Abstract
Nowadays, great efforts are made to gain insight into the molecular mechanisms that underlie structural neuronal plasticity. Moreover, the identification of signaling pathways involved in the development of psychiatric disorders aids the screening of possible therapeutic targets. Genetic variations or alterations in GPM6A expression are linked to neurological disorders such as schizophrenia, depression, and Alzheimer’s disease. GPM6A encodes the neuronal surface glycoprotein M6a that promotes filopodia/spine, dendrite, and synapse formation by unknown mechanisms. A substantial body of evidence suggests that the extracellular loops of M6a command its function. However, the proteins that associate with them and that modulate neuronal plasticity have not been determined yet. To address this question, we generated a chimera protein that only contains the extracellular loops of M6a and performed a co-immunoprecipitation with rat hippocampus samples followed by TMT/MS. Here, we report 72 proteins, which are good candidates to interact with M6a’s extracellular loops and modify its function. Gene ontology (GO) analysis showed that 63% of the potential M6a’s interactor proteins belong to the category “synapse,” at both sides of the synaptic cleft, “neuron projections” (51%) and “presynapse” (49%). In this sense, we showed that endogenous M6a interacts with piccolo, synaptic vesicle protein 2B, and synapsin 1 in mature cultured hippocampal neurons. Interestingly, about 28% of the proteins left were related to the “myelin sheath” annotation, suggesting that M6a could interact with proteins at the surface of oligodendrocytes. Indeed, we demonstrated the (cis and trans) interaction between M6a and proteolipid protein (PLP) in neuroblastoma N2a cells. Finally, the 72 proteins were subjected to disease-associated genes and variants screening by DisGeNET. Apart from the diseases that have already been associated with M6a, most of the proteins are also involved in “autistic disorder,” “epilepsy,” and “seizures” increasing the spectrum of disorders in which M6a could play a role. Data are available via ProteomeXchange with identifier PXD017347.
Highlights
The membrane glycoprotein M6a—together with proteolipid protein Proteolipid Protein 1 (PLP1), DM20, and M6b—belongs to the tetraspan PLP family (Schweitzer et al, 2006)
The cellular and molecular mechanisms governing the formation of synapses and developmental plasticity, including the roles of cell-cell recognition molecules, cell adhesion molecules, growth factors, electrical activity among others are critical for the normal brain development
We used a co-immunoprecipitation assay (co-IP)-Tandem Mass Tag (TMT)/Mass spectrometry (MS) approach followed by bioinformatics analysis, and we identified 72 potential M6a’s interactors of which four proteins were confirmed by colocalization
Summary
The membrane glycoprotein M6a—together with proteolipid protein PLP1, DM20, and M6b—belongs to the tetraspan PLP family (Schweitzer et al, 2006). Variations in Gpm6a expression are linked to chronic stress/depression, claustrophobia, and Alzheimer’s disease (Alfonso et al, 2005; El-Kordi et al, 2013; Lachén-Montes et al, 2016). The specific tetraspanin functions in different cell types depending on their heterotypic association—within the TEMs—with different partner proteins. In this regard, a large number of different partner molecules might explain why tetraspanins are involved in such a wide variety of essential cellular processes. The EC2 contains all of the known tetraspanin protein-protein interaction sites, and monoclonal antibodies that recognize cell surface epitopes so far exclusively recognize the EC2 domain. Whereas the EC1 is necessary for correct surface expression of the protein and it is responsible for EC2-interactor binding strength (Murru et al, 2018)
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