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CD68

CD68 is a 110-kDa transmembrane glycoprotein encoded by the CD68 gene located on chromosome 17p13.1 in humans, belonging to the lysosomal/endosomal-associated membrane glycoprotein (LAMP) family and serving as a key marker for mononuclear phagocytes such as monocytes and macrophages. It primarily localizes to lysosomes and endosomes, with a portion circulating to the cell surface, where its glycosylated extracellular domain facilitates binding to tissue-specific lectins and selectins as part of the scavenger receptor family. Alternative splicing of the gene produces multiple isoforms, contributing to its functional diversity in immune responses. Structurally, human CD68 consists of 354 , including a , a mucin-like rich in sites (up to 29), a LAMP-like with bridges for stability, a transmembrane region, and a short cytosolic tail that may mediate signaling. This heavy (including 9 N-linked sites) not only protects the protein but also modulates ligand interactions, such as with oxidized (oxLDL) and apoptotic cells. In mice, the ortholog macrosialin shares approximately 72% sequence identity and similar organization, highlighting evolutionary conservation across species. CD68 is predominantly expressed in myeloid cells, including tissue macrophages, microglia, osteoclasts, and myeloid dendritic cells, with highest levels observed in the spleen (RPKM 159.3) and lung (RPKM 115.5) across human tissues. Expression is regulated by transcription factors such as PU.1, c-Jun, and cytokines like (M-CSF) and (GM-CSF), enabling upregulation during or . Lower expression occurs in some lymphoid cells (e.g., B and T lymphocytes) and non-hematopoietic cells like fibroblasts or tumor cells, but it remains a reliable myeloid-specific marker. Functionally, CD68 acts as a scavenger receptor that promotes of cellular debris and pathogens, aids in intracellular lysosomal metabolism, and supports extracellular interactions in and . It may facilitate and presentation by regulating trafficking, though its precise role in innate immunity—such as formation in —remains under investigation. Additionally, CD68 has been implicated in specific processes like the entry of sporozoites into liver Kupffer cells, underscoring its involvement in host-pathogen defense. In clinical and pathological contexts, CD68 is widely used as an immunohistochemical marker to identify macrophages in tissues, particularly in inflammatory diseases, tumors, and disorders. High densities of CD68-positive tumor-associated macrophages (TAMs) often correlate with advanced tumor grade, poor prognosis in cancers like , and increased activity in conditions such as histiocytic . Its expression also aids in diagnosing myeloid neoplasms and monitoring inflammatory responses, though staining variability necessitates complementary markers for accuracy.

Molecular Biology

Gene and Regulation

The CD68 gene is situated on the short arm of chromosome 17 at locus 17p13.1, encompassing a genomic span of approximately 2.7 kilobases and comprising six exons. This compact organization facilitates its transcription into a primary mRNA that encodes the core protein product, a transmembrane highly expressed in myeloid cells. The gene's location places it in proximity to other immune-related loci, though its regulatory elements are primarily contained within the proximal promoter and intronic sequences. Transcriptional processing of the CD68 primary transcript yields a predominant mRNA isoform (NM_001251), with limited of significant as of 2025; minor variants, such as NM_001040059, arise from alternate splice sites in the 5' but do not substantially alter the protein's functional domains or prevalence in tissues. These isoforms maintain the essential , ensuring consistent of the macrophage-associated marker. The lack of extensive splicing underscores CD68's role as a stably expressed in phagocytic lineages, without the isoform complexity seen in many other immune regulators. Regulation of CD68 expression occurs through a macrophage-specific promoter lacking a , with key responsiveness to inflammatory stimuli such as interferon-gamma (IFN-γ) and (LPS), which activate transcription via (TLR4) pathways in cells like and monocytes. This induction involves binding sites for family transcription factors, notably PU.1 (which occupies the proximal -89 bp region and coordinates with interferon regulatory factor-4 to modulate activity) and Elf-1 (enhancing promoter function at -106 bp), ensuring cell-type-specific upregulation during myeloid . Additionally, motifs in enhancer regions, including intron 1, contribute to cytokine-driven amplification, linking CD68 to innate immune responses without broad off-target effects in non-phagocytic cells. Growth factors like (M-CSF) further prime expression in progenitors, highlighting a layered regulatory network. Evolutionarily, the CD68 gene is highly conserved among mammals, reflecting its fundamental role in phagocyte function; the mouse ortholog, Cd68 (also known as macrosialin), located on , shares approximately 72% amino acid sequence identity and 81% similarity with the protein, preserving critical lysosomal targeting motifs and structural features despite species-specific adaptations. This enables robust cross-species modeling of biology, with conserved promoter elements supporting similar inflammatory regulation.

Protein Structure and Localization

CD68 is a type I transmembrane with a mature molecular weight of approximately 110 , resulting from extensive post-translational modifications on its core polypeptide of 37.4 . The extracellular domain is heavily glycosylated, featuring both N-linked and O-linked modifications that contribute significantly to its size and functional properties. The protein exhibits structural homology to the lysosome-associated membrane protein (LAMP) family, particularly through a single LAMP-like domain characterized by conserved disulfide bridges. This domain is flanked by a mucin-like region enriched in serine and residues, which serves as the primary site for O-glycosylation, with up to 29 such sites in the protein. A transmembrane helix anchors CD68 to cellular membranes, while the short cytoplasmic tail contains a dileucine motif essential for intracellular trafficking to lysosomes and endosomes. CD68 is predominantly localized to the endosomal and lysosomal compartments, where it constitutes a significant portion of the membrane glycoproteins, though a minor fraction is present on the plasma membrane. Post-translational sialylation, particularly of O-linked glycans, is a key modification that underlies its alternative name, macrosialin, and facilitates interactions with . The encoding CD68 is situated on 17p13.

Biological Functions

Phagocytic and Scavenger Roles

CD68 functions as a scavenger receptor in macrophages, recognizing and binding specific ligands on apoptotic cells, bacteria, and cellular debris, potentially contributing to their clearance to maintain tissue homeostasis. As a member of the lysosomal-associated membrane protein (LAMP) family, CD68 exhibits in vitro binding to these targets, which may support internalization through endocytic pathways, though direct in vivo phagocytic activity remains unconfirmed. This potential role is prominent in mononuclear phagocytes, where CD68 may aid the innate immune response by helping clear inflammatory material, but knockout studies indicate redundancy with other receptors. In its scavenger receptor capacity, CD68 binds oxidized low-density lipoprotein (oxLDL) with high affinity on the macrophage surface, promoting uptake of this modified lipid particle implicated in lipid homeostasis and atherosclerosis. Additionally, CD68 interacts with phosphatidylserine exposed on the outer membrane of apoptotic cells, aiding their recognition during efferocytosis. These interactions are mediated by the extracellular domain of CD68, which exhibits homology to other scavenger receptors, allowing saturable binding in vitro. CD68 knockout studies in mice demonstrate normal uptake of oxLDL and bacterial particles, indicating redundancy in these mechanisms, though the receptor's binding affinity underscores its contributory role. While CD68 is implicated in efferocytosis, the process of phagocytosing apoptotic cells to prevent secondary necrosis and dampen inflammation, its precise contribution is not essential due to compensatory pathways. CD68-positive macrophages are observed clearing apoptotic bodies, with studies in human developing kidney tissue showing they phagocytose 37-75% of such cells in the nephrogenic zone. This clearance supports inflammation resolution and tissue repair, and defective efferocytosis is linked to chronic inflammatory conditions. Following binding, CD68's localization to lysosomal membranes supports of internalized material within acidic compartments, facilitating breakdown of and pathogens. This lysosomal trafficking may enhance , potentially contributing to ( presentation of derived peptides to + T cells, linking these processes to adaptive immunity. Overall, while CD68 is involved in these functions, its exact roles remain under investigation, with evidence of redundancy in scavenger and phagocytic activities.

Adhesion and Immune Modulation

CD68 facilitates adhesion to inflamed tissues through its ability to bind tissue-specific and selectins, enabling the homing of subsets to sites of , including atherosclerotic plaques where CD68 expression is upregulated in -rich areas. This binding is mediated by the mucin-like domain of CD68, which presents O-linked chains rich in sialic acids and other carbohydrates that serve as ligands for selectins on endothelial cells. The sialylated domains of CD68 play a critical role in the dynamic regulation of adhesion and release, supporting the rapid recirculation of subsets. During macrophage activation, the acquisition of additional O-linked terminal residues enhances ligand-binding capacity and allows CD68 to shuttle between endosomes, lysosomes, and the plasma membrane, facilitating crawling over selectin-bearing substrates without firm attachment. This trafficking mechanism contributes to enhanced tissue migration, often in coordination with such as αMβ2 (CD11b/CD18), which are co-expressed on s and promote and motility in inflammatory environments. In addition to , CD68 modulates immune responses by influencing interactions between macrophages and T cells, as well as . CD68-expressing macrophages can prime naïve T cells, leading to enhanced IL-2 production and potential initiation of adaptive immune responses, such as in autoimmune conditions. Furthermore, CD68+ macrophages contribute to through the of like IL-10, which suppresses pro-inflammatory signaling and promotes regulatory T-cell activity, thereby balancing immune activation at sites of chronic inflammation.

Expression Patterns

Cellular and Tissue Distribution

CD68 is predominantly expressed in cells of the monocyte-macrophage lineage, where it serves as a key marker for these myeloid-derived populations. In circulating monocytes, CD68 is present on the cell surface as a transmembrane , facilitating its role in phagocytic activities. Upon and migration into tissues, CD68 expression becomes highly enriched in resident macrophages, including specialized subsets such as Kupffer cells in the liver, alveolar macrophages in the lungs, and in the . These cells exhibit strong cytoplasmic and lysosomal localization of CD68, reflecting its association with endosomal compartments. While CD68 expression is primarily restricted to the , lower levels are observed in select other hematopoietic cells. Myeloid dendritic cells and osteoclasts, both derived from precursors, display detectable but comparatively reduced CD68 compared to . In contrast, expression is minimal or absent in lymphocytes and granulocytes, underscoring CD68's specificity for the monocyte-macrophage axis within the hematopoietic hierarchy. At the level, CD68 shows a distribution pattern aligned with abundance, with high RNA and protein expression in lymphoid organs such as the , , and lymph nodes, where resident and infiltrating predominate. Moderate expression is noted in tissues rich in tissue-resident , including the , liver, and intestine, as evidenced by and sequencing data from the Human Protein Atlas, which highlight macrophage-enriched expression clusters in these sites. Overall, CD68's profile is selective for populations, with negligible detection in non-immune parenchymal cells. Developmentally, CD68 expression is upregulated during the differentiation of monocytes into mature , a process that enhances its levels in response to environmental cues in tissues. This increase accompanies the acquisition of phagocytic and functions, marking the transition from circulating precursors to tissue-adapted effectors.

Pathological Variations

CD68 expression is markedly upregulated in inflammatory diseases characterized by macrophage infiltration, such as and (RA). In atherosclerotic lesions, CD68-positive macrophages accumulate prominently within plaques, contributing to the chronic inflammatory response and lesion progression. Similarly, in RA synovium, increased CD68 expression on synovial macrophages strongly correlates with disease activity and joint inflammation severity. Ectopic expression of CD68 has been observed beyond traditional macrophage populations, challenging its exclusivity as a myeloid marker. Seminal studies demonstrate strong CD68 protein and expression in primary fibroblasts and various lines, comparable to levels in monocytes and s. Recent investigations in 2024 further confirm tumoral CD68 expression in cells, particularly in and hepatocellular carcinomas, where it associates with epithelial-to-mesenchymal transition and altered immune interactions. In neurodegenerative conditions, CD68 levels are elevated in , reflecting activated phagocytic states. In (ALS), microglial CD68 expression is significantly upregulated in the , with a strong positive correlation to phosphorylated TDP-43 pathological burden and neuronal loss, as reported in 2023 analyses of human ALS brain tissue. During foreign body responses, CD68-positive cells in granulomas exhibit extensive co-expression with diverse markers, including up to 90% overlap with pan-leukocyte (CD45), T-cell (, , ), and other immune antigens, indicating in the inflammatory infiltrate. Quantitative variations in CD68 expression are notable in tumor microenvironments, where higher densities of CD68-positive () serve as prognostic indicators. In classic , elevated CD68+ TAM infiltration within the is linked to poor overall survival, with meta-analyses showing a of approximately 2 for high-density cases.

Applications in Research and Medicine

Diagnostic Marker in

CD68 serves as a primary immunohistochemical marker for identifying macrophages and histiocytic cells in various pathologies, particularly histiocytic disorders such as , where it is typically positive alongside other markers like to confirm lineage. In , CD68 staining highlights characteristic Gaucher cells with striated cytoplasm, aiding in the of this lysosomal storage disorder by detecting accumulated glucocerebroside-laden macrophages in and tissues. For malignant histiocytosis (now largely reclassified as ), CD68 positivity supports the identification of neoplastic histiocytes, distinguishing them from lymphoid or other infiltrates in aggressive malignancies. Although less specific for leukemias, CD68 is utilized in biopsies to detect myeloid progenitors and monocytes in conditions like with histiocytic features. Monoclonal antibodies such as KP1 for human tissues and ED1 for rat models are widely employed in protocols, with KP1 targeting the lysosomal-associated form of CD68 in macrophages and histiocytes. The ED1 specifically recognizes the lysosomal isoform of CD68 in activated macrophages and , making it valuable for studying inflammatory responses in models of . These antibodies enable sensitive detection in formalin-fixed, paraffin-embedded tissues following heat-mediated retrieval, often using citrate buffer at pH 6.0 to enhance staining specificity. In diagnostic protocols, CD68 offers advantages in delineating infiltrates from lymphoid or epithelial cells, particularly when combined with for improved specificity in neoplasms. This panel approach is essential in fixed tissue sections, where CD68's granular cytoplasmic staining pattern helps quantify burden in disorders like histiocytic intervillositis. Since the 1980s, with the development of antibodies like KP1, CD68 has been a cornerstone for identification in , evolving with techniques that enable automated quantification and multiplexing with markers such as CD3 and for enhanced analysis. Despite its utility, CD68 exhibits limitations due to non-specific expression in non-macrophage cells, including and endothelial cells, which can lead to overestimation of histiocytic infiltrates without confirmatory markers. Overlap with markers like or prolyl 4-hydroxylase further necessitates multi-marker panels to avoid misdiagnosis in synovial or tumor stroma contexts. In updates, algorithms now mitigate these issues by integrating CD68 with for precise phenotyping in complex tissues.

Emerging Roles in Disease Mechanisms

Recent research has elucidated the role of CD68-positive follicular macrophages as persistent reservoirs for in germinal centers during suppressive antiretroviral therapy (). A 2025 preprint study analyzing tissues from individuals on long-term identified these CD68+ macrophages as harboring DNA, RNA, and p24 protein, suggesting they contribute to viral and immune evasion despite treatment. This finding highlights CD68 as a marker for targeting myeloid cell reservoirs in strategies aimed at achieving an HIV cure, potentially through macrophage-specific interventions to disrupt . In cancer, CD68+ tumor-associated macrophages (TAMs) have been implicated in promoting an immunosuppressive . In classical , elevated CD68+ infiltration correlates with poorer clinical outcomes, as observed in studies from 2021 onward. In , high densities of CD68+ are associated with unfavorable overall survival and disease-free survival. In pancreatic ductal , high densities of CD68+PD-L1+ are associated with poor prognosis. In neurodegenerative diseases like (ALS), CD68 upregulation in is linked to pathological responses to TDP-43 aggregates. A 2023 analysis of ALS brain tissue revealed that microglial CD68 expression strongly correlates with phosphorylated TDP-43 load in the (r = 0.906, p = 0.0006), indicating activated in areas of neuronal loss. This activation contributes to synaptic stripping, exacerbating neurodegeneration by removing functional synapses from motor neurons. Therapeutically, targeting CD68+ macrophages shows promise in modulating disease mechanisms. In foreign body responses to implants, CD68+ cells drive chronic inflammation, as demonstrated in a 2020 study quantifying their functional heterogeneity via multiplexed imaging. For , eliminating CD68+ reservoirs could enhance cure strategies by addressing ART-persistent infection sites. Additionally, CD68 interacts with progranulin-derived granulin E to regulate lysosomal , with disruptions implicated in neurodegenerative lysosomal dysfunction; this reciprocal regulation holds potential for therapeutic modulation in progranulin-related disorders.