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CD16

CD16, also known as Fcγ receptor III (FcγRIII), is a low-affinity receptor for the Fc region of (IgG) that serves as a critical link between humoral and cellular arms of the . It exists in two primary isoforms: the transmembrane FcγRIIIa (CD16a), expressed on natural killer () cells, macrophages, monocytes, γδ T cells, and dendritic cells, and the (GPI)-anchored FcγRIIIB (CD16b), predominantly found on neutrophils and . These isoforms bind multimeric IgG immune complexes with low affinity but high avidity, preferentially interacting with IgG1 and IgG3 subclasses, and mediate key effector functions such as (ADCC) and . Structurally, both isoforms feature two extracellular immunoglobulin-like domains, with CD16a associating with ITAM-bearing adaptor proteins like the FcR γ-chain or TCR ζ-chain for , while CD16b lacks intrinsic signaling capability and relies on interactions with such as CD11b/CD18. at multiple sites (five in CD16a, including high-occupancy residues at Asn-45 and Asn-162; four to six in CD16b depending on allotype) modulates ligand binding affinity, with deglycosylation enhancing interactions with IgG1 by reducing steric hindrance. Genetic polymorphisms significantly influence function: the CD16a V158 variant exhibits higher IgG binding affinity than F158, impacting ADCC efficiency, while CD16b NA1/NA2 allotypes differ in and activation potential. In immune responses, CD16 engagement on cells triggers and release to eliminate antibody-opsonized targets via ADCC, a mechanism central to therapies like rituximab and for cancer. On neutrophils and macrophages, it promotes of immune complexes, oxidative bursts, and clearance of pathogens or debris, contributing to resolution and host defense. Dysregulation of CD16 expression or polymorphisms is implicated in autoimmune diseases, such as systemic lupus erythematosus (SLE), where the F158 and low FCGR3B copy number increase susceptibility to immune complex-mediated pathology like . Therapeutic strategies increasingly target CD16a to enhance ADCC in , with glycoengineering of antibodies improving binding and clinical outcomes in . Recent advances include cell engagers and bispecific antibodies targeting CD16a, showing promise in clinical trials for enhanced as of 2025.

Molecular Structure and Isoforms

Protein Structure

CD16, also known as FcγRIII, is a low-affinity receptor for the Fc region of (IgG), featuring two extracellular immunoglobulin-like domains: the membrane-distal domain and the membrane-proximal D2 domain, which are connected by a flexible region. The protein exists in two structural forms: one with a and short cytoplasmic tail (CD16a), and another anchored to the via a (GPI) linkage (CD16b). Due to extensive N-linked at multiple sites, primarily in the extracellular domains, the apparent molecular weight of CD16 ranges from 50 to 80 kDa, significantly higher than its predicted unglycosylated mass of approximately 25-30 kDa. The of the extracellular of FcγRIII, determined at 1.8 Å , reveals a compact fold with the two Ig-like domains oriented at an acute interdomain hinge angle of approximately 50°, forming a heart-shaped overall similar to other Fc receptors. In the crystal lattice, the extracellular domain assembles into asymmetric dimers, with the primary dimer interface (AA/BB) burying about 860 Ų of solvent-accessible surface area, potentially influencing receptor clustering on the cell surface. Key structural features include a between Asp-23 and His-111 that stabilizes the domain orientation, and Trp-113, which restricts the hinge flexibility. The IgG-binding site is primarily located on the membrane-distal domain, involving a discontinuous patch formed by the BC, C'E, and FG loops of D2 as well as the hinge and AB loops of , characterized by a net positive charge from six basic residues and one acidic residue. Critical residues in this interface include at position 66 in the hinge region of the domain, where the L66R/H polymorphism modulates IgG . patterns, particularly at Asn-163 in the D2 domain, further influence the and conformation of the .

Isoforms and Genetic Encoding

CD16 exists in two primary isoforms, CD16a and CD16b, which are encoded by closely related within the FCGR3 locus on 1q23.3. CD16a, the product of the FCGR3A , is a featuring a single and a short cytoplasmic tail that lacks intrinsic signaling motifs but associates with ITAM-bearing proteins such as CD3ζ and FcεRIγ to mediate signals. In contrast, CD16b, encoded by the FCGR3B , is anchored to the membrane via a (GPI) linkage, resulting in the absence of a transmembrane or cytoplasmic domain and thus no direct association with ITAM ; however, it can initiate signaling through clustering and indirect interactions with other membrane components.89904-0/fulltext) The two isoforms arose from events within the FCGR locus, which spans approximately 250 kb and includes highly homologous sequences that have undergone segmental duplications during mammalian , leading to the functional FCGR3A and FCGR3B s alongside non-functional pseudogenes such as FCGR3C and FCGR3D. This evolutionary process has conserved the core IgG-binding function across species while introducing tissue-specific adaptations, with the human FCGR3 locus exhibiting structural similarity to orthologous clusters in other and , though with variations in gene arrangement and copy number. The extracellular domains of CD16a and CD16b, responsible for IgG Fc binding, share high sequence identity but differ by six , including substitutions that influence and membrane association without altering the overall Ig-like fold.89904-0/fulltext) Copy number variations (CNVs) are prevalent in the FCGR3 locus, particularly affecting FCGR3B, where deletions or duplications can range from 0 to 4 copies per diploid , influencing receptor density and susceptibility to immune-mediated diseases such as . FCGR3A also shows CNV, correlating with CD16a expression levels on natural killer cells, though less frequently than FCGR3B. These variations stem from the locus's recombination-prone architecture, a hallmark of its evolutionary history, and underscore the genetic complexity underlying isoform function.

Cellular Expression and Regulation

Expression on Immune Cells

CD16, known as Fcγ receptor III (FcγRIII), is predominantly expressed on several key immune cell types, reflecting its role in antibody-mediated immune responses. cells represent a primary site of expression, with approximately 90-95% of peripheral blood cells—specifically the mature CD56^{dim} —bearing the transmembrane isoform CD16a on their surface. Neutrophils and express the (GPI)-anchored CD16b isoform, which is constitutively present and serves as a distinguishing marker on neutrophils. A of monocytes, termed non-classical or monocytes (CD14^{low}CD16^{+}), also display CD16a, comprising about 5-10% of circulating monocytes. Macrophages similarly express CD16a, particularly in tissue-resident populations. Subsets of dendritic cells, such as CD16^{+} myeloid dendritic cells, express CD16a. Gamma delta (γδ) T cells express CD16a on the majority of peripheral blood cells. exhibit minimal basal CD16 expression, though it can be induced under certain inflammatory conditions. In terms of tissue distribution, CD16 expression is notably high on specialized tissue macrophages. Liver Kupffer cells, the resident macrophages of the hepatic sinusoids, express both CD16a and other Fcγ receptors, enabling efficient clearance of immune complexes. Similarly, splenic red pulp macrophages show strong CD16 expression, contributing to the organ's role in filtering blood-borne particles. Isoform specificity aligns with cell type, such that CD16a predominates on NK cells, macrophages, dendritic cells, and γδ T cells, whereas CD16b is neutrophil- and basophil-specific. Developmentally, CD16 expression is tightly regulated during immune cell maturation. In NK cells, immature CD56^{bright}CD16^{-} precursors lack surface CD16, which is progressively upregulated as they mature into the CD56^{dim}CD16^{+} stage, a process linked to epigenetic and transcriptional changes that enhance effector functions. This maturation-dependent acquisition ensures that fully functional cells are equipped for antibody-dependent responses. Quantification of CD16^{+} immune populations relies on , a for assessing surface expression. Cells are stained with fluorescently conjugated anti-CD16 monoclonal antibodies, often in multicolor panels that include lineage-specific markers—for instance, CD3^{-}CD56^{+} for cells or CD15^{+}CD66b^{+} for neutrophils—to gate and enumerate CD16^{+} subsets accurately. Mean fluorescence intensity (MFI) measurements further quantify expression levels, distinguishing high- from low-affinity variants and enabling precise phenotyping of heterogeneous populations.

Factors Influencing Expression

The expression of CD16 on immune cells, particularly natural killer (NK) cells, is dynamically regulated by various biological and environmental factors that influence its surface levels and functional availability. These modulators include cytokines that promote differentiation and upregulation, proteolytic enzymes that mediate shedding during activation, epigenetic mechanisms controlling gene accessibility, pathological states such as chronic infections leading to downregulation, and interactions with ligands that trigger transient changes. Cytokines such as interleukin-2 (IL-2) and interleukin-15 (IL-15) play a key role in upregulating CD16 expression on cells by driving their maturation and expansion. IL-15, often presented in trans with IL-15 receptor alpha, promotes the of immature CD56brightCD16- cells into the mature CD56dimCD16+ subset, significantly increasing the proportion of CD16-expressing cells and enhancing their cytotoxic potential. Similarly, IL-2 supports cell proliferation and sustains CD16 surface density during expansion, contributing to improved (ADCC) in therapeutic contexts. Proteolytic shedding represents a major mechanism for reducing CD16 surface expression, particularly during inflammatory or activation states. The metalloprotease ADAM17 (also known as TACE) is primarily responsible for cleaving CD16 from the plasma membrane of cells upon stimulation by cytokines like IL-12 and IL-18 or engagement with target cells, resulting in the release of soluble CD16 and diminished ADCC capacity. This shedding is exacerbated in inflammatory environments, such as during acute immune responses, where ADAM17 activity correlates with reduced CD16 levels on CD56dim cells, thereby modulating excessive NK cell activation to prevent . Epigenetic modifications, including of the FCGR3A and FCGR3B promoters, tightly control baseline CD16 expression during NK cell development. In CD16a+ NK cells, the FCGR3A promoter region (Pmed1-A) exhibits hypomethylation compared to immature CD16a- NK cells or neutrophils, enabling transcriptional activation and surface expression. Conversely, hypermethylation of the FCGR3B promoter in NK cells silences its expression, restricting CD16b to neutrophils, while demethylation events during late-stage NK maturation (stage 5) correlate with increased FCGR3A activity, as confirmed by methylation-sensitive assays. In chronic infections, NK cells often enter an exhaustion state characterized by sustained downregulation of CD16 expression, impairing their effector functions. During persistent viral infections like hepatitis B virus (HBV) or human immunodeficiency virus (HIV), prolonged antigen exposure leads to reduced CD16 surface density on NK cells, associated with decreased ADCC and cytokine production, as part of a broader dysfunctional phenotype. This downregulation can partially recover following antiviral therapy; for instance, in chronic hepatitis C, direct-acting antivirals restore NK cell phenotypes, including CD16 expression, primarily after treatment completion rather than during early phases, enhancing overall immune reconstitution. Interactions with microbial ligands or immune complexes induce transient alterations in CD16 expression, often through shedding mechanisms. Engagement of CD16 by IgG-containing immune complexes formed during infection triggers ADAM17-dependent ectodomain shedding, leading to sustained reduction in surface CD16 on cells for weeks, which fine-tunes responses by limiting prolonged ADCC while promoting serial target engagement. Similarly, direct exposure to microbial pathogens, such as glycoproteins, activates cells and promotes metzincin-mediated (including ADAM17) CD16 shedding, resulting in soluble CD16 release and temporary impairment of antiviral ADCC. These ligand-induced changes highlight CD16's role in adapting cell function to dynamic infectious challenges.

Biological Functions

Antibody-Dependent Cellular Cytotoxicity

Antibody-dependent cellular cytotoxicity (ADCC) represents a primary effector function of CD16 (FcγRIIIa), enabling natural killer (NK) cells to eliminate IgG-opsonized target cells as part of innate immune defense. The process begins when the Fc domain of bound IgG antibodies on a target cell engages the extracellular Ig-like domains of CD16 on the NK cell surface, initiating receptor crosslinking and activation of associated adapter proteins. This triggers cytoskeletal reorganization, directed secretion of lytic granules containing perforin and granzymes from the NK cell, and subsequent pore formation and apoptosis induction in the target, effectively lysing infected or malignant cells. CD16 demonstrates preferential to specific IgG subclasses, with highest for IgG1 (K_A ≈ 1.5 × 10^6 M^{-1}) and IgG3 (K_A ≈ 5 × 10^6 M^{-1}), which facilitates robust ADCC responses compared to the lower affinities for IgG2 and IgG4. This subclass specificity ensures that ADCC is optimized for antibodies that commonly dominate humoral responses to pathogens and tumors, enhancing the efficiency of cell-mediated killing. A functional polymorphism in the CD16a gene at position 158, substituting (F158) with (V158), increases IgG by 2- to 3-fold and correspondingly boosts ADCC potency, as evidenced by greater target cell in V158-expressing cells. In vivo studies underscore CD16's essential role in ADCC-driven tumor clearance; for instance, conditional of CD16 in NK cells results in significantly impaired elimination of anti-CD20-opsonized lymphomas, with affected animals showing 50% mortality by day 47 post-challenge compared to complete tumor control in wild-type counterparts. Beyond , CD16-mediated ADCC contributes to antiviral immunity, such as in infections where cross-reactive IgG antibodies activate NK cells via CD16 to lyse infected cells, mitigating disease severity in primate models. In , CD16 engagement by non-neutralizing antibodies correlates with reduced viral loads and slower progression to AIDS, highlighting its protective function against persistent viral threats.

Phagocytosis and Immune Modulation

CD16, also known as FcγRIII, plays a critical role in the of IgG-opsonized targets by neutrophils and macrophages, facilitating the engulfment of and apoptotic cells to maintain immune . In neutrophils, CD16 triggers actin remodeling and of immune complexes, leading to degradation in phagolysosomes, often in synergy with other Fcγ receptors like FcγRIIA. Macrophages similarly utilize CD16 to internalize IgG-coated particles, promoting efficient clearance of opsonized pathogens and apoptotic debris through receptor crosslinking and downstream signaling. The GPI-anchored isoform CD16B, predominantly expressed on neutrophils, enhances phagocytosis efficiency, particularly when clustered on the cell surface, allowing potent uptake of IgG-opsonized despite lacking intrinsic signaling domains. In contrast, the transmembrane CD16A isoform, present at lower levels on neutrophils and more abundantly on macrophages, supports direct phagocytic activation via ITAM-associated adapters. Polymorphisms in CD16B, such as the NA1 allotype, further increase binding affinity and phagocytic capacity for certain IgG subclasses compared to NA2. Beyond direct engulfment, CD16-mediated uptake of immune complexes by dendritic cells enhances and to + T cells via pathways, thereby bridging innate and adaptive immunity. This process is particularly efficient in human CD141+ dendritic cells, where CD16 facilitates the shuttling of exogenous antigens into the for proteasomal degradation and peptide loading. Engagement of CD16 on monocytes and induces the release of pro-inflammatory cytokines such as TNF-α and IFN-γ, which amplify adaptive immune responses by activating pathways and promoting T cell polarization toward Th1 subsets. For instance, CD16 crosslinking in monocytes elevates TNF-α production up to sixfold when PI3K signaling is inhibited, while IFN-γ release from cells via CD16 correlates with enhanced macrophage activation and broader inflammatory modulation. CD16 contributes to the clearance of immune complexes in tissues by tethering them to s, preventing deposition and associated damage, though dysregulation can exacerbate reactions like the Arthus response through neutrophil recruitment and mediator release. In extravascular sites, CD16 shedding during shifts reliance to other receptors, potentially intensifying injury in immune complex-mediated conditions.

Signaling Mechanisms

Receptor-Adapter Interactions

CD16a, the transmembrane isoform expressed primarily on natural killer () cells and macrophages, forms non-covalent associations with ITAM-bearing adapter chains to enable signal initiation upon Fc ligand engagement. These adapters include the CD3ζ chain, a component of the complex repurposed in NK cells, and the FcεRIγ chain, both of which contain immunoreceptor tyrosine-based activation motifs (ITAMs) in their cytoplasmic tails. The physical interaction between CD16a and these adapters is mediated by specific motifs in their transmembrane domains. CD16a features a charged aspartic acid residue (Asp226) in its transmembrane helix, which contributes to ionic and polar interactions with complementary residues in the adapters' transmembrane regions. For instance, CD3ζ and FcεRIγ form disulfide-linked homodimers, each presenting paired residues that facilitate assembly with CD16a through a network of hydrogen bonds and van der Waals contacts along a shared helical , independent of strict charge pairing in some cases. Experimental evidence from studies confirms that disrupting these transmembrane interfaces abolishes adapter association and surface expression of CD16a. Optimal signaling requires precise in these complexes. Co-immunoprecipitation assays from NK cell lysates have directly demonstrated these associations, showing CD16a co-precipitating with CD3ζ and FcεRIγ under non-denaturing conditions. In contrast, CD16b, the (GPI)-anchored isoform predominant on s, lacks a and thus does not directly bind ITAM-bearing adapters like CD3ζ. Instead, CD16b localizes to s—- and sphingolipid-enriched membrane microdomains—that serve as platforms for indirect signaling through recruitment of associated kinases, including members of the Tec family such as and Tec. Upon crosslinking, CD16b partitions into these high-density, detergent-resistant s, enabling proximity to Src family kinases for downstream activation. Co-immunoprecipitation from lysates has confirmed CD16b's enrichment in fractions alongside these kinases, while disruption of rafts with agents like methyl-β-cyclodextrin impairs association and signaling. Knockout and knockdown studies further validate these interactions. In cell lines or primary cells with genetic ablation of CD3ζ (via or siRNA), CD16a surface expression is reduced, and adapter-dependent clustering is lost, as evidenced by impaired co-precipitation and diminished receptor stability. Similarly, FcεRIγ-deficient models show selective disruption of CD16a complexes, highlighting the adapters' essential role in maintaining receptor integrity without direct transmembrane anchoring for CD16b. Isoform differences in adapter utilization stem from their distinct membrane topologies, with CD16a relying on charged transmembrane pairing and CD16b on raft-mediated recruitment.

Downstream Signaling Pathways

Upon engagement of CD16 (FcγRIII), the associated adapter proteins undergo tyrosine phosphorylation on their immunoreceptor tyrosine-based activation motifs (ITAMs) by Src family kinases such as and , which facilitates the recruitment and activation of spleen tyrosine kinase (Syk) or zeta-chain-associated protein kinase 70 (ZAP-70). This initial phosphorylation event serves as a critical hub for propagating intracellular signals in immune effector cells like natural killer () cells and macrophages. Activated Syk/ZAP-70 then phosphorylates downstream effectors, including (PI3K) and (MAPK) pathways, which promote actin cytoskeletal rearrangement essential for target cell conjugation and , as well as transcription of pro-inflammatory genes such as cytokines and . In parallel, phospholipase Cγ (PLCγ) is activated, leading to the hydrolysis of into inositol 1,4,5-trisphosphate (IP3) and diacylglycerol (DAG); IP3 triggers calcium mobilization from intracellular stores, while DAG activates (PKC), culminating in and release of cytotoxic granules containing perforin and granzymes. Negative regulation of CD16 signaling prevents excessive activation and maintains immune ; for instance, protein tyrosine phosphatases like SHP-1 dephosphorylate ITAMs and downstream to attenuate the response. Co-engagement of the inhibitory receptor FcγRIIB, which bears an immunoreceptor tyrosine-based inhibitory motif (ITIM), recruits SHP-1 and SHP-2 phosphatases to dampen ITAM-mediated signaling and inhibit effector functions. CD16 signaling also exhibits cross-talk with other receptors, such as receptors (e.g., for IL-2 or IL-15), which can prime or amplify downstream cascades like PI3K/Akt and MAPK/ERK for and production in cells. This integration allows for context-dependent modulation of immune responses during or .

Genetic Variations

Key Polymorphisms

CD16, encoded by the FCGR3A and FCGR3B s, exhibits significant through key polymorphisms that influence its structure and function. The most prominent polymorphism in FCGR3A, which encodes the transmembrane CD16a isoform, is the V158F (rs396991), a () resulting in a valine-to-phenylalanine substitution at position 158 in the extracellular domain. This change alters the receptor's for the Fc portion of IgG, with the V158 allotype demonstrating approximately twofold higher binding for IgG1 and IgG3 compared to the F158 , primarily due to interactions with the moiety on IgG. In FCGR3B, which encodes the GPI-anchored CD16b isoform expressed on neutrophils, the primary polymorphisms define the NA1, NA2, and SH alleles, arising from combinations of four to five SNPs (e.g., rs1799830, rs401621, rs2071273). These variants lead to amino acid differences at positions 36, 65, 82, and 106, resulting in distinct glycosylation patterns: the NA1 allele has four N-linked glycosylation sites, while NA2 and SH have six, with SH differing from NA2 by an additional silent mutation. The increased glycosylation in NA2 and SH reduces binding efficiency to certain IgG subclasses and affects susceptibility to proteolytic cleavage. The FCGR locus on 1q23, spanning FCGR3A and FCGR3B along with other FcγR genes like FCGR2A and FCGR2C, features complex structures due to copy number variations (CNVs) and (LD). For instance, the FCGR3A V158F shows moderate LD with FCGR2A H131R (rs1801274), forming haplotypes that collectively modulate IgG binding across the locus, with CNVs in FCGR3B (1-4 copies per diploid ) further complicating allelic associations. Population prevalence of these polymorphisms varies significantly, reflecting potential evolutionary pressures from infectious diseases that favor balanced selection for diverse immune responses. The V158 frequency is approximately 50% in populations, rising to 70-80% in East Asians, while the NA1 predominates in Africans (up to 80%) compared to roughly equal NA1/NA2 distribution in s (50% each). Such ethnic differences suggest historical selective advantages, possibly against bacterial or pathogens, maintaining polymorphism through heterozygote . Genotyping of these CD16 polymorphisms typically employs polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) for V158F detection, where the creates or abolishes a restriction site, or direct for precise identification, particularly in the complex FCGR locus to distinguish FCGR3A from highly homologous FCGR3B sequences.

Functional Impacts of Variants

The V158 variant of CD16a (FCGR3A) exhibits a 2- to 4-fold higher binding affinity for the Fc portion of IgG1 compared to the F158 variant, primarily due to enhanced hydrophobic interactions at the ligand-binding interface. This increased affinity translates to more efficient (ADCC), where (NK) cells expressing V158 mediate stronger target cell lysis upon engagement with IgG1-opsonized cells. For instance, cells from V/V158 donors demonstrate up to 2-fold greater killing of anti-CD20-coated B-cell targets than those from F/F158 donors . Consequently, this variant promotes heightened NK cell activation, including elevated and perforin release, amplifying overall cytotoxic responses. In CD16b (FCGR3B), the NA1 allele facilitates superior phagocytosis of IgG-opsonized particles compared to the NA2 allele, attributed to fewer N-glycosylation sites (four versus six) that reduce steric hindrance in the extracellular domain. This structural difference enables NA1-expressing neutrophils to more effectively internalize bacteria coated with IgG3 or IgG1, enhancing bacterial clearance in immune complexes. In functional assays, neutrophils homozygous for NA1 exhibit 1.5- to 2-fold higher phagocytic rates against opsonized Escherichia coli than NA2 homozygotes, underscoring the allele's role in optimizing neutrophil-mediated immunity. The F158 variant of CD16a impairs downstream signaling efficiency relative to V158, primarily through reduced ligand engagement duration, which limits recruitment and phosphorylation of adapter proteins such as DAP12 (TYROBP). This results in weaker ITAM-based , including diminished activation of Syk kinase and subsequent PLCγ pathways, leading to suboptimal NK cell responses. In contrast, V158 supports more robust DAP12 association upon clustering, enhancing overall signal amplification. Population-level differences in CD16 variants influence infection susceptibility; for example, the V158 is associated with increased risk of HIV-1 acquisition, potentially due to altered cell-mediated control of viral reservoirs despite enhanced ADCC potential. In cohorts of high-risk individuals, V/V158 genotypes correlate with 1.5- to 2-fold higher odds of compared to F/F158, highlighting variant-specific impacts on viral immunity. Additionally, the V158 has been associated with reduced risk of severe outcomes due to enhanced early cell responses. In vitro studies reveal variant-specific production by cells; engagement of V158-CD16a triggers 2- to 3-fold higher interferon-γ (IFN-γ) secretion than F158 in response to IgG1-immune complexes, reflecting amplified thresholds. Similarly, NA1 neutrophils produce elevated levels of tumor factor-α (TNF-α) during assays compared to NA2, supporting enhanced inflammatory modulation. These differences underscore how polymorphisms fine-tune immune effector functions at the cellular level.

Clinical and Therapeutic Relevance

Role in Diseases

CD16 plays a significant role in the pathophysiology of various autoimmune diseases, particularly through its involvement in immune complex clearance. The NA2 allele of CD16b (FCGR3B) is associated with an increased risk of systemic lupus erythematosus (SLE) due to its lower affinity for IgG, leading to impaired clearance of immune complexes and subsequent deposition in tissues. In infectious diseases, alterations in CD16 expression influence disease severity and outcomes. Low CD16 expression on neutrophils correlates with severe , linked to hyperinflammation and poor viral control. Similarly, a decreased percentage of lowCD16+ monocytes is observed in severe cases, associating with exacerbated parasitemia and . Conversely, higher neutrophil CD16 expression is protective in bacterial , predicting better survival in complicated intra-abdominal infections by enhancing and bacterial clearance. CD16 dysfunction contributes to immune evasion in cancer, particularly via proteolytic shedding that diminishes (ADCC). In the , ADAM17-mediated shedding of CD16 from cells reduces their ability to engage tumor targets, leading to impaired ADCC and tumor progression. High infiltration of CD16+ T cells in lymphomas, such as , serves as a positive prognostic indicator, correlating with improved due to enhanced cytotoxic activity. In inflammatory conditions like (RA), elevated levels of soluble CD16 (sCD16 or sFcγRIIIa) in plasma reflect disease activity and macrophage/NK cell activation, positioning it as a potential for monitoring and joint damage. Recent studies as of 2025 highlight emerging associations between CD16 levels and treatment responses in , an autoimmune blistering disease. Lower CD16 expression on peripheral blood mononuclear cells, particularly in patients with certain FCGR3A polymorphisms, predicts poorer responses to rituximab, suggesting CD16 as a for therapeutic .

Applications as a Drug Target

CD16, also known as FcγRIIIa, serves as a critical target in immunotherapies leveraging antibody-dependent cellular cytotoxicity (ADCC) for treating B-cell malignancies. Monoclonal antibodies such as rituximab and obinutuzumab bind to tumor-associated antigens like CD20 on malignant B cells, recruiting CD16-expressing natural killer (NK) cells to induce ADCC and tumor cell lysis. Obinutuzumab, a glycoengineered type II anti-CD20 antibody, demonstrates enhanced binding affinity to CD16 compared to rituximab, resulting in superior NK cell activation and ADCC in preclinical models of chronic lymphocytic leukemia and non-Hodgkin lymphoma. Clinical studies confirm that obinutuzumab's Fc domain modifications increase CD16 ligation, leading to higher rates of B-cell depletion and improved progression-free survival in patients with follicular lymphoma when combined with chemotherapy. For rituximab, the high-affinity V158 variant of CD16 (FcγRIIIa-158V/F polymorphism) correlates with stronger ADCC and better clinical responses in indolent non-Hodgkin lymphoma, prompting genotyping to predict therapeutic efficacy. Patients homozygous for the V158 allele exhibit up to twofold greater NK cell-mediated cytotoxicity against rituximab-opsonized targets compared to those with the F158 variant. Bispecific antibodies targeting CD16 and tumor antigens redirect NK cell by simultaneously engaging immune effectors and cancer cells, bypassing the need for endogenous . Examples include bispecific T-cell engagers (BiTEs) and NK cell engagers (BiKEs) such as AFM13, a CD30xCD16 bispecific that binds on Hodgkin lymphoma cells and CD16 on NK cells to trigger and tumor killing. Preclinical data show AFM13 induces potent ADCC against CD30-positive tumors, with clinical trials demonstrating objective responses in relapsed/refractory patients, including complete remissions. Chimeric antigen receptor (CAR)-NK therapies incorporate high-affinity CD16 variants to augment ADCC alongside CAR-mediated targeting, particularly for solid tumors resistant to conventional NK cell activity. Engineering NK cells with the CD16-158V high-affinity polymorphism enhances binding to IgG1 Fc domains, improving synergy with monoclonal antibodies like trastuzumab in breast cancer models. Induced pluripotent stem cell (iPSC)-derived CAR-NK cells expressing high-affinity CD16, along with IL-15 for persistence, demonstrate superior tumor infiltration and cytotoxicity against hepatocellular carcinoma and glioblastoma in preclinical studies. Clinical trials of CD16-engineered CAR-NK cells, such as those using cord blood-derived effectors with the 158V variant, report durable responses in relapsed B-cell lymphomas and early promise in solid tumors like colorectal cancer, with reduced cytokine release syndrome compared to CAR-T therapies. In autoimmune diseases, CD16 inhibitors mitigate excessive NK cell activation driven by immune complexes. Anti-CD16 monoclonal antibodies, such as GMA161, block FcγRIIIa signaling to suppress ADCC-mediated tissue damage in models of autoimmune disorders. Preclinical evaluations in CD16 transgenic mice show GMA161 reduces autoantibody-induced inflammation without broad , supporting its advancement for disorders like . These inhibitors selectively dampen pathogenic NK responses while preserving baseline immunity. Post-2023 advances include CD16-chimeric receptors engineered into T cells to confer antibody-dependent targeting capabilities, enhancing efficacy in antibody-resistant settings. CD16-CAR T cells, incorporating the high-affinity 158V variant, redirect cytotoxic T lymphocytes against rituximab-opsonized tumors, showing improved tumor clearance in xenografts compared to unmodified CAR-T. As of 2025, phase I/II clinical trials combining CD16-engineered CAR- with rituximab report objective response rates exceeding 60% in rituximab-resistant B-cell , with enhanced NK persistence and reduced relapse. These strategies, including bispecific integrations, highlight CD16's evolving role in precision .

References

  1. [1]
    Fcγ Receptors: Structure, Function and Role as Genetic Risk Factors ...
    Human Fcγ Receptor Structure and Function. FcγRs bind to the Fc portion of IgG, and serve as a crucial link between humoral and cell mediated immune responses.
  2. [2]
    Effects of anchor structure and glycosylation of Fcγ receptor III ... - NIH
    Isoforms of the Fcγ receptor III (FcγRIII or CD16) are cell surface receptors for the Fc portion of IgG and important regulators of humoral immune responses.
  3. [3]
    The antibody-binding Fc gamma receptor IIIa / CD16a is N ...
    Among the five cognate activating FcγRs, FcγRIIIa/CD16a, is the primary target for engineered antibodies because it is primarily responsible for eliciting ...
  4. [4]
    Article Crystal Structure of the Extracellular Domain of a Human FcγRIII
    Soluble Fc gamma receptor type III (Fc gamma RIII, CD16) triggers cell activation through interaction with complement receptors. J. Immunol, 157 (1996), pp ...Results And Discussion · The Putative Ligand Binding... · Stoichiometry Of Fc And...
  5. [5]
    https://www.sciencedirect.com/science/article/pii/S1074761300000388
  6. [6]
    CD16 / Fc Gamma Receptor III Monoclonal Mouse Antibody (HO-80)
    Molecular weight. 50-80 kDa ; Human gene symbol. FCGR3A ; Entrez gene ID. 2214 ; SwissProt. P08637 ; Unigene. 372679.
  7. [7]
    Glycosylation of FcγRIII in N163 as mechanism of regulating ...
    Oct 27, 2003 · The immunoglobulin G (IgG)-binding site of FcγRIII has been well characterized as a discontinuous area on the membrane proximal ...Stable Transfection · Igg-Binding Assay · Results
  8. [8]
    Fcγ Receptor IIIa Single‐Nucleotide Polymorphisms and Haplotypes ...
    Dec 24, 2013 · FcγRIIIa-66L/R/H influences ligand binding. The low-binding haplotypes formed by 66L/R/H and 176F confer enhanced risk of lupus nephritis in ...
  9. [9]
    146740 - Fc FRAGMENT OF IgG RECEPTOR IIIa; FCGR3A - OMIM
    The Fc receptor with low affinity for IgG (FCGR3, or CD16) is encoded by 2 nearly identical genes, FCGR3A and FCGR3B (610665), resulting in tissue-specific ...
  10. [10]
    Transmembrane features governing Fc receptor CD16A assembly ...
    Jun 26, 2017 · (A) Sequence logo illustrating the degree of amino acid conservation within TM sequences of CD16A and FcεR1α from multiple mammalian species.
  11. [11]
    Fc gamma receptors: Their evolution, genomic architecture, genetic ...
    The FCGR gene locus was duplicated during evolution, retaining very high homology and resulting in a genomic region that is technically difficult to study. Here ...Missing: conservation | Show results with:conservation
  12. [12]
    Evolutionary Story of the Low/Medium-Affinity IgG Fc Receptor Gene ...
    Jun 5, 2019 · We show that murine fcgr3 evolved through several steps into FCGR2A, its ortholog, which is specific to primates.
  13. [13]
    Copy Number Polymorphism in Fcgr3 Predisposes to ... - PubMed
    Feb 16, 2006 · Here we show that copy number variation of the orthologous rat and human Fcgr3 genes is a determinant of susceptibility to immunologically ...Missing: family pseudogenes conservation
  14. [14]
    Copy number variation at the FCGR locus includes FCGR3A ...
    We report a novel CNV of the FCGR3A gene that correlates with FcgammaRIIIa expression and function on NK cells. Only FCGR3A, FCGR2C and FCGR3B show CNV.Missing: FCGR3 family duplication pseudogenes evolutionary conservation
  15. [15]
    Copy number, linkage disequilibrium and disease association in the ...
    The human 1q23.3 locus contains five FCGR genes (FCGR2A, FCGR2B, FCGR2C, FCGR3A and FCGR3B) encoding the FcγRII and FcγRIII receptor families. There is high ...
  16. [16]
    IL-15 trans-presentation promotes human NK cell development in vivo
    IL-15–IL-15Rα complexes induced extensive NK cell proliferation and differentiation, resulting in accumulation of CD16+KIR+ NK cells, which was not uniquely ...
  17. [17]
    Interleukin-15 Enhances Cytotoxicity, Receptor Expression ... - NIH
    IL-15, as well as IL-2, increases the ability of NK cells to mediate ADCC (10), stimulates the expansion of AIDS virus-specific cytotoxic T-cell lymphocytes in ...
  18. [18]
    NK cell CD16 surface expression and function is regulated by a ...
    May 2, 2013 · A disintegrin and metalloprotease-17 (ADAM17) is shown to be expressed by NK cells, and its selective inhibition abrogated CD16 and CD62L shedding.Missing: inflammation | Show results with:inflammation
  19. [19]
    https://pubmed.ncbi.nlm.nih.gov/1377991/
  20. [20]
    Epigenetic and post-transcriptional regulation of CD16 expression ...
    Jan 15, 2019 · Here we identify two types of regulation of CD16a in human NK cells, DNA methylation of the FCGR3A promoter and miR-218 targeting of FCGR3A mRNA ...
  21. [21]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC515280/
  22. [22]
    NK Cell Exhaustion - PMC - NIH
    Jun 28, 2017 · Immune cell exhaustion describes the status of dysfunction of immune cells, usually under the settings of tumors or chronic infections.
  23. [23]
    Recovery of natural killer cells is mainly in post-treatment ... - NIH
    NK cells of CHC patients can be affected by DAAs, and phenotypes and function of NK cells recover not at early stage but mainly after the end of sofosbuvir/ ...
  24. [24]
    Sustained Immune Complex-Mediated Reduction in CD16 ... - NIH
    Sep 26, 2016 · Here, we have investigated CD16 expression by NK cells from healthy subjects and find that CD16 is downregulated for many weeks after influenza ...
  25. [25]
    Human CD16 as a lysis receptor mediating direct natural killer cell ...
    CD16 (Fcγ receptor III) has been described as a receptor expressed on NK cells that facilitates antibody-dependent cellular cytotoxicity (ADCC) by binding to ...
  26. [26]
    Enhancing antibody-dependent cell-mediated cytotoxicity - NIH
    The main and best characterized mechanism utilized in ADCC is the release of perforins and granzymes from effector cell granules. Upon activation, effector ...
  27. [27]
    Specificity and affinity of human Fcγ receptors and their polymorphic ...
    Abstract. Distinct genes encode 6 human receptors for IgG (hFcγRs), 3 of which have 2 or 3 polymorphic variants. The specificity and affinity of individual.Missing: pseudogenes FCGR3C FCGR3D
  28. [28]
    One N-glycan regulates natural killer cell antibody-dependent ... - eLife
    Aug 21, 2024 · Cells expressing the V158F variant likewise demonstrated a 1.4-fold ADCC increase following kifunensine treatment. We observed a similar ...
  29. [29]
    The CD16 and CD32b Fc-gamma receptors regulate antibody ... - NIH
    The CD16 and CD32b Fc-gamma receptors regulate antibody-mediated responses in mouse natural killer cells - PMC.
  30. [30]
    Antibody-Dependent Cellular Cytotoxicity Is Associated with Control ...
    We concluded that infection with a seasonal influenza virus can induce antibodies that mediate ADCC capable of recognizing divergent influenza virus strains.
  31. [31]
    NK Cells in HIV Disease - PMC - NIH
    ADCC is a potent means of NK cell control of HIV-1 infection. NK cells express the FcγRIIIA receptor (CD16) that binds the constant (Fc) domain of IgG ...
  32. [32]
    Expression, Role, and Regulation of Neutrophil Fcγ Receptors - PMC
    Aug 27, 2019 · This review summarizes the expression and function of FcγRs on human neutrophils in health and disease and how they are affected by polymorphisms in the FCGR ...
  33. [33]
    The role of IgG Fc receptors in antibody-dependent enhancement
    Aug 11, 2020 · Crosslinking of FcγRs on phagocytes such as neutrophils, dendritic cells, monocytes and macrophages induces phagocytosis of IgG-opsonized ...
  34. [34]
    Glycoengineered CD20 antibody obinutuzumab activates ... - PubMed
    Nov 14, 2013 · Glycoengineered CD20 antibody obinutuzumab activates neutrophils and mediates phagocytosis through CD16B more efficiently than rituximab.
  35. [35]
    Antigen Cross-Presentation of Immune Complexes - PMC - NIH
    Apr 1, 2014 · Immunoglobulin G (IgG) immune complexes target Fc-gamma receptors on DCs to shuttle exogenous antigens efficiently into the cross-presentation pathway.
  36. [36]
    PI3K limits TNF-α production in CD16-activated monocytes - NIH
    In this study, we examined the role of PI3K in modulating cytokine production from primary human monocytes after cross-linking the CD16 receptor. Moreover, the ...
  37. [37]
    FcγRIIIa-dependent IFN-γ release in whole blood assay is predictive ...
    Our results highlight the importance of FcγRIIIa-dependent IFN-γ release in preclinical cytokine release assay for the prediction of CRS risk associated with ...
  38. [38]
    Mechanisms of Immune Complex Mediated Neutrophil Recruitment ...
    Injury in antibody mediated diseases may be categorized as Type I, II or III hypersensitivity reactions based largely on the nature and location of the antigen ...
  39. [39]
    Transmembrane features governing Fc receptor CD16A assembly ...
    Jun 26, 2017 · We examined in detail the TM interactions that mediate association of CD16A with FcεR1γ and CD247 signaling molecules and found that multiple ...Missing: Asp | Show results with:Asp
  40. [40]
    Dap10 and Dap12 Form Distinct, but Functionally Cooperative ... - NIH
    The transmembrane regions of DAP10 and DAP12 are sufficient to confer specific association with their partners. Although cross-linking of either DAP10- or DAP12 ...Missing: Stoichiometry CD16a
  41. [41]
    The CD3ζ adaptor structure determines functional differences ... - NIH
    We demonstrate that one of the adaptor molecules that CD16 associates with and signals through, CD3ζ, plays a critical role in these functional differences.
  42. [42]
    Co-association of CD3 zeta with a receptor (CD16) for IgG ... - PubMed
    Dec 14, 1989 · Here we report that CD16, the receptor for the Fc (constant) region of IgG, specifically associates with the CD3 zeta homodimer on the membrane of human NK ...Missing: immunoprecipitation | Show results with:immunoprecipitation
  43. [43]
    CD16b associates with high-density, detergent-resistant membranes ...
    CD16b is unique in that it is the only Fc receptor linked to the plasma membrane by a GPI (glycosylphosphatidylinositol) anchor. GPI-anchored proteins.
  44. [44]
    Neutrophil CD16b crosslinking induces lipid raft-mediated activation ...
    Jan 1, 2018 · We found that both CD32a and CD16b crosslinking can activate neutrophils, but did not exactly share cytokine expression profiles. On the other ...
  45. [45]
    The CD3ζ adaptor structure determines functional differences ...
    Mar 23, 2022 · We demonstrate that one of the adaptor molecules that CD16 associates with and signals through, CD3ζ, plays a critical role in these functional differences.
  46. [46]
    Downregulation of CD3ζ in Natural Killer Cells from Systemic Lupus ...
    We immunoprecipitated CD16 from NKL cells previously electroporated with CD3ζ siRNA or control siRNA. Our results show that when CD3ζ is downregulated CD16 ...
  47. [47]
    https://pubmed.ncbi.nlm.nih.gov/29137913/
  48. [48]
    https://rupress.org/jem/article/219/5/e20220022/213088/The-CD3-adaptor-structure-determines-functional
  49. [49]
    Signaling by Antibodies: Recent Progress - PMC - PubMed Central
    Sep 26, 2017 · Type I FcγRs can be classified as activating or inhibitory based on the presence of intracellular activating (immunoreceptor tyrosine activation ...
  50. [50]
    https://doi.org/10.1084/jem.179.2.551
  51. [51]
    https://doi.org/10.1038/s41577-020-00410-0
  52. [52]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC5613280/
  53. [53]
    2214 - Gene ResultFCGR3A Fc gamma receptor IIIa [ (human)] - NCBI
    Sep 5, 2025 · FCGR3A-V158F polymorphism could be a specific marker for response to anti-TNFalpha therapy in psoriasis patients. association between the ...
  54. [54]
    A comprehensive overview of FCGR3A gene variability by full-length ...
    Oct 29, 2018 · The V158F polymorphism at nucleotide position 5093 (rs396991) is not documented in the 1KGP because it did not reach the quality control ...
  55. [55]
    Characterization of Endogenous Human FcγRIII by Mass ... - NIH
    Dec 17, 2018 · The NA1 and NA2/SH alleles are distinguished by amino acid differences at four sites specifically R19S, N47S, D65N and V89I for the NA1 and NA2 ...
  56. [56]
    Genetic Variation in Low-To-Medium-Affinity Fcγ Receptors - Frontiers
    Another SNP in the FCGR3A gene is a triallelic SNP at position 66; p.66Leu/Arg/His, also formerly known as p.48Leu/Arg/His which is located in the EC1 ...
  57. [57]
    [PDF] Site-specific glycosylation mapping of Fc gamma receptor IIIb from ...
    May 1, 2020 · The two major FcγRIIIb allotypes, NA1 and NA2 differ in four amino acids (see Figure 2), resulting in four and six potential glycosylation sites ...
  58. [58]
    FCGR Genetic Variation in Two Populations From Ecuador ...
    Our study confirms important ethnic variation at the FCGR locus; it shows a distinctive FCGR polymorphism distribution in Ecuador highlands.
  59. [59]
    Association Studies of Fcγ Receptor Polymorphisms with Outcome ...
    We further examined allele frequencies of each polymorphism by race. FCGR3A V158F MAFs were 158V = 0.355, 0.377, and 0.389 in whites (N = 1,170), African ...
  60. [60]
    Combined FCGR2A (131H/R) and FCGR3A (158F/V) genotypes ...
    Oct 14, 2025 · Genotyping for the FcγRIIIa V158F polymorphism was conducted using the PCR-RFLP method, and the results of the gel electrophoresis are presented ...
  61. [61]
    A novel PCR-based method for direct Fcγ receptor IIIa (CD16 ...
    Aug 6, 2025 · Current methods for genotyping CD16-SNP559/ FcγRIIIa-F158V include allele specific PCR, nested PCR/RFLP, PCR/Sanger sequencing, Goldengate ...
  62. [62]
    A comprehensive overview of FCGR3A gene variability by full-length ...
    Oct 29, 2018 · Detection of V158F polymorphism by showing 3 different genotypes, homozygous T, homozygous G, and heterozygous. (a) Electropherograms show the ...
  63. [63]
    The weaker-binding Fc γ receptor IIIa F158 allotype retains ... - NIH
    Jul 31, 2022 · The predominant CD16a F158 allotype binds antibodies with less affinity than the less common V158 allotype. This polymorphism likewise affects cellular immune ...
  64. [64]
    An Engineered Human Fc variant With Exquisite Selectivity for ... - NIH
    Mar 27, 2019 · Increased natural killer cell expression of CD16, augmented binding and ADCC activity to rituximab among individuals expressing the Fc{gamma} ...
  65. [65]
    FCGR Genetic Variation in Two Populations From Ecuador ...
    Our study confirms important ethnic variation at the FCGR locus; it shows a distinctive FCGR polymorphism distribution in Ecuador highlands.
  66. [66]
    Ligand Binding and Phagocytosis by CD16 (Fc γ Receptor III) Isoforms
    The NA1 and NA2 alleles of CD16B are 95% homolo- gous to each other and are 95–97% homologous to CD16A in their extracellular domain (12). The functional ...
  67. [67]
    Ligand binding and phagocytosis by CD16 (Fc gamma receptor III ...
    Oct 27, 1995 · The two allelic forms of CD16B showed a similar affinity toward human IgG1. However, the NA1 allele showed approximately 2-fold higher affinity ...
  68. [68]
    High Affinity Allele for the Gene of FCGR3A Is Risk Factor for HIV ...
    Overall, the V158 allele was associated with an increased risk of HIV infection. The VV genotype also seemed to be associated with HIV progression. The majority ...
  69. [69]
    The role of Fc receptors in HIV infection and vaccine efficacy - NIH
    While VV158 individuals were predominantly in the HIV progressor group, higher frequencies of the V158 allele were also detected among all HIV infected patients ...
  70. [70]
    Functional Fc gamma receptor gene polymorphisms and donor ...
    In support of a functional role of FcγRIIIA polymorphism, NK92 cells expressing FCGR3A-V158 produced >2 times as much interferon gamma upon incubation with HLA ...
  71. [71]
    Evidence for both copy number and allelic (NA1/NA2) risk at ... - NIH
    Specifically, we have shown that the risk of SLE is increased with loss of the higher-affinity33 NA1 allele compared with the NA2 allele.
  72. [72]
    Comprehensive Assessment of the Association between FCGRs ...
    Aug 19, 2016 · We performed a meta analysis to assess the relationship of FCGRs polymorphisms with the risk of SLE. Thirty-five articles (including up to 5741 cases and 6530 ...
  73. [73]
    The Low Expression of Fc-Gamma Receptor III (CD16) and ... - MDPI
    Aug 19, 2022 · Severe COVID-19 infection was correlated with a low CD16 expression (r = (−) 0.72; 95% CI (−)0.92–(−)0.23; p = 0.01) and high CD64 expression ...
  74. [74]
    Changes in monocyte subsets are associated with clinical outcomes ...
    Nov 26, 2019 · We show first that a lower percentage of CD14low CD16+ monocytes was associated with more severe malaria (considering that CM is more severe ...
  75. [75]
    Better chance of survival is associated with higher neutrophil CD16 ...
    Jan 17, 2024 · Perioperative neutrophil CD16 expression shows a great potential as a predictor of favorable outcome in patients with cIAIs.Material And Methods · Flow Cytometry · Neutrophil Cd16<|control11|><|separator|>
  76. [76]
    Shedding of CD16 disassembles the NK cell immune synapse ... - NIH
    Inhibition of CD16 shedding did not affect CD16 expression of unstimulated cells ... Tumour-derived soluble MIC ligands impair expression of NKG2D and T-cell ...Missing: microbial | Show results with:microbial
  77. [77]
    CD16+ as predictive marker for early relapse in aggressive B-NHL ...
    Sep 28, 2024 · Thus, the elevated percentage of CD16+ T cells is an independent prognostic marker for improved PFS in patients with aggressive B-NHL/DLBCL.
  78. [78]
    Increase of soluble FcgRIIIa derived from natural killer cells and ...
    Increased sFcgRIIIa levels in RA patients were found to be caused by NK cell and/or macrophage activation. Plasma sFcgRIIIa levels may serve as a marker for ...Missing: elevated | Show results with:elevated
  79. [79]
    Influence of CD16 (FcγRIII) Expression on Peripheral Blood ...
    Jun 17, 2025 · This study underscores the potential influence of CD16 expression and FcγRIIIa polymorphism in response to rituximab in pemphigus patients.
  80. [80]
    Glycoengineered CD20 antibody obinutuzumab activates ...
    CD16B is known to be involved in PMN activation and immune complex–mediated phagocytosis by neutrophils.Pmn Activation And Cell... · Phagocytosis Assays · Phagocytosis Of Cll Targets...<|separator|>
  81. [81]
    Obinutuzumab-mediated high-affinity ligation of FcγRIIIA/CD16 ... - NIH
    In a recent study, we demonstrated that following CD16 stimulation by rituximab-opsonized targets, hence under low-affinity conditions, NK cells became unable ...Missing: drug | Show results with:drug
  82. [82]
    Obinutuzumab for the treatment of non-Hodgkin lymphomas - Nature
    It works by specifically targeting the CD20 protein and kills B cells in three different ways 1) antibody-dependent cellular cytotoxicity –'effector' immune ...
  83. [83]
    Increased natural killer cell expression of CD16, augmented binding ...
    The presence of valine (V) at position 158 of FcγRllla (CD16) is known to improve clinical response to rituximab in indolent non-Hodgkin lymphoma (NHL).Missing: V158 | Show results with:V158
  84. [84]
    NK-cell activation and antibody-dependent cellular cytotoxicity ...
    Feb 1, 2008 · We evaluated the relationship between rituximab-induced complement fixation, natural killer (NK)–cell activation, and NK cell–mediated ADCC.
  85. [85]
    https://www.nature.com/articles/d42473-018-00278-8
  86. [86]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC1988936/
  87. [87]
    Principles and current clinical landscape of NK cell engaging ...
    Bispecific NK cell engagers (BiKEs) or tri-specific NK cell engagers (TriKEs) allow for direct targeting of immune cells to tumors.
  88. [88]
    Bi- and trispecific immune cell engagers for immunotherapy of ...
    Jul 27, 2023 · Immune cell engagers are engineered antibodies with at least one arm binding a tumor-associated antigen and at least another one directed ...
  89. [89]
    High-affinity CD16-polymorphism and Fc-engineered antibodies ...
    Nov 15, 2018 · The CD16 158 V variant of CD16-CAR T cells showed increased cytotoxic activity against all the tested cancer cells in the presence of the wild- ...
  90. [90]
    Human iPSC-derived NK cells armed with CCL19, CCR2B, high ...
    Jul 15, 2025 · Future studies will be necessary to evaluate the role of each modification independently through targeted knockout and knockdown approaches.
  91. [91]
    The clinical landscape of CAR NK cells
    Mar 27, 2025 · Here we explore the current clinical landscape of CAR NK cells, and their application in hematologic malignancies and solid cancers.
  92. [92]
    Nonclinical Evaluation of GMA161—An Antihuman CD16 (FcγRIII ...
    Oct 24, 2011 · Nonclinical Evaluation of GMA161—An Antihuman CD16 (FcγRIII) Monoclonal Antibody for Treatment of Autoimmune Disorders in CD16 Transgenic Mice.
  93. [93]
    Review Fc-gamma receptors: Attractive targets for autoimmune drug ...
    Autoantibody immune complexes (ICs) mediate pathogenesis in multiple autoimmune diseases via direct interference with target function, complement fixation, ...
  94. [94]
    An agonist antibody that blocks autoimmunity by inducing anti ... - NIH
    This antibody was used therapeutically to block autoimmunity in a classic mouse model of spontaneous systemic lupus erythematosus.
  95. [95]
    Artiva Biotherapeutics Reports First Quarter 2025 Financial Results ...
    May 8, 2025 · Longer-term clinical data from Phase 1/2 trial exploring AlloNK + rituximab in patients with relapsed/refractory B-NHL to be presented at The ...Missing: resistant | Show results with:resistant