Fact-checked by Grok 2 weeks ago

Complement receptor 2

Complement receptor 2 (CR2), also known as CD21, is a 145 kDa transmembrane glycoprotein that serves as a key co-receptor on B lymphocytes, facilitating the linkage between the innate and adaptive arms of the by binding complement-opsonized antigens. It plays a in enhancing activation and responses, particularly through its interaction with complement fragments deposited on immune complexes, thereby lowering the threshold for B cell signaling. CR2 is also implicated in the pathogenesis of certain autoimmune diseases, such as systemic lupus erythematosus (SLE), where its dysregulation can contribute to impaired . Structurally, CR2 consists of an extracellular domain composed of 15 or 16 short consensus repeat (SCR) modules, a single transmembrane-spanning region of approximately 28 , and a short cytoplasmic tail of 34 residues that lacks intrinsic signaling motifs but associates with other proteins for . The ligand-binding site is primarily localized to the N-terminal SCR1-2 domains, which recognize specific epitopes on its ligands with high affinity. This modular architecture allows CR2 to form part of a larger co-receptor complex, including , , and Leu-13 (IFITM1), which amplifies BCR-mediated signals upon ligand engagement. CR2 is predominantly expressed on mature s starting from the naive stage, as well as on (FDCs) within lymphoid follicles, where it aids in retention and presentation. It is absent on immature B cells and plasma cells but can appear on a subset of activated T cells and certain epithelial cells under specific conditions. Expression levels of CR2 are tightly regulated during B cell development and activation, with downregulation occurring upon B cell maturation into antibody-secreting cells to prevent excessive signaling. The primary ligands of CR2 include the complement C3 fragments iC3b, C3dg, and C3d, which are generated during complement activation and opsonize pathogens or immune complexes for enhanced recognition by the . Additional ligands encompass the low-affinity IgE receptor , which modulates IgE responses; interferon-alpha (IFN-α), involved in antiviral immunity; and the Epstein-Barr virus (EBV) glycoprotein gp350/220, enabling viral entry into B cells. CR2 also binds various forms of DNA, particularly methylated DNA, independent of complement, suggesting a role in nucleic acid recognition during immune responses or . In terms of function, CR2 primarily acts as a positive co-receptor that co-ligates with the (BCR) to augment intracellular calcium mobilization, proliferation, differentiation, and production in response to stimulation, thereby providing a 100- to 1,000-fold increase in B cell sensitivity to low-avidity antigens. On FDCs, CR2 contributes to the long-term retention of antigens in germinal centers, supporting affinity maturation and formation. However, recent studies indicate context-dependent inhibitory effects in humans, such as suppression of B cell activation and production upon direct co-engagement with BCR, contrasting with its predominantly enhancing role in murine models. Rare genetic deficiencies in human CR2/CD21 are associated with and increased susceptibility to infections. Reduced CR2 expression is implicated in the of autoimmune diseases such as systemic lupus erythematosus (SLE), underscoring its essential role in immune .

Overview

Discovery and nomenclature

Complement receptor 2 (CR2) was first identified in 1984 as a 145 kDa transmembrane glycoprotein expressed on human B lymphocytes, serving as the receptor for the C3d fragment generated during complement activation. This discovery was achieved by Fearon and colleagues, who utilized the monoclonal antibody HB-5 to immunoprecipitate and characterize the protein from B-cell lysates, demonstrating its specific binding to C3d-coated particles and immune complexes. The identification established CR2 as a key component of the complement system, distinct from the earlier described C3b receptor (CR1). In 1984, the same research team, including Fingeroth, Weis, and Fearon, demonstrated through binding assays, antibody blocking experiments, and that the EBV receptor on human B cells is identical to CR2, revealing its dual role in viral attachment and complement recognition. This finding not only linked CR2 to Epstein-Barr virus (EBV) infection but also expanded its known ligands to include the viral glycoprotein gp350/220. These milestone publications, including Weis et al. on EBV binding and Fingeroth et al. on complement interactions, solidified CR2's identity as a multifunctional receptor. Originally named the C3d receptor (CR2) to denote its specificity within the complement receptor family, the protein's nomenclature evolved with advancing immunological classification systems. It was subsequently designated in the (CD) framework, reflecting its identification via monoclonal antibodies at international leukocyte antigen workshops. Additionally, due to its EBV-binding capacity, CR2 is also referred to as the Epstein-Barr virus receptor (EBVR). Early functional studies in the further characterized CR2's specificity, showing high- to C3d and moderate for the related fragments C3dg and iC3b, which are deposited on opsonized pathogens and immune complexes. These interactions were probed using assays and radiolabeled on B-cell lines, confirming CR2's role in facilitating uptake and presentation. Such insights from research established CR2 as a pivotal linker between the innate complement-mediated opsonization and adaptive B-cell responses, enhancing through coreceptor signaling.

Gene location and expression regulation

The CR2 in humans is located on , with genomic coordinates spanning approximately 36 kb from position 207,454,328 to 207,489,892 (GRCh38 assembly). This consists of 20 exons, encoding the complement receptor type 2 (CR2, also known as CD21), a key in B-cell immunity. The ortholog, Cr2, resides on at positions 194,819,119 to 194,859,024 (GRCm39 assembly), covering about 40 kb and sharing high with the human to support conserved functions in complement signaling. The promoter region of the CR2 gene features binding sites for transcription factors such as and Sp1, which play critical roles in modulating its transcriptional activity. proteins bind to two specific elements in the proximal promoter, enhancing CR2 expression in response to immune stimuli and contributing to its upregulation during B-cell maturation. Similarly, an Sp1 binding site at position -120 relative to the transcription start site supports basal transcription and fine-tunes expression levels in mature lymphocytes. Cytokines including IL-6 and IFN-γ further regulate CR2 transcription indirectly through pathways that activate these promoter elements, promoting expression in activated B cells during inflammatory responses. Epigenetic mechanisms tightly control CR2 expression during B-cell differentiation, with distinct patterns of and modifications ensuring stage-specific activation. In immature B cells, hypermethylation of CpG islands in the CR2 promoter represses transcription, whereas demethylation occurs upon maturation, correlating with increased accessibility and expression. acetylation, particularly at and H4 residues near the core promoter, is enriched in B cells, facilitating an open state that sustains CR2 levels essential for antigen-driven selection and maturation. These modifications collectively prevent in non-B lineages and plasma cells, where CR2 is downregulated via re-methylation and deacetylation. CR2 mRNA expression peaks in mature peripheral B cells, reaching levels up to 10-fold higher than in precursor stages, reflecting its role in immune surveillance. In contrast, (FDCs) maintain basal CR2 transcript levels, sufficient for antigen retention but lower than in B cells, as quantified by real-time PCR analyses showing approximately 20-50% relative expression compared to mature B lymphocytes.

Molecular structure

Domain architecture

Complement receptor 2 (CR2), also known as CD21, is a type I transmembrane with a mature molecular weight of approximately 145 . The protein's overall topology includes an extracellular domain, a single transmembrane helix, and a short intracellular cytoplasmic tail. The primary isoform of CR2 consists of 1,032 , with the cleaved to yield the mature form. The extracellular region is composed of 15 or 16 short consensus repeats (SCRs), also referred to as complement control protein (CCP) modules, each approximately 60 in length. These SCRs form a modular, flexible structure characteristic of the regulators of complement activation (RCA) family. The N-terminal SCRs 1-2 constitute the primary ligand-binding site for C3d, while the subsequent SCRs contribute to the extended architecture. CR2 is N-glycosylated, with multiple sites contributing to its stability and function, though specific positions such as Asn-331 and Asn-657 have been noted in structural studies. The spans 28 , anchoring the protein in the , and is followed by a 34-amino-acid cytoplasmic tail that lacks canonical signaling motifs such as ITAMs or ITIMs. The SCR motifs in CR2 exhibit evolutionary conservation with those in other complement regulators, including (CR1/CD35) and (DAF/CD55), reflecting a shared for recognition and complement modulation across the RCA family. Crystal structures, such as the 2001 determination of the CR2 SCR1-2:C3d complex (PDB: 1GHD), reveal extensive main-chain hydrogen bonding between C3d and SCR2, along with side-chain interactions and SCR-to-SCR packing that support dimeric arrangements, particularly involving SCRs 3-8 in stabilizing higher-order oligomers. These structural features underscore the protein's role in bridging complement fragments to immune cells without direct intracellular signaling capability.

Oligomerization and stability

Complement receptor 2 (CR2) undergoes homodimerization through its short consensus repeat 1 (SCR1) domain, where hydrogen bonds form between specific residues on adjacent monomers, stabilizing the dimer interface.66855-7/fulltext) This homodimeric configuration enhances the receptor's for multivalent , such as C3d-opsonized immune complexes, by allowing that facilitates efficient capture and B-cell signaling.00228-X) The dimerization process is critical for CR2's role in bridging innate and adaptive immunity, as monomeric forms exhibit reduced ligand affinity compared to the dimeric state. The structural integrity of CR2 is maintained by conserved disulfide bonds within each SCR domain, forming intra-domain bridges between cysteine residues (typically Cys1-Cys3 and Cys2-Cys4), which contribute to the overall folding and thermal stability of the protein. Biophysical studies using circular dichroism spectroscopy on the recombinant SCR1-2 fragment reveal a β-sheet-rich secondary structure with a melting temperature of approximately 59°C, indicating robustness under physiological conditions. CR2 conformation and ligand interactions are pH-dependent, with optimal binding and stability observed at neutral pH (around 7.4), as acidic environments disrupt electrostatic interactions at the SCR1-2 interface. In cells not expressing CR2 endogenously, internalized receptor fragments are subject to degradation via lysosomal pathways, preventing accumulation and ensuring regulated turnover. Environmental factors, such as association with membrane lipid rafts, further stabilize CR2 by promoting its co-localization with the /CD81 complex upon ligand engagement, thereby prolonging receptor residence time in signaling-competent membrane domains and inhibiting rapid . Certain within the CR2 coding sequence, including those in the dimerization interface, can compromise protein stability and , as demonstrated in functional assays where altered residues lead to diminished dimer formation and increased susceptibility to degradation.

Cellular expression

Primary cell types

Complement receptor 2 (CR2, also known as CD21) is predominantly expressed on mature B lymphocytes, including naive and memory B cells, but is absent from pre-B cells and plasma cells. In healthy adults, analysis reveals that 80-95% of circulating peripheral B cells are positive for CR2 expression, with the remaining subset consisting of CD21-low or -negative cells associated with specific immune conditions. Mature B cells typically bear approximately 8,000 CR2 molecules per cell, facilitating its role as a co-receptor in B-cell recognition. Follicular dendritic cells (FDCs) in lymphoid tissues exhibit high surface density of CR2, which is essential for capturing and retaining complement-opsonized antigens within germinal centers to support B-cell selection and affinity maturation. Unlike B cells, which express the short isoform, FDCs selectively express the long isoform of CR2 to enhance immune complex trapping. CR2 is expressed at low levels on a subset of peripheral and thymic T lymphocytes, where it may contribute to interactions, as well as on epithelial cells in the tonsils and . In the , CR2 is detectable on and neural progenitor cells, potentially influencing local immune responses. In contrast, CR2 is not expressed on monocytes or granulocytes.

Developmental regulation

Complement receptor 2 (CR2, also known as CD21) expression is tightly regulated during B-cell , remaining absent in pro-B and pre-B cells and first appearing on transitional immature B cells. This induction occurs through activation by the transcription factor , which binds to and promotes chromatin accessibility at the Cr2 locus, enabling B-cell-specific during the transition to maturity, with contributions from IL-4 and CD40 signaling. Upon antigen-driven activation, CR2 levels are downregulated on B cells, where low expression enhances signaling thresholds for survival and affinity maturation. In (FDCs), CR2 expression emerges postnatally, peaking as lymphoid organs mature around one week after birth in mice, coinciding with the organization of B-cell follicles. This developmental timing depends on lymphotoxin signaling, particularly via lymphotoxin β receptor on stromal cells, which is essential for FDC network formation and maintenance; disruptions in this pathway, such as in lymphotoxin-deficient models, prevent mature FDC differentiation and CR2 upregulation. Fetal CR2 expression on B cells is minimal during gestation, with detectable levels emerging near or after birth, reflecting the immaturity of the . In contrast, age-related changes in adulthood show a progressive expansion of CD21low B cells after age 60, correlating with diminished responses and reduced production to vaccines and pathogens. This shift contributes to , as CD21low cells exhibit altered signaling and autoreactivity, impairing overall B-cell function. Experimental evidence from Cr2-/- knockout mice underscores CR2's role in developmental regulation, revealing impaired germinal center formation with reduced size and number, alongside defective humoral responses to T-dependent antigens.

Physiological functions

Complement-mediated roles

Complement receptor 2 (CR2), also known as CD21, primarily binds to the complement fragment C3d, a degradation product of the C3 component of the complement system generated during complement activation. This interaction occurs with moderate affinity, characterized by a dissociation constant (Kd) of approximately 4.3 μM under physiological ionic strength conditions (150 mM NaCl), which decreases to 2.8 μM at lower salt concentrations (75 mM NaCl), reflecting the role of electrostatic forces in stabilizing the complex. CR2 also interacts with related fragments such as iC3b and C3dg, though with varying kinetics and potentially more complex binding modes involving multiple sites. These bindings enable CR2 to recognize complement-opsonized targets, facilitating the capture of immune complexes on follicular dendritic cells (FDCs) in lymphoid tissues. On FDCs, CR2-mediated binding promotes the retention and organization of these complexes, preventing their aggregation and aiding in their overall clearance from circulation, thereby reducing the risk of tissue deposition. In the context of opsonization, CR2 enhances the of C3d-coated and debris by serving as a bridge between opsonized particles and immune cells expressing CR2, such as B cells, or indirectly facilitating uptake by other like macrophages through immune complex transfer. This process amplifies the efficiency of clearance during innate immune responses, as C3d deposition on microbial surfaces marks them for and . For instance, CR2 on B cells can C3d-opsonized antigens, linking immediate uptake to downstream processing, while on FDCs, it supports the coordinated delivery of opsonized material to phagocytic elements in the environment. CR2 plays a pivotal role in bridging innate and adaptive immunity by retaining complement-opsonized on FDCs for extended periods—often weeks to months—allowing prolonged presentation to B cells within germinal centers. This retention is essential for driving affinity maturation, , and the generation of high-affinity memory B cells and plasma cells, as it provides a stable antigen depot that sustains B-cell interactions over multiple rounds of selection. Without CR2, antigen availability diminishes rapidly, compromising the quality and duration of humoral responses.00328-7) In vivo studies using CR2-deficient mice (which also lack CR1 due to ) demonstrate these functions, revealing significantly reduced clearance of soluble immune complexes following intravenous injection, with persistent circulating complexes observed compared to wild-type controls. These mice also exhibit impaired , including diminished formation, lower antigen-specific IgG titers, and weakened secondary responses to T-dependent antigens, underscoring CR2's necessity for efficient complement-mediated clearance and adaptive immune priming.

B-cell activation enhancement

Complement receptor 2 (CR2, also known as CD21) functions as a co-receptor on B cells, forming a with CD19 and CD81 (TAPA-1) that links (BCR) signaling to immunoreceptor tyrosine-based activation motifs (ITAMs) on CD19, thereby amplifying BCR-mediated signals and lowering the activation threshold by up to 10,000-fold for antigens with low . This enhancement allows B cells to respond effectively to weak antigens that would otherwise fail to trigger activation, facilitating the integration of innate complement signals with adaptive humoral responses. The mechanism involves co-ligation of CR2 and the BCR by antigens tagged with the complement fragment C3d, which cross-links CR2 to the BCR and induces tyrosine phosphorylation of CD19 ITAMs, recruiting 3-kinase (PI3K) to generate second messengers that amplify downstream signaling cascades. This co-engagement reduces the requirements for calcium flux and other BCR-induced events, enabling proliferation and differentiation at concentrations 100- to 1,000-fold lower than those needed for BCR ligation alone. In experimental models, such as those using anti-IgM antibodies cross-linked to anti-CR2, this results in markedly enhanced calcium responses and activation marker expression compared to BCR stimulation in isolation. CR2-mediated enhancement is critical for , promoting IgG class switching, , and affinity maturation in , as evidenced by CR2-deficient mice exhibiting reduced IgG titers, impaired formation, and defective affinity maturation against T-dependent antigens.80433-1) Studies with C3d-fused antigens demonstrate a 10- to 10,000-fold increase in titers, underscoring CR2's role in boosting primary and secondary responses without requiring additional adjuvants. Quantitative models, such as the Fearon framework from the , describe this threshold reduction as a 2- to 3-log amplification of BCR signals through CR2-CD19 co-ligation, where the of antigen-C3d interactions directly correlates with the magnitude of activation and downstream effector functions like production. This model highlights how CR2 effectively shifts the dose-response for activation, enabling physiological responses to trace levels of complement-opsonized pathogens.

Molecular interactions

Ligand specificity

Complement receptor 2 (CR2) primarily binds the complement degradation fragments , , and with high through its N-terminal short repeats (SCRs) 1 and 2, forming a key link in immune complex recognition. These ligands arise from the proteolytic processing of b, and CR2 shows no binding to native or intact b, ensuring specificity for opsonized surfaces. The interaction occurs via a V-shaped SCR1-2 domain that engages a globular region on , involving extensive main-chain hydrogen bonds and side-chain contacts. Among non-complement ligands, CR2 recognizes the Epstein-Barr virus (EBV) glycoprotein gp350/220, which structurally mimics C3d to enable viral attachment to B cells and other CR2-expressing cells. This mimicry exploits the same SCR1-2 binding site as complement fragments, highlighting evolutionary adaptation in viral pathogenesis. CR2 also binds the low-affinity IgE receptor CD23, modulating IgE responses, and interferon-alpha (IFN-α), involved in antiviral immunity. Additionally, CR2 interacts with various forms of DNA, particularly methylated DNA, independent of complement, suggesting a role in nucleic acid recognition. The kinetics of C3d binding to CR2 reveal an association rate constant of approximately $10^5 \, \mathrm{M^{-1} s^{-1}}, consistent with electrostatic facilitating rapid encounter, while dissociation is -sensitive and accelerated in the acidic environment of endosomes ( ~5-6) to support delivery and immune complex clearance. specificity is governed by charged residues in the SCR1-2 domains, which mediate electrostatic interactions with basic patches on C3d, contributing to the overall affinity and selectivity of the complex.

Protein complex formation

Complement receptor 2 (CR2, also known as CD21) forms a constitutive, non-covalent complex with CD19 and CD81 on the surface of mature B lymphocytes, functioning as a coreceptor that links complement recognition to B cell signaling pathways. The association between CR2 and CD19 is mediated by the membrane-proximal short consensus repeat (SCR) 15 domain of CR2, while CD81, a tetraspanin protein, interacts primarily through transmembrane domain contacts with both CR2 and CD19. This trimolecular complex exhibits an approximate 1:1:1 stoichiometry, as determined by biochemical analyses of B cell surface proteins and structural modeling of their interactions. Fluorescence resonance energy transfer () studies on B cell membranes have demonstrated that CR2, , and maintain close spatial proximity, typically less than 10 , consistent with their stable assembly into a functional unit that facilitates signal amplification upon encounter. This proximity is essential for the coreceptor's role in lowering the threshold for B cell activation by recruiting downstream effectors into lipid rafts. In (FDCs), CR2 engages in associations with (also known as FcεRII), promoting the retention and presentation of complement-opsonized s to circulating B cells within germinal centers. These CR2-CD23 interactions are calcium-dependent and support prolonged antigen trapping on FDC processes, enhancing humoral immune responses. Upon ligand-induced ligation, the CR2-CD19-CD81 complex recruits the Lyn through phosphorylation of cytoplasmic tyrosines, initiating downstream signaling cascades without CR2 possessing intrinsic ITIM or ITAM motifs. This recruitment occurs within microdomains, where the complex modulates BCR signaling by sustaining activity and preventing premature signal termination.

Isoforms and variants

Structural differences

Complement receptor 2 (CR2) exhibits structural variations primarily through of its pre-mRNA, resulting in multiple isoforms in humans. identifies four isoforms from alternative splicing, with the two primary membrane-bound forms differing by the inclusion of 11. The predominant isoform, CR2-1 (short form), is the membrane-bound form consisting of short consensus repeats (SCRs) in the extracellular and totaling 1033 , including the transmembrane and cytoplasmic tails. A second isoform, CR2-2 (long form), arises from alternative splicing that includes exon 11, leading to an additional SCR and thus an extracellular domain with 16 SCRs. These isoforms differ in their ligand-binding capacities due to the variable SCR composition, with CR2-1 being the major form expressed on B cells at approximately 80% ratio. Post-transcriptional processing further distinguishes membrane-bound isoforms (CR2-1 and CR2-2, ~145 kDa). Soluble CR2 is generated through proteolytic shedding rather than alternative polyadenylation. Structural differences also exist across species. In primates, including humans, CR1 and CR2 are encoded by distinct but adjacent genes on chromosome 1, with CR2 featuring 15-16 SCRs. In contrast, subprimates such as rodents utilize a single gene (Cr2) that generates both receptors through differential splicing: the CR2 form with 15 SCRs and a CR1-like form with 21 SCRs by inclusion of additional N-terminal exons. These evolutionary divergences reflect adaptations in complement regulation, with the single-gene strategy in subprimates allowing coordinated expression of related receptors.

Functional implications

The full-length CR2-1 isoform, characterized by 15 short consensus repeats (SCRs), predominates on mature B cells and serves as an essential component of the B-cell coreceptor complex, associating with and to amplify signaling through the upon binding C3d-opsonized antigens. This configuration lowers the threshold for B-cell activation by up to 1000-fold, facilitating humoral immune responses. Genetic knockout of CR2 in mice, which mimics the functional loss of this dominant isoform, results in severely impaired responses to T-dependent antigens, with reductions in IgG titers and defective formation, underscoring its non-redundant role in adaptive immunity. Soluble CR2 (sCR2), generated through proteolytic shedding of the extracellular domain from B and T cells, circulates in and functions as a decoy receptor by binding C3d fragments on immune complexes, thereby inhibiting excessive complement activation and preventing their deposition on tissues. This isoform modulates inflammatory responses and has therapeutic potential in autoimmune diseases like systemic lupus erythematosus (SLE), where sCR2 fusion proteins such as TT30 (CR2-factor H) underwent phase I clinical trials for safety and efficacy in conditions like but were discontinued. Species-specific differences in CR2 isoforms highlight divergent contributions to immune processes; in , the CR1-like long isoform derived from of the Cr2 gene is predominantly expressed on (FDCs) and is critical for retaining complement-opsonized in germinal centers, supporting B-cell selection and maturation. In humans, the CR2-2 long isoform (16 SCRs), enriched on FDCs via inclusion of 11, may fine-tune modulation in germinal centers by altering and patterns, potentially influencing B-cell survival and differentiation. Experimental modulation of isoform ratios, such as through SNPs affecting 11 splicing, reveals functional impacts; cells favoring the short CR2-1 isoform show enhanced B-cell activation, while dominance of the long CR2-2 correlates with approximately 50% reduced proliferative responses in isoform-specific knockdown studies using splicing-targeted approaches.

Clinical and diagnostic relevance

Association with diseases

Complement receptor 2 (CR2) has been implicated in several autoimmune diseases through genetic variations that alter its function. Polymorphisms in the CR2 gene, such as those forming common haplotypes including SNPs like rs1048971, rs17615, and rs4308977, are associated with decreased risk of systemic lupus erythematosus (SLE), with certain variants linked to altered transcriptional activity and reduced susceptibility. Additionally, reduced CR2 expression due to mutations in the CR2 gene causes 7 (CVID7; OMIM 614699), a condition characterized by low serum immunoglobulin levels, impaired B-cell responses, and recurrent infections. In infectious diseases, CR2 serves as the primary receptor for Epstein-Barr virus (EBV) entry into B cells, facilitating viral attachment via interaction with the EBV gp350. This role contributes to EBV-associated pathologies, including chronic infections where elevated CR2 expression on immune cells may enhance viral persistence, as observed in human T-lymphotropic virus type 1 (HTLV-1) infections. A functional polymorphism in CR2 (rs3813946) is associated with increased susceptibility to , potentially through elevated CR2 expression. Beyond and infections, CR2 variants contribute to osteonecrosis of the in SLE patients, particularly in Korean populations, where specific polymorphisms increase susceptibility by disrupting complement-mediated regulation. Therapeutically, CR2 represents a target for modulating immune dysregulation, with soluble CR2-based constructs explored for inhibiting excessive complement activation in models.

Applications in immunohistochemistry

Complement receptor 2 (CR2, also known as CD21) is widely utilized in (IHC) through monoclonal antibodies to visualize (FDCs) in lymphoid tissues, aiding in the pathological assessment of various lymphomas. Optimal protocols employ monoclonal antibodies such as clone 1F8 or 2G9 on frozen sections, where they effectively highlight expansive FDC networks within neoplastic follicles, appearing as intricate dendritic meshes that delineate tumor architecture in conditions like . These protocols typically involve acetone fixation for frozen tissues followed by avidin-biotin complex detection, yielding strong cytoplasmic and membranous on FDCs while minimizing . In diagnostic applications, CD21 IHC demonstrates positivity in low- to high-grade follicular lymphomas (grades 1-3), where it reveals preserved or expanded FDC meshes that support the follicular growth pattern, and in extranodal marginal zone lymphomas ( type), accentuating residual FDC clusters amid tumor infiltrates. A characteristic meshwork pattern of CD21-positive FDCs is observed in , particularly the hyaline-vascular variant, forming tight, onion-skin-like networks around hyalinized vessels that distinguish it from reactive . This staining is instrumental in confirming FDC involvement in these entities. Limitations of CD21 IHC include weaker or inconsistent staining in formalin-fixed, paraffin-embedded (FFPE) tissues due to masking from fixation artifacts, often necessitating heat-induced retrieval (e.g., citrate buffer at 6.0) to enhance sensitivity, though results may still vary compared to frozen sections. For FDC neoplasms, quantitative scoring of staining intensity and distribution is recommended, as patchy or reduced expression can complicate interpretation in poorly differentiated tumors. Clinically, CD21 IHC is integrated into the (WHO) classification framework for nodal lymphomas, where it helps subclassify B-cell neoplasms by mapping FDC infrastructure and excluding mimics like . It exhibits high sensitivity for diagnosing FDC sarcomas, with strong, diffuse staining in the majority of cases when combined with markers like CD35, facilitating precise identification in rare mesenchymal tumors of lymphoid origin.

References

  1. [1]
    https://doi.org/10.3389/fimmu.2021.620427
  2. [2]
    The Structure-Function Relationships of Complement Receptor Type ...
    In this review we discuss the interactions that CR2 undertakes with its best characterized ligands C3d, CD23 and the EBV gp350/220 envelope protein.
  3. [3]
    https://doi.org/10.1016/j.molimm.2012.07.002
  4. [4]
    Epstein-Barr virus receptor of human B lymphocytes is the ... - PNAS
    Identity of the Epstein-Barr virus (EBV) receptor with the complement receptor type 2 (CR2) was established in three sets of experiments using the ...
  5. [5]
    https://www.pnas.org/doi/10.1073/pnas.81.14.4510
  6. [6]
    120650 - COMPLEMENT COMPONENT RECEPTOR 2; CR2 - OMIM
    CR2, also known as CD21, is a membrane protein on B lymphocytes where Epstein-Barr virus (EBV) binds during infection.
  7. [7]
    1380 - Gene ResultCR2 complement C3d receptor 2 [ (human)] - NCBI
    Aug 19, 2025 · This gene encodes a membrane protein, which functions as a receptor for Epstein-Barr virus (EBV) binding on B and T lymphocytes.Missing: chromosome | Show results with:chromosome
  8. [8]
    Gene: Cr2 (ENSMUSG00000026616) - Summary - Ensembl
    Chromosome 1: 194,819,119-194,859,024 reverse strand. This gene has 13 transcripts (splice variants), 174 orthologues, 37 paralogues and is associated with 34 ...
  9. [9]
    NF-kappaB regulates the expression of the human ... - PubMed - NIH
    We propose that the NF-kappaB signaling pathway enhances the expression of the CR2 gene, as a result of NF-kappaB proteins binding to two CR2 promoter elements.Missing: Sp1 | Show results with:Sp1
  10. [10]
    Focused transcription from the human CR2/CD21 core promoter is ...
    Important regulatory regions include an SP1 site located at −120 and two ... Moreover, we identified functional regulatory elements in the core promoter ...Missing: NF- κB
  11. [11]
    Interleukin 6 Influences Germinal Center Development and Antibody ...
    Its production is regulated by several cytokines including IL-1, IL-2, IL-3, IL-4, IL-13, γ-IFN, TNF and platelet-derived growth factor as well as LPS ...
  12. [12]
    Regulation of CD21 expression by DNA methylation and histone ...
    Expression of the CD21 gene is tightly regulated during B lymphocyte differentiation. Only mature B lymphocytes, but not pro-, pre- or plasma B lymphocytes, ...
  13. [13]
    Molecular Structure and Expression of Anthropic, Ovine, and Murine ...
    Jun 1, 2008 · Human CR2 (CD21) is a 145-kDa type 1 transmembrane glycoprotein that binds the surface-fixed cleavage fragments of C3, iC3b, C3dg, and C3d and ...
  14. [14]
    CR2 - Complement receptor type 2 - Homo sapiens (Human) - UniProt
    CR2 is a receptor for ligands, including C3d, which facilitates B-cell antigen recognition and uptake, enhancing immune responses.Missing: nomenclature | Show results with:nomenclature
  15. [15]
    Revisiting the Coreceptor Function of Complement Receptor Type 2 ...
    Mar 31, 2021 · The positive coreceptor function of CR2 (CD21) on B cells is generally accepted, although its role in the enhancement of antibody production ...Abstract · Introduction · Results · Discussion
  16. [16]
    Structural biology of complement receptors - Frontiers
    Figure 1 Complement receptors CR1 and CR2 are mosaic proteins built from CCP/SCR modules. (A) Structure of a prototypical CCP/SCR domain, the CR1 CCP16 ...
  17. [17]
    Mutational Analysis of the Complement Receptor Type 2 (CR2/CD21)
    The molecular structure of CR2 is well known and comprises a 15 or 16 SCR extracellular domain, a 24 amino acid residue transmembrane domain, and a short 34 ...Missing: architecture | Show results with:architecture
  18. [18]
    Mapping of the C3d Ligand Binding Site on Complement Receptor 2 ...
    The most distally located SCRs (SCR1-2) mediate the interaction of CR2 with its four known ligands (C3d, Epstein-Barr virus gp350, interferon-α, and CD23).Missing: glycosylation | Show results with:glycosylation
  19. [19]
    Structure of complement receptor 2 in complex with its C3d ligand
    The structure reveals extensive main chain interactions between C3d and only one short consensus repeat (SCR) of CR2 and substantial SCR side-side packing.Missing: architecture | Show results with:architecture
  20. [20]
    Structural Studies in Solution of the Recombinant N-Terminal Pair of ...
    Apr 28, 2001 · Here, we report biophysical studies of the CR2 SCR 1-2 domain binding to its ligand C3dg. Two recombinant forms of CR2 containing the SCR 1-2 ...Missing: architecture | Show results with:architecture
  21. [21]
    The molecular mechanism of pH-regulating C3d-CR2 interactions
    Due to the importance of C3d-CR2 interaction in the design of vaccines, many studies have indicated the interactions are pH-dependent. Moreover, C3d-CR2 ...
  22. [22]
    Functional analysis of the cytoplasmic domain of complement ...
    The complement receptor type 2 (CR2/CD21) is functionally regulated by ... two CD21-CTFs were degraded both by the proteasomal and the lysosomal pathways.
  23. [23]
    The CD19/CD21 complex functions to prolong B cell antigen ...
    Here, we show that the binding of complement-tagged antigens stimulates the translocation of both the BCR and the CD19/CD21 complex into lipid rafts, resulting ...
  24. [24]
    Revisiting the Coreceptor Function of Complement Receptor Type 2 ...
    Apr 1, 2021 · It is generally accepted that complement receptor type 2 [CR2 (CD21)] is an activating coreceptor for B cells despite the fact that the ...
  25. [25]
    CD21–/low B cells in human blood are memory cells
    Here, we show that CD21–/low cells represent approximately 5% of B cells in peripheral blood from adults but are barely detectable in cord blood, after ...
  26. [26]
    Complement Receptor 2 (CR2) - Sino Biological
    Complement receptor type 2 (CR2, CD21) is expressed on mature B cells (about 8000 per cell), some T cells, FDCs, pharyngeal epithelial cells, astrocytes and ...<|control11|><|separator|>
  27. [27]
    Complement Receptor 2 - an overview | ScienceDirect Topics
    The CFH gene is located at chromosome position 1q23. Klein et al. (1998) first reported linkage to markers in this region in a large family in which AMD ...
  28. [28]
    Follicular Dendritic Cells Specifically Express the Long CR2/CD21 ...
    We demonstrated that FDCs selectively express CD21L, while B cells selectively express the short CR2/CD21 lacking exon 10a (CD21S). By screening mouse Ltk− ...
  29. [29]
    Complement Receptors and Their Role in Leukocyte Recruitment ...
    Feb 10, 2021 · Complement receptors expressed on leukocytes and parenchymal cells, which, by recognizing complement-derived molecules, promote leukocyte recruitment, ...
  30. [30]
    Complement Receptor 2 Is Expressed in Neural Progenitor Cells ...
    Mar 16, 2011 · We discovered that complement receptor 2 (CR2), classically known as a coreceptor of the B-lymphocyte antigen receptor, is expressed in adult ...
  31. [31]
    B-cell extrinsic CR1/CR2 promotes natural antibody production and ...
    Oct 5, 2006 · Coupled with CR1 or CD19, CR2 regulates B-cell activation and differentiation and promotes memory generation and immunoglobulin class switching.Missing: mRNA | Show results with:mRNA
  32. [32]
    Structural biology of complement receptors - PMC - NIH
    Sep 11, 2023 · CR2 was recognized as a receptor for the Epstein-Barr virus (EBV) very early on, mapping the CR2 binding region to the first two CCP domains and ...
  33. [33]
    CD19: Lowering the Threshold for Antigen Receptor Stimulation of B ...
    B lymphocytes proliferated when approximately 100 antigen receptors per cell, 0.03 percent of the total, were coligated with CD19. The B cell resolves its ...Missing: amplification | Show results with:amplification
  34. [34]
    Qualitative Regulation of B Cell Antigen Receptor Signaling by CD19
    Coligation also lowers the threshold for antigen stimulation of B cell proliferation (20) and enhances by ⩾10,000-fold the immunogenicity of antigen–complement ...
  35. [35]
    Structure of Complement Receptor 2 in Complex with Its C3d Ligand
    The complex contains a V-shaped CR2 receptor binding to a globular C3d ligand (Fig. 1A and Table 1). The V-shaped CR2 molecule has a span of 42.6 Å at the base, ...
  36. [36]
    Molecular Basis of the Interaction between Complement Receptor ...
    The binding of the Epstein-Barr virus glycoprotein gp350 by complement receptor type 2 (CR2) is critical for viral attachment to B lymphocytes.
  37. [37]
    Kinetic analysis of the interactions of complement receptor 2 (CR2 ...
    We have used surface plasmon resonance technology to study the interaction of CR2 with its ligands C3d, iC3b, and the EBV surface glycoprotein gp350/220.
  38. [38]
    The electrostatic nature of C3d-complement receptor 2 association
    It has been recognized in experimental studies that the C3d-CR2 association is pH- and ionic strength-dependent. This led us to perform electrostatic ...Missing: disulfide bonds
  39. [39]
    The CD19/CR2/TAPA-1 complex of B lymphocytes - PubMed
    Authors. D T Fearon , R H Carter. Affiliation. 1 Wellcome Trust Immunology ... This may facilitate interaction of the B cell with other cells essential for ...
  40. [40]
    Lipid rafts and B cell signaling - PMC - NIH
    In this review, we discuss the role of lipid rafts in the activation of B cells. Our major focus is on the role of lipid rafts in the signaling by the BCR.
  41. [41]
    CD21 is a ligand for CD23 and regulates IgE production - Nature
    Aug 6, 1992 · These results demonstrate that the cell-surface protein CD21 is a ligand for CD23 and that the pairing of these molecules may participate in the control of IgE ...
  42. [42]
    Follicular Dendritic Cells Specifically Express the Long CR2/CD21 ...
    Jan 1, 1997 · This paper describes an antibody (mAb 7D6) that specifically recognizes human follicular dendritic cells (FDCs).
  43. [43]
    Complement receptor 2 polymorphisms associated with systemic ...
    Figure 1. CR2 SNP locations and haplotype blocks. The CR2 gene is composed of 20 exons, 19 of which are constitutively spliced into the mature RNA transcript,7 ...
  44. [44]
    Identification of an alternative polyadenylation site in the human C3b ...
    It appears to have been derived from an alternatively processed transcript, caused by polyadenylation occurring at a site within an intron in the CR1 ...Missing: isoform | Show results with:isoform<|control11|><|separator|>
  45. [45]
    Soluble CD21: From Shedding to Autoimmunity - Karger Publishers
    May 16, 2025 · On dendritic cells, CD21 alongside CD35 aids in the maintenance of immune complexes on the cell surface in the germinal center [7].
  46. [46]
    Disruption of the Cr2 locus results in a reduction in B-1a cells and in ...
    Cr2-/- mice had a severe defect in their humoral response to T-dependent antigens that was characterized by a reduction in serum antibody titers.Missing: formation | Show results with:formation
  47. [47]
    The Human Complement Receptor Type 2 (CR2)/CR1 Fusion ...
    Dec 1, 2018 · TT32 is a CR2-CR1 fusion protein using the first ten SCRs of CR1, chosen because they contain both C3 and C5 convertase inhibitory activity.Missing: evolutionary motifs
  48. [48]
    Optimal Germinal Center B cell Activation and T-dependent ... - PMC
    Cr1/2 expression on B cells and FDC has been shown to provide a secondary signal for B cell activation, to facilitate transport of antigen in immune follicles, ...Missing: mRNA | Show results with:mRNA<|control11|><|separator|>
  49. [49]
    Transcriptional effects of a lupus-associated polymorphism in the 5 ...
    Jun 4, 2012 · Common three SNP haplotype of the CR2 gene is associated with increased risk of SLE. The 5´ UTR SNP shows altered transcriptional activity of ...Missing: rs10489757 | Show results with:rs10489757
  50. [50]
    614699 - IMMUNODEFICIENCY, COMMON VARIABLE, 7; CVID7
    ... (CVID7) is caused by compound heterozygous mutation in the CD21 gene (CR2; 120650) on chromosome 1q32. One such patient has been reported. For a general ...
  51. [51]
    Functional polymorphism in the 5′-UTR of CR2 is associated with ...
    The higher levels of CR2 may be a risk of NPC susceptibility, since upregulated CR2 expression may enhance the EBV infection through either B cells or ...
  52. [52]
    Systemic lupus erythematosus: updated insights on the ... - Nature
    Mar 17, 2025 · ... (CR2) have been reported to be associated with the susceptibility of osteonecrosis. CR2 is a membrane glycoprotein that binds to the ...
  53. [53]
    A Novel Image Analysis Approach Reveals a Role for Complement ...
    Apr 11, 2021 · Presentation of ICs on FDCs to B cells is believed to drive affinity maturation. CR1 and CR2 are expressed on B cells and FDCs. Cr2 knock ...Missing: mRNA | Show results with:mRNA
  54. [54]
    Whole exome sequencing identifies compound heterozygous ... - NIH
    CR2 deficiency is known to be a causative factor for CVID phenotype. CVID is a primary immunodeficiency characterised by a decrease in serum IgG level, a ...
  55. [55]
    CD21 (2G9) Mouse Monoclonal Antibody
    Jan 5, 2023 · Anti-CD21 is useful in the identification of follicular dendritic cell framework in various lymphomas, particularly follicular lymphomas, and is ...
  56. [56]
    Follicular dendritic cell sarcoma (FDCS) - Pathology Outlines
    Aug 27, 2024 · The abnormal cells are positive for CD21, CD23, CD35, clusterin and CXCL13. There are small numbers of terminal deoxynucleotidyl transferase ...
  57. [57]
    IMMUNOHISTOCHEMICAL ANALYSIS FOR CD21, CD35 ... - PMC
    Immunohistochemistry reactions were applied to 50 oral lymphomas using the antibodies anti-CD21, anti-CD35 and anti-caldesmon to FDCs, and anti-S100 protein to ...
  58. [58]
    CD21 - Pathology Outlines
    Aug 18, 2023 · CD21, CD23 and CD35 are dendritic cell markers · Diagnosis of follicular dendritic cell sarcomas (Am J Surg Pathol 1996;20:944) · Assess ...
  59. [59]
    Castleman disease - Pathology Outlines
    Follicular dendritic cell meshworks, CD21. Follicular dendritic cell meshworks, CD21.
  60. [60]
    Follicular dendritic cells in reactive and neoplastic lymphoid tissues
    Reproducible demonstration of FDCs in routinely processed paraffin sections with CD21, CD23, and CD35 antibodies, as presented here, provides invaluable ...Missing: limitations masking
  61. [61]
    [PDF] Antibodies validated for routinely processed tissue seldom ... - bioRxiv
    May 12, 2020 · except that antigen masking associated with routine tissue processing limits the range of useful ... paraffin-embedded (FFPE) material ...
  62. [62]
    Follicular dendritic cell sarcoma - PMC - NIH
    Neoplastic cells express one or more of the FDC-associated markers CD21, CD23, CD35, clusterin, CXCL13 and podoplanin, with highest sensitivity (> 80%) shown by ...