Diana Moss

Co-localisation, heterophilic interactions and regulated expression of IgLON family proteins in the chick nervous system.

The chick glycoprotein GP55 has been shown to inhibit the growth and adhesion of DRG and forebrain neurons. GP55 consists of several members of the IgLON family, a group of glycoproteins including LAMP, OBCAM, CEPU-1 (chick)/neurotrimin (rat) and neurotractin (chick)/kilon (rat) thought to play a role in the guidance of growing axons. IgLONs belong to the Ig superfamily and have three C2 domains and a glycosyl phosphatidylinositol anchor which tethers them to the neuronal plasma membrane. We have now completed the deduced amino acid sequence for two isoforms of chicken OBCAM and used recombinant LAMP, OBCAM and CEPU-1 to raise antisera specific to these three IgLONs. LAMP and CEPU-1 are co-expressed on DRG and sympathetic neurons, while both overlapping and distinct expression patterns for LAMP, OBCAM and CEPU-1 are observed in retina. Analysis of IgLON mRNA expression reveals that alternatively spliced forms of LAMP and CEPU-1 are developmentally regulated. In an attempt to understand how the IgLONs function, we have begun to characterise their molecular interactions. LAMP and CEPU-1 have already been shown to interact homophilically. We now confirm that OBCAM will bind homophilically and also that LAMP, OBCAM and CEPU-1 will interact heterophilically with each other. We propose that IgLON activity will depend on the complement of IgLONs expressed by each neuron.

Expression of cellular adhesion molecule ‘OPCML’ is down-regulated in gliomas and other brain tumours

The four GPI‐anchored cell adhesion molecules that exemplify the IgLON family are most highly expressed in the nervous system and associate to form up to six different heterodimeric ‘Diglons’ that can modify cell adhesion and inhibit axon migration. Recently, two members, OPCML and LSAMP, were identified as putative tumour suppressor genes in ovarian and renal carcinomas respectively. In this study, we investigated OPCML expression in nonneoplastic brain tissue and 35 brain tumours (18 glioblastoma multiformes, five anaplastic gliomas, five meningiomas, six metastases and one medulloblastoma) and four glioma cell lines using quantitative reverse transcriptase polymerase chain reaction (RT‐PCR). OPCML was highly expressed in cerebellum, less so in cerebral cortex, frontal lobe and meninges and was significantly reduced or absent in 83% of brain tumours and all cell lines compared with nonneoplastic whole brain. Two OPCML splice variants have been identified in humans, termed α1 and α2, but the latter has not been demonstrated in human neural tissues. Using PCR with specific primers, nonneoplastic brain and 3/6 of tested brain tumours expressed both splice variants, whereas the remaining brain tumours only expressed the α2 variant. Hypermethylation of the α1 OPCML promoter, associated with down‐regulation of expression in ovarian tumours, did not correlate with expression levels in the subset of brain tumours tested, implying transcription of OPCML from an alternative promoter or a different mechanism of down‐regulation. This study demonstrates that OPCML down‐regulation occurs in the majority of brain tumours tested, warranting further investigation of OPCML and other IgLONs in the development and progression of brain tumours.

Diglons are heterodimeric proteins composed of IgLON subunits, and Diglon-CO inhibits neurite outgrowth from cerebellar granule cells

IgLONs are a family of four cell adhesion molecules belonging to the Ig superfamily that are thought to play a role in cell-cell recognition and growth-cone migration. One member of the family, opioid-binding cell-adhesion molecule (OBCAM), might act as a tumour suppressor. Previous work has shown that limbic-system-associated protein (LAMP), CEPU-1/Neurotrimin and OBCAM interact homophilically and heterophilically within the family. Here, we show that, based on their relative affinities, CEPU-1 might be both a homo- and a heterophilic cell adhesion molecule, whereas LAMP and OBCAM act only as heterophilic cell adhesion molecules. A binding assay using recombinant IgLONs fused to human Fc showed that IgLONs are organized in the plane of the membrane as heterodimers, and we propose that IgLONs function predominantly as subunits of heterodimeric proteins (Diglons). Thus, the four IgLONs can form six Diglons. Furthermore, although singly transfected cell lines have little effect on neurite outgrowth, CHO cell lines expressing both CEPU-1 and OBCAM (Diglon-CO) inhibit neurite outgrowth from cerebellar granule cells.

Assessing the Efficacy of Nano- and Micro-Sized Magnetic Particles as Contrast Agents for MRI Cell Tracking

Iron-oxide based contrast agents play an important role in magnetic resonance imaging (MRI) of labelled cells in vivo. Currently, a wide range of such contrast agents is available with sizes varying from several nanometers up to a few micrometers and consisting of single or multiple magnetic cores. Here, we evaluate the effectiveness of these different particles for labelling and imaging stem cells, using a mouse mesenchymal stem cell line to investigate intracellular uptake, retention and processing of nano- and microsized contrast agents. The effect of intracellular confinement on transverse relaxivity was measured by MRI at 7 T and in compliance with the principles of the ‘3Rs’, the suitability of the contrast agents for MR-based cell tracking in vivo was tested using a chick embryo model. We show that for all particles tested, relaxivity was markedly reduced following cellular internalisation, indicating that contrast agent relaxivity in colloidal suspension does not accurately predict performance in MR-based cell tracking studies. Using a bimodal imaging approach comprising fluorescence and MRI, we demonstrate that labelled MSC remain viable following in vivo transplantation and can be tracked effectively using MRI. Importantly, our data suggest that larger particles might confer advantages for longer-term imaging.

Overexpression of the MRI Reporter Genes Ferritin and Transferrin Receptor Affect Iron Homeostasis and Produce Limited Contrast in Mesenchymal Stem Cells

Imaging technologies that allow the non-invasive monitoring of stem cells in vivo play a vital role in cell-based regenerative therapies. Recently, much interest has been generated in reporter genes that enable simultaneous monitoring of the anatomical location and viability of cells using magnetic resonance imaging (MRI). Here, we investigate the efficacy of ferritin heavy chain-1 (Fth1) and transferrin receptor-1 (TfR1) as reporters for tracking mesenchymal stem cells. The overexpression of TfR1 was well tolerated by the cells but Fth1 was found to affect the cell’s iron homeostasis, leading to phenotypic changes in the absence of iron supplementation and an upregulation in transcript and protein levels of the cell’s endogenous transferrin receptor. Neither the sole overexpression of Fth1 nor TfR1 resulted in significant increases in intracellular iron content, although significant differences were seen when the two reporter genes were used in combination, in the presence of high concentrations of iron. The supplementation of the culture medium with iron sources was a more efficient means to obtain contrast than the use of reporter genes, where high levels of intracellular iron were reflected in transverse (T2) relaxation. The feasibility of imaging iron-supplemented cells by MRI is shown using a 3R-compliant chick embryo model.

Promotion of neuronal cell adhesion by members of the IgLON family occurs in the absence of either support or modification of neurite outgrowth

The IgLONs are a family of glycosyl phosphatidyl inositol‐linked cell adhesion molecules which are thought to modify neurite outgrowth and may play a role in cell–cell recognition. The family consists of LAMP, OBCAM, neurotrimin/CEPU‐1 and neurotractin/kilon. In this paper we report the effect of recombinant LAMP, CEPU‐1 and OBCAM, and transfected cell lines expressing these molecules, on the adhesion and outgrowth of dorsal root ganglion (DRG) and sympathetic neurones. CHO cells transfected with cDNA for CEPU‐1 adhered to a recombinant CEPU‐1‐Fc substrate. However, DRG or sympathetic neurones only adhered to CEPU‐1‐Fc when presented on protein A. Although DRG and sympathetic neurones express IgLONs on their surface, both types of neurones exhibited differential adhesion to CEPU‐1‐Fc, LAMP‐Fc and OBCAM‐Fc. Neither DRG nor sympathetic neurones extended neurites on a protein A/IgLON‐Fc substrate and overexpression of CEPU‐1‐GFP in DRG neurones also failed to stimulate neurite outgrowth on an IgLON‐Fc substrate. DRG neurones adhered to and extended neurites equally on transfected and non‐transfected cell lines and the recombinant proteins did not modulate the outgrowth of neurones on laminin. In contrast to previous reports we suggest that IgLONs may not have a primary role in axon guidance but may be more important for cell–cell adhesion and recognition.

Identification and Characterization of CEPU-Se—A Secreted Isoform of the IgLON Family Protein, CEPU-1

CEPU-1/Neurotrimin is a neuronal glycoprotein thought to play a role in axon guidance and cell-cell recognition. It is a member of the IgLON family, has three C2 domains, and is attached to the plasma membrane by a GPI-anchor. We report here the characterisation of an alternatively-spliced isoform of CEPU-1 that is secreted. This isoform, termed CEPU-Se, is coexpressed with CEPU-1 in retina, cerebellum, and DRG neurons. In the cerebellum CEPU-1/CEPU-Se is expressed predominantly on granule cells and in the molecular layer. Divalent but not monovalent CEPU-Se interacts with CEPU-1 and other IgLONs, suggesting that the ability of CEPU-Se to modify the activity of the IgLON family may require an additional cofactor. CEPU-Se does not support the outgrowth of DRG neurons or the extension of established growth cones; however, neurite outgrowth on laminin is unaffected by CEPU-Se. Our data suggest that CEPU-Se may act to modulate the ability of CEPU-1, LAMP, and OBCAM to influence neurite outgrowth.

An Evaluation of a SVA Retrotransposon in the FUS Promoter as a Transcriptional Regulator and Its Association to ALS

Genetic mutations of FUS have been linked to many diseases including Amyotrophic Lateral Sclerosis (ALS) and Frontotemporal Lobar Degeneration. A primate specific and polymorphic retrotransposon of the SINE-VNTR-Alu (SVA) family is present upstream of the FUS gene. Here we have demonstrated that this retrotransposon can act as a classical transcriptional regulatory domain in the context of a reporter gene construct both in vitro in the human SK-N-AS neuroblastoma cell line and in vivo in a chick embryo model. We have also demonstrated that the SVA is composed of multiple distinct regulatory domains, one of which is a variable number tandem repeat (VNTR). The ability of the SVA and its component parts to direct reporter gene expression supported a hypothesis that this region could direct differential FUS expression in vivo. The SVA may therefore contribute to the modulation of FUS expression exhibited in and associated with neurological disorders including ALS where FUS regulation may be an important parameter in progression of the disease. As VNTRs are often clinical associates for disease progression we determined the extent of polymorphism within the SVA. In total 2 variants of the SVA were identified based within a central VNTR. Preliminary analysis addressed the association of these SVA variants within a small sporadic ALS cohort but did not reach statistical significance, although we did not include other parameters such as SNPs within the SVA or an environmental factor in this analysis. The latter may be particularly important as the transcriptional and epigenetic properties of the SVA are likely to be directed by the environment of the cell.

Evaluating the effectiveness of transferrin receptor-1 (TfR1) as a magnetic resonance reporter gene.

Magnetic resonance (MR) reporter genes have the potential for tracking the biodistribution and fate of cells in vivo, thus allowing the safety, efficacy and mechanisms of action of cell‐based therapies to be comprehensively assessed. In this study, we evaluate the effectiveness of the iron importer transferrin receptor‐1 (TfR1) as an MR reporter gene in the model cell line CHO‐K1. Overexpression of the TfR1 transgene led to a reduction in the levels of endogenous TfR1 mRNA, but to a 60‐fold increase in total TfR1 protein levels. Although the mRNA levels of ferritin heavy chain‐1 (Fth1) did not change, Fth1 protein levels increased 13‐fold. The concentration of intracellular iron increased significantly, even when cells were cultured in medium that was not supplemented with iron and the amount of iron in the extracellular environment was thus at physiological levels. However, we found that, by supplementing the cell culture medium with ferric citrate, a comparable degree of iron uptake and MR contrast could be achieved in control cells that did not express the TfR1 transgene. Sufficient MR contrast to enable the cells to be detected in vivo following their administration into the midbrain of chick embryos was obtained irrespective of the reporter gene. We conclude that TfR1 is not an effective reporter and that, to track the biodistribution of cells with MR imaging in the short term, it is sufficient to simply culture cells in the presence of ferric citrate. Copyright

DIgLONs inhibit initiation of neurite outgrowth from forebrain neurons via an IgLON-containing receptor complex.

IgLONs are a family of four GPI-anchored cell adhesion molecules that regulate neurite outgrowth, synaptogenesis and may act as tumour suppressor genes. IgLONs are thought to function as monomers or homodimers and we have proposed that IgLONs also act as heterodimeric complexes termed Dimeric IgLONs or DIgLONs. Here we show that the initiation of neurite outgrowth is inhibited from a subset of chick embryonic day (E) 7 or 8 forebrain neurons when they are cultured on CHO cell lines expressing DIgLON:CEPU-1-OBCAM and DIgLON:CEPU-1-LAMP but not on CHO cells that express single IgLONs CEPU-1 or OBCAM. Surprisingly at the younger age of E6 forebrain neurons do not respond to DIgLONs. Since there is little difference in expression of IgLONs on the surface of chick forebrain neurons at these two ages we suggest IgLONs alone are not the receptor on the responding forebrain neurons. A DIgLON heterodimeric recombinant protein DIgLON:CEPU-1-OBCAM-Fc also blocked neurite outgrowth from E8 chick forebrain neurons. However, when IgLONs were removed from the surface of these E8 neurons they no longer responded to DIgLON:CEPU-1-OBCAM-Fc substrate, indicating that IgLONs form at least a component of the neuronal cell receptor complex involved in this inhibition of neurite outgrowth. Inhibitors pertussis toxin and Y27632 reversed the inhibition of neurite outgrowth on a DIgLON:CEPU-1-OBCAM and DIgLON:CEPU-1-LAMP substrate. This suggests the involvement of a G-protein coupled receptor and activation of Rho A. In summary we provide evidence that DIgLON:CEPU-1-OBCAM and DIgLON:CEPU-1-LAMP complexes regulate initiation of neurite outgrowth on forebrain neurons via an IgLON-containing receptor complex.