CD58 binds toCD2 (LFA-2)[4][5] onT cells and is important in strengthening the adhesion and recognition between the T cells and Professional Antigen Presenting Cells, facilitatingsignal transduction necessary for animmune response. This adhesion occurs as part of the transitory initial encounters between T cells and Antigen Presenting Cells beforeT cell activation, when T cells are roaming thelymph nodes looking at the surface of APCs for peptide:MHC complexes theT-cell receptors are reactive to.
Polymorphisms in the CD58 gene are associated with increased risk formultiple sclerosis.[6] Genomic region containing the single-nucleotide polymorphism rs1335532, associated with high risk ofmultiple sclerosis, has enhancer properties and can significantly boost the CD58 promoter activity in lymphoblast cells. The protective (C) rs1335532 allele creates functional binding site forASCL2 transcription factor, a target of theWnt signaling pathway.[7]
CD58 plays a role in the regulation of colorectal tumor-initiating cells (CT-ICs). Thus, cells that express CD58 have become a cell of interest in tumorigenesis.[8] Mutations of CD58 have been linked to immune evasion observed in some lymphomas and studies are underway to analyze how its involvement directly affects classical Hodgkin lymphoma (cHL).[9]
CD58, lymphocyte-function antigen 3 (LFA-3), is aglycoprotein that plays a vital role in the body'simmune response. The naturalligand to CD58,CD2, is most commonly found on the surfaces of both T cells andNatural Killer cells (T/NK cells).[3] During an immune response, the interactions between the CD2 and CD58 glycoproteins allows for the activation andproliferation of both T and Natural Killer cells (T/NK cells), enhancingcell adhesion.[3] Furthermore, upon activation, a succession of intracellular signaling within T and Natural Killer cells and other target cells occurs, enhancing furthercell recognition.[3] Overall, CD58-CD2 interactions are intricate and involved in a variety of immune regulatory responses, including antiviral, inflammation in numerousautoimmune diseases, andimmune rejections in organ transplants.[3]
CD58 is expressed on a variety of different cells, includinghematopoietic and nonhematopoietic cells.[10] More specifically, CD58 is expressed on cell surfaces, allowing for effector-target adhesion sequentially toantigen recognition.[11] This adhesion allows for proper T cell activation via correct cell signaling.
The composition of CD2 and CD58 share many similarities. Both extracellular domains have similaramino acid sequences which aid in cell adhesion.[12] This allows for a high affinity of the extracellular amino-terminal sequence on CD2 to bind with CD58, which has a capacity to bind to CD2 on T cells, on target cells.[12][13] For aregulatory T cell to become activated, the recognition of an antigen located within amajor histocompatibility complex (MHC) protein by the TcR, orT cell receptor, is insufficient.[14] Proliferation of regulatory T cells requires the TcR recognition and other co-stimulatory signals.[15] The binding of CD2-CD58 allows for the formation of a co-stimulatorysignal, contributing to further regulatory T cell proliferation and regulation of T cell responses via signaling transduction.[15][16]
The CD58 glycoprotein can be found in two differentprotein isoforms, each on the cell surface.[17] These includetransmembrane andGPI-anchored form.[17] It has been found that in both isoforms, CD58 is able to interact with a variety of differentkinases, and is not dependent on only one form.[17] Rather, each isoform is able to associate more effectively with different kinases.[18] Each form, transmembrane and GPI-anchored, can be found in different parts of thecell membrane. The GPI-anchored isoform is mostly found inlipid rafts while the transmembrane isoform is mainly found in nonraft domains.[18] Despite this, the transmembrane CD58 form can trigger independent signaling without the need for the GPI-anchored isoform.[18] Transmembrane CD58 has a structure that consists of sixN-linked glycosylation sites in the extracellular domain, a hydrophobic transmembrane domain, and finally a shortcytoplasmic domain.[19] GPI-anchored CD58 has a similar extracellular domain, but no hydrophobic transmembrane domain or cytoplasmic domain.[19] Rather, it is linked to the cell membrane via aGPI tail. It is estimated that the CD58 structure is made of approximately 44-68%carbohydrate.[19] The structure of CD58 also plays a role in cell adhesion. A study found that effective cell adhesion was dependent on the density of CD58.[20] Comparing the GPI-anchored and transmembrane isoforms, the GPI-anchored is much more efficient during cell adhesion, and on average, takes much less time than the transmembrane isoform.[20] Regardless, the structure of both the GPI-anchor and transmembrane CD58 are crucial in overall function. While the GPI-anchor enhances cell adhesion, the transmembrane isoform is more efficient in cell signal transduction.[3]
Multiple Sclerosis (MS) is autoimmune disease that effects thecentral nervous system (CNS). In an individual with MS, theimmune system attacks themyelin sheath, which are crucial for covering nerve fibers and allowing proper communication with thebrain and the rest of the body.[21] A genomic association study suggested that there is a risk of developing MS in individuals with allelic variation in the CD58 genecoding region.[22] Further research done on the topic suggested that there is a strong association betweenCD58single-nucleotide polymorphism (SNP) rs12044852 and the onset of MS.[23] Another study focused on the (SNP) rs1414273 in the microRNA-548acstem-loop region of the CD58 gene.[24] More specifically, the SNP was found to have an influence onDrosha cleavage activity, which can cause uncoupling of the expression of CD58 and microRNA-548ac production.[24] The data from the study also showedcarriers of theallele rs1414273 showed an overall decrease in CD58mRNA levels.[24] However, the carriers of the allele did exhibit an increase in the levels of hsa-miR-548ac.[24] There is an influence between CD58 and susceptibility to MS. On a similar note, agenome wide association study found that the SNP rs1335532 was associated with a decrease in the susceptibility of developing MS.[25] In addition, it was found that in individuals with MS had an increase in CD58 mRNA.[25] This was because the region where rs1335532 resides had certain properties that increased the activity of CD58 inlymphoblasts.[25] The protective rs1335532 allele also targeted theWnt signaling pathway by creating a binding site forASCL2, atranscription factor and target of the Wnt signaling pathway.[25] In immune cells likemonocytes and primaryB-cells, the Wnt signaling pathway activation causes an increase in CD58 promotor activity via a strongbinding site of ASCL2.[25] A reduced expression of CD58 is a possible risk for developing MS.
Rheumatoid arthritis (RA) is an autoimmune disease that mainly affects an individual'sjoints, but can affect and cause problems in different tissues.[26] A study that usedenzyme-linked immunosorbent assay (ELISA) to measure sCD58 (soluble form of CD58) in individuals with RA and normal controls (NC) to determine if there was a correlation between sCD58 levels and RA.[27] It was found that sCD58 levels were significantly lower in the individuals with RA compared to those in the control (NC).[27] The sCD58 levels in the synovial fluid (SF) of the individuals with RA were also lower than the control subjects.[27] A decrease in sCD58 production could cause a decrease in CD2-CD58 adhesion, leading to an increase in T cells.[28] Continuedinflammation would also be an effect of the decrease in sCD58.[28]
