Neural cell adhesion molecule (NCAM), also called CD56, is a homophilic binding glycoprotein expressed on the surface of
neurons,
glia and
skeletal muscle. Although CD56 is often considered a marker of neural lineage commitment due to its discovery site, CD56 expression is also found in, among others, the
hematopoietic system. Here, the expression of CD56 is mostly associated with, but not limited to,
natural killer cells. CD56 has been detected on other lymphoid cells, including
gamma delta (γδ) Τ cells and activated
CD8+ T cells, as well as on dendritic cells.[5] NCAM has been implicated as having a role in cell–cell adhesion,[6] neurite outgrowth, synaptic plasticity, and learning and memory.
Forms, domains and homophilic binding
NCAM is a glycoprotein of Immunoglobulin (Ig) superfamily.
At least 27 alternatively spliced NCAM mRNAs are produced, giving a wide diversity of NCAM isoforms.[7] The three main isoforms of NCAM vary only in their
cytoplasmic domain:
NCAM-120kDa (GPI anchored)
NCAM-140kDa (short cytoplasmic domain)
NCAM-180kDa (long cytoplasmic domain)
The extracellular domain of NCAM consists of five
immunoglobulin-like (Ig) domains followed by two fibronectin type III (FNIII) domains. The different domains of NCAM have been shown to have different roles, with the Ig domains being involved in homophilic binding to NCAM, and the FNIII domains being involved signalling leading to neurite outgrowth.
Homophilic binding occurs between NCAM molecules on opposing surfaces (trans-) and NCAM molecules on the same surface (cis-)1. There is much controversy as to how exactly NCAM homophilic binding is arranged both in trans- and cis-. Current models suggest trans- homophilic binding occurs between two NCAM molecules binding antiparallel between all five Ig domains or just IgI and IgII. cis- homophilic binding is thought to occur by interactions between both IgI and IgII, and IgI and IgIII, forming a higher order NCAM multimer. Both cis- and trans- NCAM homophilic binding have been shown to be important in NCAM “activation” leading to neurite outgrowth.
Minor exons
Another layer of complexity is created by the insertion of other "minor" exons in the NCAM transcript. The two most notable are:
the VASE (VAriable domain Spliced Exon) exon which is thought to correlate with an inhibition of the neurite outgrowth promoting properties of NCAM.
the MSD (Muscle Specific Domain), which is thought to play a positive role in myoblast fusion.[8] In skeletal muscle it is found in all three NCAM isoforms, increasing their
MW, giving NCAM-125, NCAM-145, and NCAM-185 isoforms, but is most commonly found in the NCAM-125 isoform.[8]
Posttranslational modification
NCAM exhibits
glycoforms as it can be posttranslationally modified by the addition of
polysialic acid (PSA) to the fifth Ig domain, which is thought to abrogate its homophilic binding properties and can lead to reduced cell adhesion important in cell migration and invasion. PSA has been shown to be critical in learning and memory. Removal of PSA from NCAM by the enzyme
endoneuraminidase (EndoN) has been shown to abolish
long-term potentiation (LTP) and
long-term depression (LTD).[9][10][11]
Later in development, NCAM1 (CD56) expression is found on various differentiated tissues and is a major CAM mediating adhesion among neurons and between neurons and muscle.
A member of the NCAM superfamily, NCAM2 gene has been observed progressively downregulated in
human papillomavirus-positive
neoplastic keratinocytes derived from uterine cervical
preneoplastic lesions at different levels of malignancy.[12] For this reason, NCAM2 is likely to be associated with tumorigenesis and may be a potential prognostic marker for uterine cervical
preneoplastic lesions progression.[12]
Alzheimer's disease
NCAM2 is found in lower levels in hippocampal synapses of Alzheimer's disease sufferers and is found to be broken down by
beta-amyloid.[13]
Rabies
NCAM has been identified as one of the target proteins for the rabies virus, allowing entry into the cell.[14]
Anti-NCAM therapy
NCAM has been used as a target molecule for experimental antibody-based immunotherapy. Successful radio-immunolocalisation of metastases was demonstrated after giving injections of NCAM-binding 123J-UJ13a or 131J-UJ13a radio-immunoconjugates to children with neuroblastoma. Patients with small cell lung cancer were treated with the anti-NCAM immunotoxin huN901-DM1 in two different clinical studies, revealing acceptable toxicity and signs of clinical response.[15]
^Becker CG, Artola A, Gerardy-Schahn R, Becker T, Welzl H, Schachner M (July 1996). "The polysialic acid modification of the neural cell adhesion molecule is involved in spatial learning and hippocampal long-term potentiation". Journal of Neuroscience Research. 45 (2): 143–52.
doi:
10.1002/(SICI)1097-4547(19960715)45:2<143::AID-JNR6>3.0.CO;2-A.
PMID8843031.
S2CID43042018.
^Stoenica L, Senkov O, Gerardy-Schahn R, Weinhold B, Schachner M, Dityatev A (May 2006). "In vivo synaptic plasticity in the dentate gyrus of mice deficient in the neural cell adhesion molecule NCAM or its polysialic acid". The European Journal of Neuroscience. 23 (9): 2255–64.
doi:
10.1111/j.1460-9568.2006.04771.x.
PMID16706834.
S2CID22798537.
1epf: CRYSTAL STRUCTURE OF THE TWO N-TERMINAL IMMUNOGLOBULIN DOMAINS OF THE NEURAL CELL ADHESION MOLECULE (NCAM)
1lwr: Solution structure of the NCAM fibronectin type III module 2
1qz1: Crystal Structure of the Ig 1-2-3 fragment of NCAM
2e3v: Crystal structure of the first fibronectin type III domain of neural cell adhesion molecule splicing isoform from human muscle culture lambda-4.4
2haz: Crystal structure of the first fibronectin domain of human NCAM1