Myelin oligodendrocyte glycoprotein

Myelin oligodendrocyte glycoprotein (MOG) is a glycoprotein believed to be important in the myelination of nerves in the central nervous system (CNS). In humans this protein is encoded by the MOG gene.^[5][6][7] It is speculated to serve as a necessary "adhesion molecule" to provide structural integrity to the myelin sheath and is known to develop late on the oligodendrocyte.^{[8][full citation needed]}

MOG
Available structures PDB Ortholog search: PDBe RCSB List of PDB id codes 1Q70
Identifiers
Aliases	MOG, BTN6, BTNL11, MOGIG2, NRCLP7, myelin oligodendrocyte glycoprotein
External IDs	OMIM: 159465; MGI: 97435; HomoloGene: 111009; GeneCards: MOG; OMA:MOG - orthologs
Gene location (Human) Chr. Chromosome 6 (human)[1] Band 6p22.1 Start 29,657,002 bp[1] End 29,672,372 bp[1]
Gene location (Mouse) Chr. Chromosome 17 (mouse)[2] Band 17 B1|17 19.16 cM Start 37,321,635 bp[2] End 37,334,290 bp[2]
RNA expression pattern Bgee Human Mouse (ortholog) Top expressed in C1 segment substantia nigra hippocampus proper putamen primary visual cortex temporal lobe amygdala caudate nucleus Brodmann area 9 corpus callosum Top expressed in deep cerebellar nuclei lumbar subsegment of spinal cord lateral geniculate nucleus globus pallidus ventral tegmental area pontine nuclei medial geniculate nucleus central gray substance of midbrain nucleus of stria terminalis dorsal tegmental nucleus More reference expression data BioGPS n/a
Gene ontology Molecular function virus receptor activity signaling receptor binding Cellular component integral component of membrane plasma membrane membrane external side of plasma membrane Biological process central nervous system development viral entry into host cell cell adhesion viral process regulation of immune response T cell receptor signaling pathway Sources:Amigo / QuickGO
Orthologs Species Human Mouse Entrez 4340 17441 Ensembl ENSG00000234096 ENSG00000232641 ENSG00000137345 ENSG00000230885 ENSG00000236561 ENSG00000237834 ENSG00000204655 ENSG00000234623 ENSMUSG00000076439 UniProt Q16653 Q61885 RefSeq (mRNA) NM_001008228 NM_001008229 NM_001170418 NM_002433 NM_206809 NM_206810 NM_206811 NM_206812 NM_206813 NM_206814 NM_001363610 NM_010814 RefSeq (protein) NP_001008229 NP_001008230 NP_001163889 NP_002424 NP_996532 NP_996533 NP_996534 NP_996535 NP_996537 NP_001350539 NP_034944 Location (UCSC) Chr 6: 29.66 – 29.67 Mb Chr 17: 37.32 – 37.33 Mb PubMed search [3] [4]
Wikidata
View/Edit Human View/Edit Mouse

Molecular function

While the primary molecular function of MOG is not yet known, its likely role with the myelin sheath is either in sheath "completion and/or maintenance".^[7] More specifically, MOG is speculated to be "necessary" as an "adhesion molecule" on the myelin sheath of the CNS to provide the structural integrity of the myelin sheath.^{[8][full citation needed]}"

MOG's cDNA coding region in humans have been shown to be "highly homologous"^[9] to rats, mice, and bovine, and hence highly conserved. This suggests "an important biological role for this protein".^[7]

Physiology

The gene for MOG, found on chromosome 6 p21.3-p22,^[10] was first sequenced in 1995. It is a transmembrane protein expressed on the surface of oligodendrocyte cell and on the outermost surface of myelin sheaths. "MOG is a quantitatively minor type I transmembrane protein,^[11] and is found exclusively in the CNS. "A single Ig-domain is exposed to the extracellular space"^[11] and consequently allows autoantibodies easy access. and therefore is easily accessible to autoantibodies too.^[7][11] The MOG "primary nuclear transcript … is 15,561 nucleotides in length"^[7] and, for humans, it has eight exons which are "separated by seven introns".^[7] The introns "contain numerous reptitive [sic] DNA^[7]" sequences, among which are "14 Alu sequences within 3 introns",^[7] and have a range varying from 242 to 6484 bp.

Structure

Alternatively spliced human mRNA of the MOG gene form at least nine isoforms.^[12]

The crystal structure of myelin oligodendrocyte glycoprotein was determined by x-ray diffraction at a resolution of 1.45 Angstroms, using protein from the Norway rat. This protein is 139 residues long, and is a member of the immunoglobulin superfamily.^[13] The dssp secondary structure of the protein is 6% helical and 43% beta sheet: there are three short helical segments and ten beta strands.^[14] The beta strands are within two antiparallel beta sheets that form an immunoglobulin-like beta-sandwich fold.^[15] Several features of the protein structure suggest MOG has a role as an "adhesin in the completion and/or compaction of the myelin sheath." There is a "significant strip" of electronegative charge beginning near the N-terminus and running about half the length of the molecule. Also, MOG was shown to dimerize in solution, and the shape complementarity index is high at the dimer interface, suggesting a "biologically relevant MOG dimer."^[16]

Synthesis

Developmentally, MOG is formed "very late on oligodendrocytes and the myelin sheath".^{[8][full citation needed]}

Role in disease

Non-inflammatory demyelinating diseases

Interest in MOG has centered on its role in demyelinating diseases. Some of them are not-inflammatory, such as adrenoleukodystrophy, vanishing white matter disease, and Rubella induced mental retardation.^[17]

Anti-MOG associated inflammatory demyelinating diseases

Main article: antiMOG associated encephalomyelitis

MOG has received much of its laboratory attention in studies dealing with MS. Several studies have shown a role for antibodies against MOG in the pathogenesis of MS,^{[8][full citation needed][18]} though most of them were written before the discovery of NMO-IgG and the NMO spectrum of diseases.

Anti-MOG status is different depending whether it is measured by ELISA or by microarray (CBA). The proper way to identify it is by microarray, reacting patient serum with living cells, and detecting the binding IgG via a fluorescent-labeled secondary antibody.^[19]

In animal models

Animal models of MS, namely Experimental Autoimmune Encephalomyelitis (EAE) models, have shown that "MOG-specific EAE models (of different animal strains) display/mirror human multiple sclerosis",^{[8][full citation needed]} but basically explains the part involved in the optic neuritis.^[20] These models with anti-MOG antibodies have been investigated extensively and are considered the only antibodies with demyelinating capacity^{[8][full citation needed]} but again, EAE pathology is closer to NMO and ADEM than to the confluent demyelination observed in MS.

Anti-MOG antibodies have been shown to behave similarly to AQP4 antibodies in animal models,^[20] and are considered a biomarker against the MS diagnosis^[21][22]

In seronegative neuromyelitis optica

Anti-MOG autoimmunity has been found to be involved in most AQP4-seronegative NMO^[23][24] and also in optic neuritis and some fulminant forms of ADEM.^[25] MOG antibodies in NMOSD are variable depending on the seropositivity status.^[26]

In other conditions

The presence of anti-MOG autoantibodies has been associated with the following conditions^[27]

• Most cases of aquaporin-4-seronegative neuromyelitis optica: NMO derived from an antiMOG associated encephalomyelitis,^[28]
• Some cases of acute disseminated encephalomyelitis, specially the recurrent ones (MDEM)^[29] and the fulminant courses^[25]
• Some cases of multiple sclerosis^[27]
• isolated optic neuritis or transverse myelitis^[27]