane, and cytoplasmic). The membrane-distal α1 and β1 domains form a peptide-binding platform characterized by an open-ended groove, which accommodates antigenic of variable lengths, typically ranging from 13 to 25 . This structural feature contrasts with the closed-ended groove of molecules and enables the presentation of longer peptide fragments derived from extracellular proteins. In humans, classical molecules are encoded by genes at the , HLA-DQ, and HLA-DP loci within the major histocompatibility complex on chromosome 6. Each locus produces distinct α and β chains that pair to form functional heterodimers, with possible combinations (e.g., DRα with DRβ variants) enhancing molecular diversity and the repertoire of presentable peptides. Non-classical variants, such as and HLA-DO, play regulatory roles but do not directly present antigens. Expression of molecules is restricted primarily to professional antigen-presenting cells, including dendritic cells, macrophages, and B lymphocytes, where it is upregulated by interferon-γ to facilitate immune responses. This cell-type specificity ensures coordinated to + T cells. The invariant chain (, also known as CD74) plays a crucial role in the biosynthesis and intracellular trafficking of molecules by associating with the αβ heterodimer in the , occupying the -binding groove to prevent endogenous peptide loading and guiding the complex through the Golgi apparatus to late endosomal compartments.

MHC class III molecules

The major histocompatibility complex (MHC) class III region, located on 6p21 in humans between the class I and class II regions, encompasses a diverse set of genes that encode proteins involved in innate immunity rather than . These genes include those for components, proinflammatory cytokines, and heat shock proteins, contributing to , clearance, and cellular stress responses. Unlike MHC class I and II molecules, class III products do not bind or present peptides to T cells, reflecting their evolutionary divergence from adaptive immune functions. Key complement-related genes in the MHC class III region are , , , and factor B (also known as CFB). and the isotypes ( and ) participate in the classical complement activation pathway, where binds to antibody-antigen complexes and forms the (C4b2a) to initiate opsonization and membrane attack complex assembly. Factor B, in contrast, functions in the alternative pathway by associating with C3b to generate the (C3bBb), amplifying complement responses against microbial surfaces. These genes exhibit polymorphism, with variations in copy number influencing complement efficiency and disease susceptibility. Cytokine genes such as alpha (TNF-α, encoded by TNFA) and (LTA) are also housed in this region, regulating and immune cell recruitment. TNF-α promotes endothelial activation, leukocyte adhesion, and cascades during acute responses, while LTA contributes to lymphoid organ development and T cell-mediated . Polymorphisms in TNFA, notably the -308 G/A variant, are associated with increased TNF-α production and heightened risk for autoimmune conditions such as and systemic lupus erythematosus. Heat shock protein genes, including HSPA1A, HSPA1B, and HSPA1L (encoding family members), lie within the MHC class III region and act as molecular chaperones to maintain under stress conditions like or . These proteins facilitate protein refolding, prevent aggregation, and indirectly support immune responses by stabilizing cellular integrity during . Recent studies highlight the role of copy number variations in neuropsychiatric disorders; for instance, increased copies correlate with elevated C4 protein levels and risk, particularly in males, potentially via enhanced in the brain. This underscores the class III region's broader impact on immune-mediated pathologies beyond classical .

and presentation

Endogenous pathway for class I

The endogenous pathway enables the presentation of peptides derived from cytosolic proteins on molecules, allowing cytotoxic T cells to surveil for intracellular threats such as viral infections or tumorigenesis. Intracellular proteins, including viral proteins and aberrant self-proteins from tumors, undergo ubiquitination in the , marking them for degradation by the 26S complex. This multicatalytic protease generates short peptides, typically 8–11 in length, by cleaving internal bonds while sparing certain residues to produce suitable ligands for binding. The resulting peptides are actively transported across the (ER) membrane by the transporter associated with (TAP), an ATP-binding cassette (ABC) heterodimer composed of TAP1 and TAP2 subunits. TAP preferentially selects peptides with hydrophobic or basic C-terminal residues and appropriate length, ensuring compatibility with pockets. In the ER lumen, these peptides are loaded onto nascent molecules—heterotrimers of a polymorphic heavy chain, β2-microglobulin, and the —within the -loading complex (PLC). The PLC assembles key chaperones, including , which binds N-linked glycans on the heavy chain to stabilize folding; ERp57, which facilitates disulfide bond formation; and tapasin, which tethers to TAP, editing peptides for optimal by promoting of suboptimal ligands. Quality control in the ER involves further peptide optimization and complex stability assessment. Endoplasmic reticulum aminopeptidase 1 (ERAP1) trims extended peptides (longer than 9–10 residues) from the , generating ligands that fit precisely into the binding groove and enhance thermodynamic stability. Unstable -peptide complexes are retained in the ER by interactions with or tapasin; those failing quality checks undergo retrotranslocation to the via the Sec61 translocon and subsequent ubiquitination and proteasomal through ER-associated (ERAD), preventing surface expression of empty or low-affinity molecules. Studies have shown that can generate neoantigens presented by molecules and that splice variants of processing components like tapasin can affect antigen loading efficiency, modulating presentation repertoires in disease contexts.

Exogenous pathway for class II

The exogenous pathway for molecules primarily handles antigens derived from extracellular sources, such as pathogens or allergens, enabling their presentation to + T cells. Extracellular antigens are internalized by professional antigen-presenting cells (APCs), including dendritic cells, macrophages, and B cells, through or macropinocytosis into early endosomal vesicles. These vesicles mature into late endosomes and fuse with lysosomes, where the acidic environment facilitates degradation of the antigens by lysosomal proteases, particularly such as cathepsin S, which cleaves proteins into of 13-25 suitable for binding. S plays a critical non-redundant role in this process, as its inhibition impairs peptide generation and subsequent . Newly synthesized MHC class II αβ heterodimers in the endoplasmic reticulum associate with the invariant chain (Ii, also known as CD74), a chaperone protein that prevents premature peptide binding in the peptide-binding groove and directs the complex to endosomal compartments via dileucine sorting motifs in Ii's cytoplasmic tail. In the MHC class II compartment (MIIC), a specialized late endosomal/lysosomal structure enriched in MHC class II, Ii undergoes sequential proteolytic degradation by cathepsins, first to a trimeric p22 fragment and then to the class II-associated invariant chain peptide (CLIP), which remains bound in the peptide groove. The non-classical MHC class II molecule HLA-DM then catalyzes the removal of CLIP and facilitates the exchange for higher-affinity antigenic peptides, ensuring the selection of stable complexes through peptide editing that favors immunodominant epitopes. In certain APCs, such as B cells and thymic epithelial cells, HLA-DO acts as a modulator of activity, inhibiting its peptide exchange function to promote the loading of low-affinity peptides and diversify the presented repertoire, thereby influencing and response specificity. The resulting MHC class II-peptide complexes are transported to the cell surface via recycling endosomes for recognition by + T cells. has shown that lipid rafts, cholesterol- and sphingolipid-enriched membrane microdomains, facilitate trafficking and concentration during , enhancing efficiency by promoting interactions with accessory molecules.

Cross-presentation mechanisms

Cross-presentation is a specialized process primarily carried out by dendritic cells (DCs), enabling the presentation of exogenous antigens on major histocompatibility complex (MHC) class I molecules to activate CD8+ T cells, thereby bridging innate and adaptive immunity. DCs initiate this by phagocytosing extracellular material, such as apoptotic cells, viral particles, or tumor debris, which is internalized into phagosomes. This mechanism is crucial for initiating immune responses against pathogens and tumors that do not directly infect antigen-presenting cells. Two primary routes facilitate : the cytosolic pathway and the vacuolar pathway. In the cytosolic route, phagocytosed antigens are exported from endosomal compartments into the , where they are degraded by proteasomes into peptides; these peptides are then transported back into the (ER) or phagosomes via the transporter associated with (TAP) for loading onto molecules. A key feature of this pathway involves ER-phagosome , mediated by SNARE proteins like Sec22b, which recruits ER components including TAP and to the phagosome membrane, allowing efficient peptide loading. In contrast, the vacuolar route processes antigens entirely within endosomal or phagosomal compartments using endosomal proteases like cathepsins, generating peptides that bind to recycling molecules without cytosolic involvement. Both pathways are specialized in certain DC subsets, such as XCR1+ conventional DCs, which excel in cytosolic for robust CD8+ T cell priming. Several regulators fine-tune cross-presentation efficiency. The Sec61 translocon, typically involved in ER protein translocation, facilitates antigen export from endosomes to the cytosol in the cytosolic pathway, as demonstrated by inhibition studies showing reduced cross-presentation upon Sec61 blockade. Immunity-related GTPase (IRG) proteins, such as Irga6, promote phagosome maturation and recruit TAP to pathogen-containing vacuoles, enhancing antigen processing during infections like those by . Inhibitory signals, including PD-L1 expression on DCs, can attenuate cross-presentation by dampening T cell activation during , providing a feedback mechanism to prevent excessive . Cross-presentation plays a pivotal role in anti-viral and anti-tumor immunity by enabling + T cell responses to extracellular threats. For instance, it is essential for clearing virus-infected cells that release antigens without direct infection and for mounting cytotoxic responses against tumors. In the tumor microenvironment, enhanced cross-presentation by has been shown to improve CAR-T cell efficacy; recent research indicates that using irradiation to boost recruitment and cross-presentation of tumor antigens accelerates CAR-T persistence and anti-tumor activity in solid tumors.

Immune cell recognition

T lymphocyte restrictions

T lymphocyte recognition of antigens is fundamentally restricted by major histocompatibility complex (MHC) molecules, a first demonstrated in experiments showing that cytotoxic T cells respond to antigens only when presented by MHC molecules matching those of the infected cell. This ensures that T cells interact specifically with self-MHC presenting foreign peptides, forming peptide-MHC (pMHC) complexes recognized by the (TCR). CD8+ T cells, primarily cytotoxic, recognize antigens presented by molecules, while CD4+ helper T cells recognize those presented by molecules. The association of CD8+ T cells with restriction was established through studies on virus-specific , confirming that effector function requires matching alleles between target and effector cells. Similarly, the restriction for helper T cells was shown in assays where T cell activation by antigen-pulsed macrophages required histocompatibility at loci. These coreceptor-MHC pairings enhance TCR avidity and during recognition. Thymic education imposes MHC specificity on developing T cells through positive and negative selection processes. Positive selection occurs in the thymic , where double-positive (CD4+ CD8+) thymocytes with TCRs capable of low-affinity binding to self-pMHC survive and differentiate into single-positive T cells matched to either (CD8+) or class II (CD4+), ensuring a repertoire restricted to self-MHC. Negative selection in the thymic medulla eliminates thymocytes with high-affinity binding to self-pMHC, preventing while further refining . These selection mechanisms, dependent on thymic epithelial and dendritic cells presenting self-peptides, shape a functional T cell pool tolerant to self yet responsive to foreign antigens in the context of self-MHC. In transplantation, T cells exhibit alloreactivity, directly recognizing foreign MHC molecules on donor cells without requiring peptide specificity, leading to rapid graft rejection. This direct allorecognition arises because many TCRs cross-react with allogeneic pMHC complexes, mimicking self-pMHC interactions but with altered peptide contributions. Recent single-cell RNA sequencing analyses of T cell repertoires have revealed that MHC heterozygosity reduces TCR clonal diversity compared to homozygosity, as increased negative selection pressures limit the pool of viable clones, influencing alloreactive potential in diverse genetic contexts.

Natural killer cell interactions

Natural killer (NK) cells interact with major histocompatibility complex (MHC) class I molecules primarily through a balance of inhibitory and activating receptors, enabling them to distinguish healthy cells from those that are stressed, infected, or malignant. This regulation prevents inappropriate cytotoxicity against self-tissues while allowing NK cells to target cells with altered MHC expression. The "missing self" hypothesis posits that NK cells are licensed to kill target cells lacking sufficient self-MHC class I expression, as this absence removes inhibitory signals that normally restrain NK activity. Inhibitory killer-cell immunoglobulin-like receptors (KIRs) on cells, such as KIR2DL1, bind specific HLA class I alleles (e.g., group 2 epitopes) to deliver negative signals via immunoreceptor tyrosine-based inhibitory motifs (ITIMs), thereby suppressing cell-mediated killing of healthy cells. This interaction ensures self-tolerance, as cells expressing KIRs specific for self-HLA ligands undergo education during development to become functionally competent. Loss or downregulation of on target cells, common in viral infections or tumors, disrupts these inhibitory contacts, permitting activation and . Complementing inhibitory pathways, activating receptors like recognize stress-induced, MHC class I-like ligands such as and MICB, which are upregulated on transformed or infected cells but absent on normal tissues. engagement triggers NK cell degranulation and release, promoting independent of MHC class I downregulation. These ligands, structurally related to but lacking peptide-binding grooves for classical , serve as danger signals to override inhibitory KIR signals in pathological contexts. Non-classical MHC class I molecules like further modulate responses through interaction with the CD94/NKG2A heterodimeric receptor, which delivers potent inhibition upon binding HLA-E loaded with signal sequence-derived from other MHC class I proteins. This pathway monitors MHC class I , as reduced HLA-E surface expression due to impaired supply signals cellular , licensing NK attack. Crystal structures reveal that CD94/NKG2A contacts both the HLA-E α-helices and , with subtle peptide variations influencing binding affinity and inhibitory strength. In clinical settings, KIR-HLA mismatches enhance NK alloreactivity in haploidentical (HSCT), where donor NK cells lacking inhibitory KIR ligands for recipient HLA class I can mediate graft-versus-leukemia effects without exacerbating . Landmark studies showed that such mismatches in (AML) patients yield superior event-free survival (e.g., 67% at 2 years versus 18% in matched cases) due to selective antileukemic activity. Recent analyses confirm improved overall survival in post-transplant cyclophosphamide-based haplo-HSCT protocols. As of 2025, advances in cell therapy for AML increasingly incorporate KIR-HLA considerations to optimize adoptive transfer efficacy. Ex vivo-expanded, KIR-mismatched cells infused post-HSCT demonstrate enhanced persistence and antileukemic potency without significant toxicity, as shown in small pilot studies. Strategies such as blocking NKG2A or inhibitory KIRs amplify responses against HLA-E-expressing AML blasts, addressing tumor escape mechanisms in ongoing chimeric receptor ()-NK trials. Systematic reviews of cell-based clinical trials in AML emphasize donor selection based on KIR haplotypes to enhance therapeutic potential.

Clinical significance

Role in transplantation

The major histocompatibility complex (MHC), known as (HLA) in humans, plays a central role in transplant immunology by serving as the primary target for immune rejection of allogeneic grafts. Mismatches in MHC molecules between donor and recipient trigger robust T-cell responses, leading to graft failure if not adequately managed. This incompatibility arises due to the high polymorphism of MHC genes, which generates diverse peptide-MHC complexes recognized as foreign by the recipient's immune system. Transplant rejection is mediated through two main pathways of allorecognition: direct and indirect. In direct allorecognition, recipient T cells directly recognize intact foreign MHC molecules on donor antigen-presenting cells (APCs), which is predominant in acute rejection episodes occurring within days to weeks post-transplant. This pathway activates CD4+ and CD8+ T cells, leading to cytotoxic damage and inflammation in the graft. Indirect allorecognition involves recipient APCs processing and presenting donor MHC-derived peptides via self-MHC molecules to T cells, contributing to both acute and chronic rejection by sustaining long-term immune responses, including antibody production and fibrosis. Acute rejection is typically cellular and reversible with immunosuppression, while chronic rejection manifests as progressive vascular and interstitial damage, often irreversible and driven by ongoing indirect responses. To minimize rejection risk, histocompatibility testing via HLA typing is essential for donor-recipient matching. Traditional serological methods use complement-dependent cytotoxicity to detect HLA antigens with antisera, though they are limited by resolution and availability of typing sera. Molecular techniques have largely replaced serology: polymerase chain reaction-sequence-specific oligonucleotide probing (PCR-SSOP) identifies HLA alleles by hybridizing probes to amplified DNA, offering intermediate resolution; polymerase chain reaction-sequence-specific primers (PCR-SSP) provides rapid allele-specific amplification; and next-generation sequencing (NGS) delivers high-resolution typing of full HLA genes, enabling precise mismatch assessment even at the protein level. Matching prioritizes HLA-A, -B, and -DR loci, as mismatches here correlate strongly with rejection; for example, zero-mismatch kidneys show superior long-term survival compared to those with 4-6 mismatches. Beyond HLA, ABO blood group incompatibility and minor histocompatibility antigens (mHAs) contribute to rejection. ABO mismatches provoke hyperacute rejection via preformed isohemagglutinins binding vascular , while mHAs—peptides from polymorphic non-MHC genes presented by shared HLA—elicit chronic allograft vasculopathy and in HLA-matched transplants, particularly in . Desensitization protocols address these barriers through to remove antibodies, intravenous immunoglobulin to neutralize remaining alloantibodies, rituximab to deplete B cells, and intensified , enabling successful ABO-incompatible or highly sensitized HLA-mismatched transplants with graft survival rates approaching 90% at 5 years. Recent advancements include the use of eculizumab, a complement C5 inhibitor, in sensitized kidney transplant recipients to prevent antibody-mediated rejection. A 2022 randomized trial showed eculizumab reduced acute antibody-mediated rejection compared to standard care in high-risk patients with donor-specific antibodies.

Associations with diseases

The major histocompatibility complex (MHC), particularly human leukocyte antigen (HLA) alleles, plays a critical role in disease susceptibility through its influence on immune recognition and response. In autoimmune diseases, specific HLA class II alleles predispose individuals to aberrant T-cell activation against self-antigens. For instance, HLA-DR4 (encoded by HLA-DRB1*04 alleles) is strongly associated with rheumatoid arthritis (RA), where it presents arthritogenic peptides such as those from collagen II, leading to chronic synovial inflammation. This association arises from the "shared epitope" motif in the DRB1 third hypervariable region, which enhances peptide binding and T-cell repertoire selection biased toward autoimmunity. Similarly, HLA-B27 confers high risk for ankylosing spondylitis (AS), an inflammatory spondyloarthropathy, by facilitating molecular mimicry between self-peptides and bacterial antigens from pathogens like Klebsiella pneumoniae, triggering cross-reactive CD8+ T-cell responses at entheseal sites. Additional mechanisms include HLA-B27's misfolding and endoplasmic reticulum stress, which promote pro-inflammatory cytokine release, and arthritogenic peptide editing that alters MHC groove occupancy to favor autoreactive epitopes. HLA-DR3 and HLA-DR4 are strongly associated with type 1 diabetes, presenting islet autoantigens and contributing to beta-cell destruction. HLA-Cw6 is linked to psoriasis, influencing susceptibility to skin inflammation via antigen presentation to T cells. In infectious diseases, certain HLA alleles confer protection by optimizing antiviral T-cell responses. HLA-B57 restricts HIV-1 replication effectively, slowing disease progression in carriers by eliciting strong CD8+ T-cell responses against conserved viral epitopes like TW10 in , which limits viral escape and maintains low viral loads over years. This protective effect is most pronounced in chronic phases, where HLA-B57-positive individuals exhibit delayed + T-cell decline compared to other genotypes. For (HBV), HLA-DRB113:02 protects against chronic infection by enhancing + T-cell recognition of and antigens, promoting viral clearance through robust Th1 responses and production. Population studies confirm that DRB113:02 carriers have up to 80% lower risk of persistent HBV compared to non-carriers, underscoring its role in spontaneous resolution. In cancer, MHC dysregulation enables immune evasion, with HLA class I loss being a prevalent mechanism across tumor types. Somatic (LOH) in HLA genes occurs in 20-40% of tumors, reducing to cytotoxic T cells and allowing outgrowth of non-immunogenic clones, as observed in , colorectal, and cancers. This evasion is compounded by beta-2-microglobulin or TAP transporter defects, which impair MHC assembly and surface expression. Checkpoint inhibitors targeting PD-1 restore MHC-TCR interactions by blocking inhibitory signals on , reactivating exhausted + T cells to recognize presented neoantigens and induce tumor regression in responsive malignancies like and non-small cell . Clinical trials demonstrate that PD-1 blockade efficacy correlates with high , which generates diverse MHC-bound neoantigens for TCR engagement. Recent research highlights MHC-microbiome interactions in celiac disease, a gluten-related disorder, where strongly predisposes to pathogenesis. preferentially binds gluten-derived deamidated , driving gluten-specific CD4+ T-cell responses that cause villous atrophy, while gut amplifies this through altered microbial antigens that mimic and enhance MHC loading. Concurrently, advances in neoantigen leverage MHC prediction algorithms, such as AI-enhanced tools like NetMHCpan-4.1 derivatives, to identify patient-specific tumor epitopes with >90% binding affinity accuracy, enabling personalized mRNA or that boost MHC-TCR and elicit durable antitumor immunity in phase II trials for and . These algorithms integrate multi-omics data to prioritize immunogenic neoantigens, addressing HLA heterogeneity for broader applicability.

Evolutionary and additional roles

Origins and diversity

The major histocompatibility complex (MHC) genes trace their origins to the emergence of jawed vertebrates approximately 500 million years ago, arising through gene duplications from ancestral immune recognition molecules that laid the foundation for the . This evolutionary event, documented in comparative analyses of vertebrate genomes, marked the first appearance of and class II genes, which are absent in jawless vertebrates like lampreys and , underscoring the MHC's role as a hallmark of adaptive immunity in gnathostomes. Seminal studies on and bony MHC loci have revealed that these duplications likely occurred in tandem with the recombination-activating genes (/RAG2), enabling somatic diversification of receptors. Across vertebrates, the peptide-binding cores of and class II molecules exhibit remarkable structural conservation, from fish to mammals including humans, preserving the alpha-helical and beta-sheet architecture essential for to T cells. This conservation is evident in sequence alignments showing over 40% identity in key domains across distant taxa, facilitating consistent interactions with invariant chains and transporters like . In contrast, MHC class III genes, which encode complement components and inflammatory mediators rather than antigen-presenting proteins, display higher variability in gene content and organization, reflecting their diverse roles in innate immunity that have undergone more lineage-specific . The high polymorphism of MHC genes, with thousands of alleles per locus in many species, is primarily shaped by pathogen-driven balancing selection. confers fitness benefits by allowing individuals to present a wider array of pathogen-derived peptides, reducing susceptibility to specific infections as demonstrated in models of host-parasite . Complementing this, negative favors rare alleles, as pathogens evolve to evade common MHC variants, thereby maintaining over generations—a mechanism supported by empirical data from viral and bacterial challenge studies in and . These selective pressures explain the MHC's status as one of the most polymorphic regions in genomes. Recent in 2024 has highlighted MHC adaptations in , Chiroptera, where lineage-specific expansions and structural modifications in class I genes enhance peptide-binding diversity and complex stability, contributing to their renowned tolerance of viral pathogens like coronaviruses. For instance, insertions in bat MHC-I molecules increase thermal stability and broaden the repertoire of bound epitopes, adaptations likely selected for in response to frequent viral exposures in this order. Such findings from high-resolution bat genome assemblies underscore how MHC continues to respond to ecological pressures in mammalian radiations.

Involvement in mate selection

The major histocompatibility complex (MHC) influences mate selection through olfactory cues, promoting where individuals prefer partners with dissimilar MHC genotypes to enhance offspring immune diversity. This phenomenon, known as MHC-dependent mate preference (MHCD), is mediated by body odors that reflect MHC variation, allowing potential mates to subconsciously assess genetic compatibility. In , early studies using H-2 congenic strains demonstrated that females preferentially mate with males differing at the H-2 locus (the mouse equivalent of MHC), as males exposed to urine from MHC-dissimilar females spent more time investigating them compared to MHC-similar ones. This preference persists even when visual and auditory cues are controlled, indicating an olfaction-based mechanism that avoids while maximizing heterozygosity. Human evidence similarly points to HLA (human MHC) dissimilarity affecting odor attractiveness, as shown in the seminal "sweaty T-shirt" experiment where women rated the of men with dissimilar HLA types as more pleasant and intense, particularly if not using oral contraceptives. Twin studies further support a genetic basis, with monozygotic twins showing greater concordance in odor preferences for HLA-dissimilar scents than dizygotic twins, suggesting beyond shared environment. Cultural factors, such as contraceptive use, can modulate these preferences, potentially leading to attraction to HLA-similar odors under certain conditions. Genome-wide association studies (GWAS) in diverse populations, including large cohorts from and , have provided evidence linking MHC variation to partner choice, revealing subtle disassortative patterns that counter earlier contradictory findings from smaller samples and highlight the role of MHC in promoting despite social influences. A meta-analysis of human studies confirms a significant, albeit small, for MHC-dissimilar mates, consistent across , , and actual data. However, some genomic analyses of couples have found no significant MHC effect on , indicating ongoing debate in the field.

References

  1. [1]
    Major histocompatibility complex: Antigen processing and presentation
    The major Histocompatibility complex (MHC) system known as the human leukocyte antigen (HLA) in humans is located on the short arm of chromosome 6 (6p21.3)
  2. [2]
    The major histocompatibility complex and its functions - NCBI - NIH
    The function of MHC molecules is to bind peptide fragments derived from pathogens and display them on the cell surface for recognition by the appropriate T ...5-9. Many proteins involved in... · 5-10. A variety of genes with...
  3. [3]
    [PDF] Significance of the MHC
    - The term “Major Histocompatibility Complex” actually refers to a region of the genome that encodes a number of genes (hence Complex) that play an important ( ...
  4. [4]
    Major Histocompatibility Complex (MHC) Class I and MHC Class II ...
    Mar 17, 2017 · Major histocompatibility complex (MHC) class I and class II proteins play a pivotal role in the adaptive branch of the immune system. Both ...<|control11|><|separator|>
  5. [5]
    Physiology, MHC Class I - StatPearls - NCBI Bookshelf
    Sep 26, 2022 · Major histocompatibility complex (MHC) class I is a diverse set of cell surface receptors expressed on all nucleated cells in the body and platelets.Physiology, Mhc Class I · Related Testing · Clinical Significance
  6. [6]
    Molecular Characteristics, Functional Definitions, and Regulatory ...
    Dec 22, 2023 · The major histocompatibility complexes of vertebrates play a key role in the immune response. Antigen-presenting cells are loaded on MHC I ...
  7. [7]
    The evolutionary ecology of the major histocompatibility complex
    Aug 10, 2005 · The primary role of the MHC is to recognise foreign proteins, present them to specialist immune cells and initiate an immune response (Klein, ...
  8. [8]
    Genetics, Histocompatibility Antigen - StatPearls - NCBI Bookshelf
    ... MHC molecule. A major histocompatibility complex is a set of genes that code these MHC molecules/HLA antigens. Multiple genes code for different parts of ...Introduction · Development · Biochemical · MechanismMissing: general | Show results with:general
  9. [9]
    Genetics, Human Major Histocompatibility Complex (MHC) - NCBI
    Aug 14, 2023 · HLA complex is known to be highly polygenic as it is composed of many genes, which can divide broadly into three categories: Class I, Class II, and Class III.Missing: general | Show results with:general
  10. [10]
    Major Histocompatibility Complex (MHC) Markers in Conservation ...
    MHC genes, found in all jawed vertebrates, are the most polymorphic genes in vertebrate genomes. They play key roles in immune function via immune-recognition ...
  11. [11]
    IPD-IMGT/HLA Database
    The IPD-IMGT/HLA Database provides a specialist database for sequences of the human major histocompatibility complex (MHC) and includes the official sequences.Allele Query Tool · Sequence Alignment Tool · IPD-MHC · Download
  12. [12]
    Nomenclature report on the major histocompatibility complex, genes ...
    In humans, the MHC is designated as human leucocyte antigen (HLA), and the Nomenclature Committee for the Factors of the HLA system has recently launched an ...
  13. [13]
    Naming Alleles - HLA Nomenclature
    Each HLA allele name has a unique number corresponding to up to four sets of digits separated by colons. The length of the allele designation is dependent on ...Missing: rules MHC
  14. [14]
    Nomenclature Committee - IPD-MHC Database
    The Comparative Major Histocompatibility Complex (MHC) Nomenclature Committee seeks to provide a guiding framework for allelic nomenclature across all non-human ...
  15. [15]
    [PDF] Naming HLA diversity: A review of HLA nomenclature
    This review covers the major steps in the development of the HLA nomenclature as well as the efforts of other groups to extend its usefulness for research and.
  16. [16]
    Mouse (Mus musculus) MHC H2 - IMGT Repertoire (MH)
    Feb 8, 2002 · Mouse (Mus musculus) H2 genes are located on chromosome 17 (18.40-20.05 cM). They are listed by alphabetic order.
  17. [17]
    [PDF] Mouse Haplotype Table - Thermo Fisher Scientific
    Mouse Haplotype Table. MHC Class I. MHC Class II. MHC Class Ib. Mouse Strains. MHC Haplotype. H-2K. H-2D. H-2L. I-A. I-E. Qa-2. Qa-1. CD45 (Ly-5) Thy-1 (CD90) ...
  18. [18]
    Major histocompatibility complex (Mhc) class Ib gene duplications ...
    The Mhc genomic region in the mouse, located on chromosome 17, is named H2 and the genes within this region are usually classified into three distinct classes ( ...<|separator|>
  19. [19]
    2004 Nomenclature for the chicken major histocompatibility (B and Y ...
    A nomenclature for B and Y (Rfp-Y) loci and alleles has been developed that can be applied to existing and newly defined haplotypes including recombinants.
  20. [20]
    [PDF] Comparative MHC nomenclature: report from the ISAG/IUIS-VIC ...
    Jul 24, 2018 · Originally, serology was used to define 24 B haplotypes in egg-laying chickens; alleles within these haplotypes were giv- en names based on the ...
  21. [21]
    IPD-MHC Database - EMBL-EBI
    Atlantic salmon and rainbow trout possess a single classical MHC class I locus, UBA, and a single classical MHC class II molecule encoded by closely linked DAA ...
  22. [22]
    MHC and Evolution in Teleosts - PMC - NIH
    Jan 19, 2016 · The teleost MHCII nomenclature uses D or duo for the second class, followed by a letter referring to family, and finally a letter for the ...
  23. [23]
    Studies on the genetic and antigenic basis of tumour transplantation ...
    With the A strain it was shown that the gene was identical with that for antigen II present in the erythrocytes. The gene is therefore labelled H2. Of sixty- ...
  24. [24]
    Restriction of in vitro T cell-mediated cytotoxicity in lymphocytic ...
    Apr 19, 1974 · R. M. ZINKERNAGEL &; P. C. DOHERTY. Nature volume 248, pages 701–702 (1974)Cite this article. 10k Accesses. 1842 Citations. 43 Altmetric.Missing: MHC | Show results with:MHC
  25. [25]
    Structure, function, and immunomodulation of the CD8 co-receptor
    Aug 26, 2024 · We describe the molecular interactions of CD8 with classical MHC-I, non-classical MHCs, and Lck partners involved in T cell signaling.
  26. [26]
    Human leukocyte antigen super-locus: nexus of genomic ... - Nature
    Dec 21, 2022 · The human Major Histocompatibility Complex (MHC) on the short arm of chromosome 6 (band p21.3) is a Human Leukocyte Antigen (HLA) super-locus ...
  27. [27]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC11381289/
  28. [28]
    The HLA genomic loci map: expression, interaction, diversity and ...
    Jan 9, 2009 · The non-classical HLA class I genes are differentiated from the classical class I genes on the basis that they have limited polymorphism; the ...
  29. [29]
    Chromosomal organization of the human major histocompatibility ...
    Feb 1, 1989 · ... HLA-G and HLA-F, are located on the short arm of chromosome 6 telomeric to the HLA-A locus. The third expressed non-A, -B, and -C class I gene, ...
  30. [30]
    Type 1 Diabetes and the HLA Region: Genetic Association Besides ...
    No significant associations were observed with HLA class I genes. Table 1. List of the 26 genes found to be associated with T1D, sorted by p-value of the ...<|separator|>
  31. [31]
    Class II Gene - an overview | ScienceDirect Topics
    The class II genes encoding α and β chains are termed A and B (for example, HLA-DQA1, HLA-DQB1) and comprise five and six exons, respectively.
  32. [32]
    Genetic organization of the human MHC class III region - PubMed
    Aug 1, 2001 · The MHC has now been entirely sequenced and ~220 genes have been defined of which ~62 are in the class III region. It is becoming clear that ...
  33. [33]
    Evolution and comparative analysis of the MHC Class III ...
    Nov 2, 2006 · Seven genes within the human Class III region, from MIC to SKI2W and including the tumour necrosis factor family, are thought to be involved in ...
  34. [34]
    Major Histocompatibility Complex (MHC): Mouse
    Jun 15, 2015 · The major histocompatibility complex (MHC) of the mouse, which is called the H2 complex, is located on chromosome 17. It contains genes critical to the ...
  35. [35]
    Major histocompatibility complex (Mhc) class Ib gene duplications ...
    Apr 17, 2008 · Duplicated Mhc class Ib genes located in the H2-Q, -T and -M regions are differentially expressed in a variety of developing and adult tissues.<|separator|>
  36. [36]
    Major histocompatibility complex (MHC) class I and class II proteins
    The major histocompatibility complex (MHC) loci are amongst the most polymorphic regions in the genomes of vertebrates. In the human population, thousands of ...<|control11|><|separator|>
  37. [37]
    Statistics - IPD-IMGT/HLA Database
    Numbers of HLA Alleles. HLA class I alleles, 29475. HLA class II alleles, 13521. HLA alleles, 42996. Other non-HLA alleles, 1032. Number of confidential alleles ...
  38. [38]
    The evolution of MHC diversity: Evidence of intralocus gene ...
    Apr 10, 2012 · The diversity of these genes is thought to be generated by different mechanisms including point mutation, gene conversion and crossing-over.
  39. [39]
    Ancestral polymorphism at the major histocompatibility complex ...
    Aug 15, 2012 · MHC variation is also governed by gene conversion, where homologous recombination occurs between duplicated genes (paralogous genes), thus ...
  40. [40]
    Contrasting evolutionary histories of MHC class I and class II loci in ...
    Feb 10, 2016 · MHC haplotypes may arise via meiotic reciprocal recombination (crossing over) or gene conversion, and the latter process is thought to explain ...
  41. [41]
    How pathogens drive genetic diversity: MHC, mechanisms and ...
    Major histocompatibility complex (MHC) genes have been put forward as a model for studying how genetic diversity is maintained in wild populations.
  42. [42]
    Advances in the Evolutionary Understanding of MHC Polymorphism
    Oct 25, 2019 · Heterozygote advantage (HA) Because each MHC molecular variant is able to present only a limited repertoire of antigens to T cells, being ...
  43. [43]
    Divergent Allele Advantage at Human MHC Genes - NIH
    Heterozygous individuals at MHC loci are assumed to present a broader range of pathogen-derived peptides than homozygotes, thus increasing the probability of ...
  44. [44]
    Protective HLA-B57: T cell and natural killer cell recognition in HIV ...
    Sep 16, 2022 · HLA-B*57:01 and HLA-B*57:03 have been associated with HIV control in Caucasian and African patients, respectively [25–27]. Both allomorphs are ...
  45. [45]
    Long-read sequencing reveals novel genetic polymorphisms in the ...
    Jan 13, 2025 · Long-read sequencing reveals novel genetic polymorphisms in the major histocompatibility complex region and their impacts on the Han Chinese ...
  46. [46]
    Structural Comparison Between MHC Classes I and II - Frontiers
    Jun 13, 2021 · In MHC-I structures, a heavy chain (HC) comprising the two membrane-distal domains (I-α1 and I-α2), a membrane-proximal IgSF domain (I-α3), and ...
  47. [47]
    The pockets guide to HLA class I molecules - Portland Press
    Sep 28, 2021 · HLA-I molecules possess six distinct binding pockets within the binding cleft termed as pockets A–F [9] (Figure 1), which allow peptide residue ...
  48. [48]
    MR1 antigen presentation to mucosal-associated invariant T cells ...
    May 19, 2009 · MR1 is a novel class Ib molecule with properties highly suggestive of its regulation of mucosal immunity. The Mr1 gene is evolutionarily ...
  49. [49]
    CD8 coreceptor engagement of MR1 enhances antigen ...
    Aug 26, 2022 · CD8 coreceptor engagement of MR1 enhances antigen responsiveness by human MAIT and other MR1-reactive T cells.
  50. [50]
    Covering All the Bases: Complementary MR1 Antigen Presentation ...
    Sep 1, 2020 · Here, we review recent developments and new insights into the cellular mechanisms of MR1-dependent antigen presentation with a focus on microbial MR1T cell ...
  51. [51]
    Three-dimensional structure of the human class II histocompatibility ...
    A dimer of the class II αβ heterodimers is seen in the crystal forms of HLA-DR1, suggesting class II HLA dimerization as a mechanism for ...
  52. [52]
    Crystal structure of the human class II MHC protein HLA-DR1 ...
    Mar 17, 1994 · Crystal structure of the human class II MHC protein HLA-DR1 complexed with an influenza virus peptide. Lawrence J. Stern,; Jerry H. Brown, ...
  53. [53]
    MHC class II - Latest research and news - Nature
    MHC class II molecules are expressed by the professional antigen-presenting cells (APCs) of the immune system. APCs use MHC class II molecules to provide CD4- ...
  54. [54]
    Expression of the MHC class III genes - PubMed
    The second (C2) and fourth (C4) components of complement and factor B (B) are coded for by genes within the major histocompatibility complex (MHC).
  55. [55]
    A molecular map of the human major histocompatibility complex ...
    Jan 19, 1984 · The C2 and factor B genes, less than 2 kb apart, are about 30 kb from two C4 genes separated from each other by about 10 kb. You have full ...
  56. [56]
    Complement Genetic Feature - Sino Biological
    Three components, factor B, C2 and C4 (with 2 isotypes), are coded by polymorphic HLA-linked genes and are sometimes referred to as MHC class III antigens ...
  57. [57]
    MHC-linked class III genes. Analysis of C4 gene frequencies ...
    The class III complement components, C4, C2 and factor B (BF), are encoded in the human major histocompatibility complex (MHC). The two genes determining C4 ...
  58. [58]
    Genetic Sophistication of Human Complement Components C4A ...
    A molecular map of the human major histocompatibility complex class III region linking complement genes C4, C2 and factor B. Nature. 1984; 307:237-241.
  59. [59]
    Genes of the Class II and Class III Major Histocompatibility Complex ...
    The genes encoding TNF-α and lymphotoxin (LT)—α (TNFA and LTA, respectively) are located within the MHC class III region on chromosome 6, which lies ∼1 Mb ...Abstract · Materials and Methods · Results · Discussion
  60. [60]
    Tumour necrosis factor and lymphotoxin genes map close to H–2D ...
    Jan 15, 1987 · Tumour necrosis factor (TNF-α) and lymphotoxin (TNF-β) are related proteins, secreted by macrophages and lymphocytes respectively, ...Author Information · About This Article · Cite This ArticleMissing: cytokines | Show results with:cytokines
  61. [61]
    Effects of a polymorphism in the human tumor necrosis factor α ...
    These results show that this polymorphism has direct effects on TNFα gene regulation and may be responsible for the association of TNF2 with high TNFα phenotype ...
  62. [62]
    Polymorphisms of the tumor necrosis factor alpha locus among ...
    Jul 26, 2001 · Polymorphisms, influencing either the structure or expression of the TNF protein, might contribute to differences in autoimmune disease ...
  63. [63]
    Genetic determinants of HSP70 gene expression following heat shock
    A number of different genes encode human inducible Hsp70 proteins notably HSPA1A (HSP70-1) and HSPA1B (HSP70-2) located in the major histocompatibility complex ...
  64. [64]
    Structure and expression of the three MHC-linked HSP70 genes
    Jun 28, 1990 · The HSP70-1 and HSP70-2 genes have been shown to be expressed at high levels as a ∼ 2.4 kb mRNA in cells heat-shocked at 42°C.
  65. [65]
    Complement C4 gene copy numbers modulate serum immune ...
    Oct 14, 2025 · Background: The copy number of complement component C4 genes (C4A and C4B) has been associated with schizophrenia risk, particularly in men.
  66. [66]
    Complement C4 gene copy numbers modulate serum immune ...
    The copy number of complement component C4 genes (C4A and C4B) has been associated with schizophrenia risk, particularly in men.
  67. [67]
    Pathways of Antigen Processing - PMC - PubMed Central - NIH
    The trafficking of exogenous and endogenous proteins for antigen processing and presentation are summarized in Figure 2. In general, MHC-I molecules bind ...
  68. [68]
    Targeting Proteasomes and the MHC Class I Antigen Presentation ...
    Nov 29, 2023 · Immunoproteasomes represent actionable therapeutic targets that can be pharmacologically manipulated to treat cancer and infectious diseases.Missing: seminal | Show results with:seminal
  69. [69]
    MHC class I assembly: out and about - PMC - NIH
    In the ER, MHC class I heterodimers lacking peptides are recruited into complexes with the TAP transporter, in an interaction bridged by tapasin (Figure 1).Missing: ERAP | Show results with:ERAP
  70. [70]
    Tapasin enhances MHC class I peptide presentation ... - PNAS
    TAP transports peptides from the cytosol into the ER. Tapasin helps the assembly of class I molecules with peptides (10). Calreticulin is an ER chaperone for ...
  71. [71]
    Antigen Processing and Presentation | British Society for Immunology
    MHC class I and class II molecules are similar in function: they deliver short peptides to the cell surface allowing these peptides to be recognised by CD8+ ( ...
  72. [72]
    The ER aminopeptidase ERAP1 enhances or limits antigen ... - Nature
    Nov 18, 2002 · We found that purified ERAP1 trimmed peptides that were ten residues or longer, but spared eight-residue peptides.Missing: review | Show results with:review
  73. [73]
    ERAAP and Tapasin independently edit the amino and carboxyl ...
    Targeting tumour cells with defects in the MHC Class I antigen processing pathway with CD8+ T cells specific for hydrophobic TAP- and Tapasin-independent ...
  74. [74]
    Targeting MHC-I molecules for cancer: function, mechanism, and ...
    Dec 2, 2023 · Expression of classical human leukocyte antigen class I antigens, HLA-E and HLA-G, is adversely prognostic in Pancreatic cancer patients.
  75. [75]
    The ins and outs of MHC class II-mediated antigen processing and ...
    In this Review, we describe our current knowledge of the mechanisms of uptake and processing of antigens, the intracellular formation of peptide–MHC class II ...
  76. [76]
    Exogenous Antigens Bind MHC Class II first, and Are Processed by ...
    Aug 5, 2015 · Pathogen-derived antigens bind to MHC class II as full-length proteins or large fragments, while DM facilitates the selection of the best fitting epitopes.Missing: paper | Show results with:paper
  77. [77]
    Human cathepsin S, but not cathepsin L, degrades efficiently MHC ...
    Our observations support a role for Cat S only in the degradation of p10 in all MHC class II-expressing tissues and suggest that results obtained in mice have ...
  78. [78]
    HLA-DM and HLA-DO interplay for the peptide editing of HLA class II ...
    HLA-DM is a peptide editor, and HLA-DO is its antagonist, modulating HLA class II antigen presentation. Their interplay controls peptide repertoires.
  79. [79]
    The love and hate relationship of HLA-DM/DO in the selection of ...
    HLA-DM and DO both help select immunodominant epitopes. DM is a peptide editor, and DO may regulate peptide loading, not just inhibit DM.
  80. [80]
    Current Concepts of Antigen Cross-Presentation - Frontiers
    Dendritic cells have the capacity to efficiently present internalized antigens on MHC I molecules. This process is termed cross-presentation and plays an ...
  81. [81]
    Cross-presentation of exogenous antigens on MHC I molecules - PMC
    Dendritic cells utilize distinct and overlapping pathways for cross-presentation. Phagosomes acquire cytosolic and ER-derived proteins for MHC-I loading of ...
  82. [82]
    Regulation of the Cell Biology of Antigen Cross-Presentation
    Antigen cross-presentation is an adaptation of the cellular process of loading MHC-I molecules with endogenous peptides during their biosynthesis within the ...
  83. [83]
    The translocon protein Sec61 mediates antigen transport ... - PubMed
    May 19, 2015 · The translocon protein Sec61 mediates antigen transport from endosomes in the cytosol for cross-presentation to CD8(+) T cells. Immunity ...
  84. [84]
    Processing and presentation of antigens derived from intracellular ...
    Feb 10, 2010 · The IRG proteins are a family of interferon-induced proteins involved in resistance to intracellular pathogens [38]. IRG-mediated resistance to ...
  85. [85]
    PD-L1 on dendritic cells attenuates T cell activation and regulates ...
    Sep 24, 2020 · PD-L1 on DCs is upregulated during antigen-presentation to protect DCs from cytotoxicity of activated T cells. However, such effect also dampens ...
  86. [86]
    Dendritic cells accelerate CAR T cells in irradiated tumors through ...
    Nov 21, 2024 · Here we resolve how the immunology of irradiated tumors dramatically enhances persistence and efficacy of CAR T cells targeted to advanced lung ...
  87. [87]
    Positive selection of antigen-specific T cells in thymus by restricting ...
    Oct 20, 1988 · Here we provide direct evidence that positive selection of antigen-specific, class I MHC-restricted CD4 − 8 + T cells in the thymus requires the specific ...
  88. [88]
    MHC heterozygosity limits T cell receptor variability in CD4 T cells
    Jul 12, 2024 · MHC heterozygotes expressed a less diverse TCR repertoire than expected compared with their MHC homozygous relatives, likely because of increased rates of ...Missing: broader | Show results with:broader
  89. [89]
    NK cell self tolerance, responsiveness and missing self recognition
    This review addresses the mechanisms that confer NK cell self tolerance in light of the fact that many NK cells in normal mice and humans lack self-MHC- ...
  90. [90]
    Killer Ig-Like Receptors (KIRs): Their Role in NK Cell Modulation ...
    The “missing self-hypothesis” stemmed from the observation that NK cells could kill a lymphoma cell line that had lost major histocompatibility (MHC) class I ...
  91. [91]
    From the “missing self” hypothesis to adaptive NK cells: Insights of ...
    Mar 8, 2019 · Since its postulation, the missing-self hypothesis demonstrated that loss of MHC class I molecules is common during malignant cell ...2 Nk Cell Receptors · 3 Nk Cells As Effectors In... · 4 Nk Cell Recognition Of...
  92. [92]
    KIR Receptors as Key Regulators of NK Cells Activity in Health ... - NIH
    Jul 14, 2021 · [13] presented the “missing self” hypothesis, which stated that NK cells kill cells with weak or no MHC-I expression (Figure 1). According to ...2. Nk (natural Killer Cells) · Figure 1 · 4. Kir Typing Methods
  93. [93]
    Human NK Cell Education by Inhibitory Receptors for MHC Class I
    In humans, this “missing self” recognition is ensured by inhibitory receptors such as KIR, which dampen NK cell activation upon interaction with their MHC class ...Results · Nk Cells Lacking Mhc Class... · DiscussionMissing: review | Show results with:review
  94. [94]
    Regulation of ligands for the activating receptor NKG2D - PMC - NIH
    Multiple ligands for the human and mouse NKG2D receptor. Like major histocompatibility complex (MHC) class I molecules, MHC class I chain related proteins (MIC) ...
  95. [95]
    NKG2D and Its Ligands: “One for All, All for One” - Frontiers
    The activating receptor NKG2D is peculiar in its capability to bind to numerous and highly diversified MHC class I-like self-molecules. These ligands are ...
  96. [96]
    NKG2D and its ligands - ScienceDirect.com
    NKG2D is an activating immunoreceptor, first recognized on NK cells but subsequently found on γδ T cells, CD8+ αβ T cells and macrophages.
  97. [97]
    The NKG2A–HLA-E Axis as a Novel Checkpoint in the Tumor ...
    NKG2A forms heterodimers with the CD94 chain (6) and recognizes the nonclassical HLA class I molecule HLA-E. These recent studies demonstrated high expression ...Hla-E As A Molecule Of... · Hla-E Expression In Cancer · Nkg2a In Clinical Trials<|separator|>
  98. [98]
    High-throughput characterization of HLA-E-presented CD94/NKG2x ...
    Aug 9, 2023 · HLA-E is a non-classical class I MHC protein involved in innate and adaptive immune recognition. While recent studies have shown HLA-E can ...
  99. [99]
    Structural basis for NKG2A/CD94 recognition of HLA-E - PNAS
    We have determined the crystal structure of the NKG2A/CD94/HLA-E complex at 4.4-Å resolution, revealing two critical aspects of this interaction.
  100. [100]
    Survival advantage with KIR ligand incompatibility in hematopoietic ...
    Aug 1, 2003 · At 4.5 years patients with KIR ligand incompatibility had higher probability of overall survival (87% versus 48%, P = .006) and disease-free ...
  101. [101]
    Impact of inhibitory KIR ligand mismatch and other variables on ...
    Dec 15, 2024 · Notably, KIR ligand mismatching in the GVH direction has been linked with lower relapse rates, improved engraftment, and reduced rates of GVHD ...2 Methods · 2.2 Ptcy-Based Haplo-Bmt · 3 Results
  102. [102]
    Adoptive NK cell therapy in AML: progress and challenges - PMC
    Jan 17, 2025 · Adoptive cell therapy (ACT) using natural killer (NK) cells has emerged as a promising therapeutic strategy for acute myeloid leukemia (AML) ...
  103. [103]
    Immunotherapy with ex vivo–expanded donor-derived NK cells after ...
    NK cell therapy has shown potential as a relapse-prevention strategy in high-risk patients with AML undergoing haploidentical HSCT. •. No infusion-related ...
  104. [104]
    https://www.sciencedirect.com/science/article/pii/S2452318625000431
  105. [105]
    A systematic review of the last two decades of NK cell-based clinical ...
    Sep 30, 2025 · NK cell-based therapy represents a promising and well-tolerated immunotherapeutic approach for AML. However, optimizing NK cell expansion, ...
  106. [106]
    The Major Histocompatibility Complex in Transplantation - PMC - NIH
    The principal target of the immune response is the MHC (major histocompatibility complex) molecules expressed on the surface of donor cells.
  107. [107]
    The Role of Major Histocompatibility Complex in Organ ...
    Sep 13, 2019 · Antigen presentation by MHC can initiate various types of immunological rejection of transplants. Of these types of rejection, antibody-mediated ...
  108. [108]
    Mechanisms of allorecognition and xenorecognition in transplantation
    Recent research suggests that semidirect alloresponses, where T cells recognize recipient APCs with donor MHC, play important role in allograft rejection, ...
  109. [109]
    Mechanism of cellular rejection in transplantation - PubMed Central
    The function of MHC molecules is to present foreign antigens to T cells. It has been known for more than 30 years that the T cell receptor (TCR) present on ...
  110. [110]
    Advancements in HLA Typing Techniques and Their Impact on ... - NIH
    This review focuses on hematopoietic stem cell transplantation (HSCT) and explores prospective advancements and application of HLA DNA typing techniques.
  111. [111]
    A glow of HLA typing in organ transplantation - PMC - NIH
    Methods for HLA typing are described, including serological methods, molecular techniques of sequence-specific priming (SSP), sequence-specific oligonucleotide ...
  112. [112]
    HLA genotyping by next-generation sequencing of complementary ...
    Nov 28, 2017 · HLA typing by next-generation sequencing generally uses genomic DNA as the template source. Because methods based on amplification of individual ...
  113. [113]
    Desensitization for solid organ and hematopoietic stem cell ... - NIH
    In transplantation, desensitization is a treatment protocol designed to eliminate antibody to donor HLA and/or ABO antigens or reduce the antibody to a level ...
  114. [114]
    Essential concept of transplant immunology for clinical practice - PMC
    Desensitization protocols to remove the preformed hemagglutinin A and/or B from recipient circulation have been used for ABO incompatible kidney transplants[1,7] ...
  115. [115]
    Occurrence and Impact of Minor Histocompatibility Antigens ... - NIH
    Minor histocompatibility antigens belong to genetic factors which may vary between the donor and the recipient despite identical HLA and thus they may influence ...1. Introduction · 2.2. Transplantation... · 3. Results
  116. [116]
    Successful eculizumab treatment as an adjunctive therapy to ... - NIH
    Short-term eculizumab therapy is promising for rescuing ABOi KT recipients with high anti-ABO antibody titers refractory to plasmapheresis-based desensitization ...
  117. [117]
    Safety and efficacy of eculizumab for the prevention of antibody ...
    In a single‐center study, eculizumab lowered the incidence of acute AMR in the first 3 months posttransplant in living‐donor kidney recipients who were ...
  118. [118]
    Association of MHC and rheumatoid arthritis: HLA-DR4 and ... - NIH
    Inherited susceptibility to rheumatoid arthritis (RA) is associated with the DRB1 genes encoding the human leukocyte antigen (HLA)-DR4 and HLA-DR1 molecules.
  119. [119]
    Association of RA with HLA-DR4 - the role of repertoire selection
    Apr 12, 2000 · In normals and patients with RA, HLA-DR genes exert a major influence on the CD4 αβ T-cell repertoire, as shown by studies of AV and BV gene ...
  120. [120]
    Molecular mimicry in HLA-B27-related arthritis - PubMed - NIH
    One hypothesis about the pathogenesis of arthritis is that the bacteria that cause the arthritis carry components that are cross-reactive with HLA-B27 antigens.Missing: mechanism | Show results with:mechanism
  121. [121]
    Conformational Plasticity of HLA-B27 Molecules Correlates ...
    Feb 10, 2020 · Molecular mimicry has been proven to exist in the HLA-B27 as well as other contexts (60, 61) and may contribute also to the emergence of cross- ...Abstract · Introduction · Results · Discussion
  122. [122]
    Early HLA-B*57-Restricted CD8+ T Lymphocyte Responses Predict ...
    Although HLA-B*57 (B57) is associated with slow progression to disease following HIV-1 infection, B57 heterozygotes display a wide spectrum of outcomes, ...
  123. [123]
    HLA B*5701 is highly associated with restriction of virus ... - PNAS
    In one study, B*57 was second to B*27 as the allele most commonly associated with nonprogression (37).
  124. [124]
    HLA-DRB1*1301 and *1302 protect against chronic hepatitis B
    In the first study the class II allele HLA-DRB1*1301-02 was found in 4 of 70 subjects with chronic hepatitis B virus infection (5.7%) compared to 27 of 101 ...<|separator|>
  125. [125]
    High resolution HLA-DRB1 analysis and shared molecular amino ...
    Apr 25, 2022 · The relationship between HLA DRB1alleles and outcome of HBV infection has been explored in some study. HLA-DRB1*13 is associated with natural ...
  126. [126]
    Somatic HLA Class I Loss Is a Widespread Mechanism of Immune ...
    Somatic HLA-I LOH is a potential mechanism for immune evasion in samples with tumor antigen presentation. A, Putative neoantigens are listed by the gene ...
  127. [127]
    The Challenges of HLA Class I Loss in Cancer Immunotherapy
    Dec 1, 2022 · Loss of tumor HLA class I expression with different underlying molecular defects results in reduced antigen presentation and facilitates cancer immune evasion.
  128. [128]
    Regulatory mechanisms of PD-1/PD-L1 in cancers - Molecular Cancer
    May 18, 2024 · The interaction of PD-1 with PD-L1 or PD-L2 provides inhibitory signals responsible for inhibiting T cell signaling, mediating the mechanisms ...
  129. [129]
    Fundamental Mechanisms of Immune Checkpoint Blockade Therapy
    PD-1 blockade is able to induce tumor rejection through reinvigoration of CD8 T cells, leading to both increased functional activity and frequency. Blockade of ...Introduction · Mechanisms Of Pd-1--Mediated... · Therapeutic Combinations
  130. [130]
    Gut microbiome markers in subgroups of HLA class II genotyped ...
    Jul 24, 2022 · Gut microbiome markers in subgroups of HLA class II genotyped infants signal future celiac disease in the general population: ABIS study.
  131. [131]
    Their Roles in Disease Pathogenesis and Immune System Regulation
    Aug 22, 2024 · Complex interactions between the human major histocompatibility complex (MHC) and microbiota: their roles in disease pathogenesis and immune system regulation.2.1. Hla Proteins, Genes And... · 3. The Microbiota: An... · 4. The Role Of Hla In...
  132. [132]
    Advances and challenges in neoantigen prediction for cancer ...
    Jun 11, 2025 · Key areas for improvement include refining MHC-peptide binding predictions, expanding datasets, and developing more advanced algorithms—crucial ...
  133. [133]
    Computation strategies and clinical applications in neoantigen ...
    Jul 9, 2025 · We presented a comprehensive review of integrated neoantigen prediction algorithms, encompassing task definition, theoretical developments, benchmark datasets, ...
  134. [134]
    Origin and evolution of the adaptive immune system - NIH
    Major histocompatibility complex​​ Genes involved in class I processing and presentation are closely linked in almost all vertebrates (except in placental ...
  135. [135]
    Evolution of the MHC and the Adaptive Immune System of Jawed ...
    The organization of the MHC varies enormously among jawed vertebrates, but class I and II genes have not been found in other animals. How did the MHC arise, and ...
  136. [136]
    Reconstructing MHC Origin and Evolution - PubMed - NIH
    Dec 1, 2023 · The β2m gene is linked to the Ig/TCR genes in some vertebrates suggesting that it was present at 1R, perhaps as the donor of C1 domain to the ...
  137. [137]
    Heterozygote advantage can explain the extraordinary diversity of ...
    Nov 26, 2024 · An eco-evolutionary model shows that heterozygote advantage can maintain over 100 major histocompatibility complex alleles, ...
  138. [138]
    MHC allele frequency distributions under parasite-driven selection
    Oct 27, 2010 · The negative frequency-dependent selection resulting from this situation gives a selective advantage to rare MHC alleles and can cause high ...
  139. [139]
    Amino acid insertion in Bat MHC-I enhances complex stability ... - NIH
    May 16, 2024 · This study demonstrated that both 5AA and 3AA insertions enhance the thermal stability of the bat MHC-I complex and enrich the diversity of bound peptides.
  140. [140]
    Bat genomes illuminate adaptations to viral tolerance and disease ...
    Jan 29, 2025 · Our work reveals molecular mechanisms that contribute to viral tolerance and disease resistance in bats.
  141. [141]
    Patterns of MHC‐dependent mate selection in humans and ...
    Nov 17, 2016 · Our results indicate that preference for more MHC-diverse mates is significant for humans and likely conserved across primates.Missing: GWAS | Show results with:GWAS
  142. [142]
    MHC-dependent mate preferences in humans - Journals
    Here we show that the MHC influences both body odours and body odour preferences in humans, and that the women's preferences depend on their hormonal status.
  143. [143]
    The Evolution of Mating Preferences and Major Histocompatibility ...
    Here we provide a critical review of the studies on MHC‐dependent mating preferences in mice, sheep, and humans and the possible functions of this behavior.
  144. [144]
    New evidence that the MHC influences odor perception in humans
    Increasing evidence suggests a correlation between mate choice, odor preference, and genetic similarity at the Major Histocompatibility Complex (MHC) in a ...
  145. [145]
    Is Mate Choice in Humans MHC-Dependent? | PLOS Genetics
    Here, by using genome-wide genotype data and HLA types in African and European American couples, we test whether humans tend to choose MHC-dissimilar mates.