CD93 (Cluster of Differentiation 93) is a protein that in humans is encoded by the CD93 gene. CD93 is a C-type lectin transmembrane receptor which plays a role not only in cell–cell adhesion processes but also in host defense.

Family

CD93 belongs to the Group XIV C-Type lectin family, a group containing three other members, endosialin (CD248), CLEC14A and thrombomodulin, a well characterized anticoagulant. All of them contain a C-type lectin domain, a series of epidermal growth factor like domains, a highly glycosylated mucin-like domain, a unique transmembrane domain and a short cytoplasmic tail. Due to their strong homology and their close proximity on chromosome 20, CD93 has been suggested to have arisen from the thrombomodulin gene through a duplication event.

Expression

CD93 was originally identified in mice as an early B cell marker through the use of AA4.1 monoclonal antibody. Then this molecule was shown to be expressed on an early population of hematopoietic stem cells, which give rise to the entire spectrum of mature cells in the blood. Now CD93 is known to be expressed by a wide variety of cells such as platelets, monocytes, microglia and endothelial cells. In the immune system CD93 is also expressed on neutrophils, activated macrophages, B cell precursors until the T2 stage in the spleen, a subset of dendritic cells and of natural killer cells. Molecular characterization of CD93 revealed that this protein is identical with C1qRp, a human protein identified as a putative C1q receptor. C1q belongs to the complement activation proteins and plays a major role in the activation of the classical pathway of the complement, which leads to the formation of the membrane attack complex. C1q is also involved in other immunological processes such as enhancement of bacterial phagocytosis, clearance of apoptotic cells or neutralisation of virus. Strikingly, it has been shown that anti-C1qRp significantly reduced C1q enhanced phagocytosis. A more recent study confirmed that C1qRp is identical to CD93 protein, but failed to demonstrate a direct interaction between CD93 and C1q under physiological conditions. Recently it has been shown that CD93 is re-expressed during the late B cell differentiation and CD93 can be used in this context as a plasma cell maturation marker. CD93 has been found to be differentially expressed in grade IV glioma vasculature when compared to low grade glioma or normal brain and its high expression correlated with the poor survival of the patients.

Function

CD93 was initially thought to be a receptor for C1q, but now is thought to instead be involved in intercellular adhesion and in the clearance of apoptotic cells. The intracellular cytoplasmic tail of this protein contains two highly conserved domains which may be involved in CD93 function. Indeed, the highly charged juxtamembrane domain has been found to interact with moesin, a protein known to play a role in linking transmembrane proteins to the cytoskeleton and in the remodelling of the cytoskeleton. This process appears crucial for both adhesion, migration and phagocytosis, three functions in which CD93 may be involved.

In the context of late B cell differentiation, CD93 has been shown to be important for the maintenance of high antibody titres after immunization and in the survival of long-lived plasma cells in the bone marrow. Indeed, CD93 deficient mice failed to maintain high antibody level upon immunization and present a lower amount of antigen specific plasma cells in the bone marrow.

In the context of the endothelial cells, CD93 is involved in endothelial cell-cell adhesion, cell spreading, cell migration, cell polarization as well as tubular morphogenesis. Recently it has been found that CD93 is able to control endothelial cell dynamics through its interaction with an extracellular matrix glycoprotein MMRN2. Absence of CD93 or its interacting partner MMRN2 in the endothelial cells lead to disruption of extracellular matrix protein fibronectin fibrillogenesis and decreased integrin B1 activation.

CD93 plays a significant role in the glioma development. CD93 knockout mice with glioma show smaller tumor size and improved survival. The tumors also show disrupted fibronectin fibrillogenesis and decreased integrin B1 activation.

See also

Further reading

  • Chevrier S, Genton C, Kallies A, Karnowski A, Otten LA, Malissen B, Malissen M, Botto M, Corcoran LM, Nutt SL, Acha-Orbea H (March 2009). . Proceedings of the National Academy of Sciences of the United States of America. 106 (10): 3895–900. Bibcode:. doi:. PMC . PMID .
  • Tenner AJ (August 1998). "C1q receptors: regulating specific functions of phagocytic cells". Immunobiology. 199 (2): 250–64. doi:. PMID .
  • Ghebrehiwet B, Peerschke EI, Hong Y, Munoz P, Gorevic PD (June 1992). "Short amino acid sequences derived from C1q receptor (C1q-R) show homology with the alpha chains of fibronectin and vitronectin receptors and collagen type IV". Journal of Leukocyte Biology. 51 (6): 546–56. doi:. PMID . S2CID .
  • Peerschke EI, Ghebrehiwet B (November 1990). . Journal of Immunology. 145 (9): 2984–8. doi:. PMID . S2CID .
  • Eggleton P, Lieu TS, Zappi EG, Sastry K, Coburn J, Zaner KS, Sontheimer RD, Capra JD, Ghebrehiwet B, Tauber AI (September 1994). . Clinical Immunology and Immunopathology. 72 (3): 405–9. doi:. PMID .
  • Joseph K, Ghebrehiwet B, Peerschke EI, Reid KB, Kaplan AP (August 1996). . Proceedings of the National Academy of Sciences of the United States of America. 93 (16): 8552–7. Bibcode:. doi:. PMC . PMID .
  • Cáceres J, Brandan E (May 1997). "Interaction between Alzheimer's disease beta A4 precursor protein (APP) and the extracellular matrix: evidence for the participation of heparan sulfate proteoglycans". Journal of Cellular Biochemistry. 65 (2): 145–58. doi:. PMID . S2CID .
  • Nepomuceno RR, Tenner AJ (February 1998). . Journal of Immunology. 160 (4): 1929–35. doi:. PMID . S2CID .
  • Stuart GR, Lynch NJ, Day AJ, Schwaeble WJ, Sim RB (December 1997). "The C1q and collectin binding site within C1q receptor (cell surface calreticulin)". Immunopharmacology. 38 (1–2): 73–80. doi:. hdl:. PMID .
  • Nepomuceno RR, Ruiz S, Park M, Tenner AJ (March 1999). . Journal of Immunology. 162 (6): 3583–9. doi:. PMID . S2CID .
  • Norsworthy PJ, Taylor PR, Walport MJ, Botto M (August 1999). "Cloning of the mouse homolog of the 126-kDa human C1q/MBL/SP-A receptor, C1qR(p)". Mammalian Genome. 10 (8): 789–93. doi:. PMID . S2CID .
  • Hartley JL, Temple GF, Brasch MA (November 2000). . Genome Research. 10 (11): 1788–95. doi:. PMC . PMID .
  • Kittlesen DJ, Chianese-Bullock KA, Yao ZQ, Braciale TJ, Hahn YS (November 2000). . The Journal of Clinical Investigation. 106 (10): 1239–49. doi:. PMC . PMID .
  • Joseph K, Shibayama Y, Ghebrehiwet B, Kaplan AP (January 2001). "Factor XII-dependent contact activation on endothelial cells and binding proteins gC1qR and cytokeratin 1". Thrombosis and Haemostasis. 85 (1): 119–24. doi:. PMID . S2CID .
  • Simpson JC, Wellenreuther R, Poustka A, Pepperkok R, Wiemann S (September 2000). . EMBO Reports. 1 (3): 287–92. doi:. PMC . PMID .
  • Steinberger P, Szekeres A, Wille S, Stöckl J, Selenko N, Prager E, Staffler G, Madic O, Stockinger H, Knapp W (January 2002). "Identification of human CD93 as the phagocytic C1q receptor (C1qRp) by expression cloning". Journal of Leukocyte Biology. 71 (1): 133–40. doi:. PMID . S2CID .

External links