Christina Claxton

Lamellipodia mediate the heterogeneity of central olfactory ensheathing cell interactions

The growth and guidance of primary olfactory axons are partly attributed to the presence of olfactory ensheathing cells (OECs). However, little is understood about the differences between the subpopulations of OECs and what regulates their interactions. We used OEC-axon assays and determined that axons respond differently to peripheral and central OECs. We then further purified OECs from anatomically distinct regions of the olfactory bulb. Cell behaviour assays revealed that OECs from the olfactory bulb were a functionally heterogeneous population with distinct differences which is consistent with their proposed roles in vivo. We found that the heterogeneity was regulated by motile lamellipodial waves along the shaft of the OECs and that inhibition of lamellipodial wave activity via Mek1 abolished the ability of the cells to distinguish between each other. These results demonstrate that OECs from the olfactory bulb are a heterogeneous population that use lamellipodial waves to regulate cell–cell recognition.

Motile membrane protrusions regulate cell–cell adhesion and migration of olfactory ensheathing glia

Olfactory ensheathing cells (OECs) are candidates for therapeutic approaches for neural regeneration due to their ability to assist axon regrowth in central nervous system lesion models. However, little is understood about the processes and mechanisms underlying migration of these cells. We report here that novel lamellipodial protrusions, termed lamellipodial waves, are integral to OEC migration. Time‐lapse imaging of migrating OECs revealed that these highly dynamic waves progress along the shaft of the cells and are crucial for mediating cell–cell adhesion. Without these waves, cell–cell adhesion does not occur and migrational rates decline. The activity of waves is modulated by both glial cell line‐derived neurotrophic factor and inhibitors of the JNK and SRC kinases. Furthermore, the activity of lamellipodial waves can be modulated by Mek1, independently of leading edge activity. The ability to selectively regulate cell migration via lamellipodial waves has implications for manipulating the migratory behavior of OECs during neural repair.

Stimulation of olfactory ensheathing cell motility enhances olfactory axon growth

Axons of primary olfactory neurons are intimately associated with olfactory ensheathing cells (OECs) from the olfactory epithelium until the final targeting of axons within the olfactory bulb. However, little is understood about the nature and role of interactions between OECs and axons during development of the olfactory nerve pathway. We have used high resolution time-lapse microscopy to examine the growth and interactions of olfactory axons and OECs in vitro. Transgenic mice expressing fluorescent reporters in primary olfactory axons (OMP-ZsGreen) and ensheathing cells (S100ß-DsRed) enabled us to selectively analyse these cell types in explants of olfactory epithelium. We reveal here that rather than providing only a permissive substrate for axon growth, OECs play an active role in modulating the growth of pioneer olfactory axons. We show that the interactions between OECs and axons were dependent on lamellipodial waves on the shaft of OEC processes. The motility of OECs was mediated by GDNF, which stimulated cell migration and increased the apparent motility of the axons, whereas loss of OECs via laser ablation of the cells inhibited olfactory axon outgrowth. These results demonstrate that the migration of OECs strongly regulates the motility of axons and that stimulation of OEC motility enhances axon extension and growth cone activity.

Complementary and layered expression of Ephs and ephrins in developing mouse inner ear.

The distributions of the Eph‐class receptors EphA4 and EphB1, and their ligands ephrin‐A2, ephrin‐B1, and ephrin‐B2, were analysed by immunostaining in the mouse inner ear. Complementary patterns of EphA4 and its potential ligand ephrin‐A2 were found, with ephrin‐A2 in many of the structures lining the cochlear duct and within the cochlear nerve cells, and EphA4 in the deeper structures underlying the cochlear duct and in the cells lining the nerve pathway. EphB1 and its potential ligands ephrin‐B1 and ephrin‐B2 showed a segregated layered expression in the lateral wall of the cochlear duct (the external sulcus), which together with EphA4 expressed in the area, form a four‐layered structure with an alternating pattern of receptors and ligands in the different layers. This arrangement gives the potential for different bidirectional Eph‐mediated interactions between each of the layers. The results suggest that the Eph system in the cochlea may have a role in maintaining cell segregation during phases of cochlear development. J. Comp. Neurol. 449:207–216, 2002.

Expression of EphA4 in developing inner ears of the mouse and guinea pig

The expression of EphA4, an Eph-class receptor tyrosine kinase, was determined by immunohistochemistry in developing inner ears of the mouse and the guinea pig. In the mouse, EphA4 expression was visible in the fibroblasts of the spiral ligament and in the structures that were to become the osseous spiral lamina. Cochlear nerve ganglion cells expressed ephrin-B2, and the modiolus expressed mRNA coding for ephrin-B3, both transmembrane ligands for EphA4. In contrast, in the guinea pig, cells of the cochlear nerve ganglion expressed EphA4, as did supporting cells of the organ of Corti (Hensens cells and inner pillar cells). There was also some expression in fibroblasts of the spiral ligament but none in the structures that were to become the osseous spiral lamina. It is suggested that in the mouse, EphA4 may help direct the cochlear innervation towards the organ of Corti by a repulsive interaction, but that this is highly species dependent.

BOC, brother of CDO, is a dorsoventral axon‐guidance molecule in the embryonic vertebrate brain

The early axon scaffolding in the embryonic vertebrate brain consists of a series of ventrally projecting axon tracts that grow into a single major longitudinal pathway connected across the midline by commissures. We have investigated the role of Brother of CDO (BOC), an immunoglobulin (Ig) superfamily member distantly related to the Roundabout (Robo) family of axon‐guidance receptors, in the development of this embryonic template of axon tracts in the zebrafish brain. A zebrafish homologue of BOC was isolated and shown to be expressed predominantly in the developing neural plate and later in the neural tube and developing brain. Zebrafish boc was initially highly localized to discrete bands in the mid‐ and hindbrain, but, as the major brain subdivisions emerged, it became more evenly expressed along the rostrocaudal axis, particularly in dorsal regions. The function of zebrafish boc was examined by a loss‐of‐function approach. Analysis of embryos injected with antisense morpholinos designed against boc revealed highly selective defects in the development of dorsoventrally projecting axon tracts. Loss of boc caused ventrally projecting axons, particularly those arising from the presumptive telencephalon, to follow aberrant trajectories. These data indicate that boc is an axon‐guidance molecule playing a fundamental role in pathfinding during the early patterning of the axon scaffold in the embryonic vertebrate brain. J. Comp. Neurol. 485:32–42, 2005.

Yap Controls Stem/Progenitor Cell Proliferation in the Mouse Postnatal Epidermis

Tissue renewal is an ongoing process in the epithelium of the skin. We have begun to examine the genetic mechanisms that control stem/progenitor cell activation in the postnatal epidermis. The conserved Hippo pathway regulates stem cell turnover in arthropods through to vertebrates. Here we show that its downstream effector, yes-associated protein (YAP), is active in the stem/progenitor cells of the postnatal epidermis. Overexpression of a C-terminally truncated YAP mutant in the basal epidermis of transgenic mice caused marked expansion of epidermal stem/progenitor cell populations. Our data suggest that the C-terminus of YAP controls the balance between stem/progenitor cell proliferation and differentiation in the postnatal interfollicular epidermis. We conclude that YAP functions as a molecular switch of stem/progenitor cell activation in the epidermis. Moreover, our results highlight YAP as a possible therapeutic target for diseases such as skin cancer, psoriasis, and epidermolysis bullosa.

Fibroblast Growth Factor Receptor‐4 Splice Variants Cause Deletion of a Critical Tyrosine

We have identified two novel isoforms of fibroblast growth factor receptor‐4 (FGFR4). They result from alternative splicing of intron 17. Two transcripts, both slightly larger than the one coding for the known mouse FGFR4, are generated. The shortest (FGFR4‐17a) includes the 31‐most 3‐nucleotides of intron 17; the longest (FGFR4‐17b) includes all 114 nucleotides of intron 17. Translation of the FGFR4‐17a and FGFR4‐17b splice variants predicts that both novel putative FGFR4 isoforms have a truncated C‐terminal intracellular tail. The first amino acid residue affected by the insertions in both novel isoforms is Tyr‐760, a residue that may play a crucial role in intracellular signaling through stimulation of the phosphatidylinositol‐biphosphate pathway.

Growth cone dynamics in the zebrafish embryonic forebrain are regulated by Brother of Cdo

During development of the embryonic zebrafish brain, the differential expression of axon guidance molecules directs the growth of axons along defined neuronal tracts. Neurons within the dorsorostral cluster of the presumptive telencephalon project axons ventrally along the supraoptic tract. Brother of Cdo (Boc) is a known axon guidance molecule that is expressed in a broad band lying ventral to the dorsorostral cluster of neurons. Loss of Boc function has previously been shown to perturb the development of the supraoptic tract. We have used live cell imaging of individual growth cones within the living zebrafish embryo to determine how Boc regulates the growth cone dynamics and axon guidance within the supraoptic tract. A plasmid construct encoding elavl3-eGFP was injected into early embryos to selectively label a small number of neurons while the expression of Boc was knocked down by injection of antisense morpholino oligonucleotides. Time-lapse imaging of growth cones within the living embryos revealed that loss of Boc significantly affected the morphology of growth cones in comparison to axons within control embryos. Growth cones navigating along the supraoptic tract in the absence of Boc extended significantly longer filopodia in the rostrocaudal direction. These results indicate that Boc acts to restrict axons and their filopodia within the narrow pathway of the supraoptic tract. The highly selective nature of these pathfinding defects reveal that Boc is likely to be one of many molecules that coordinate the trajectory of axons within the supraoptic tract.

A tyrosine kinase screen of mouse vestibular maculae

Receptor tyrosine kinases allow extracellular signals to influence intracellular events, while other tyrosine kinases are involved in intracellular signalling. They may therefore be involved in the development, maintenance and repair of the sensory epithelia of the inner ear, since these are believed to be affected by inter- and intracellular signalling. In order to analyse possible tyrosine kinases expressed in sensory areas of the inner ear, a reverse transcription polymerase chain reaction screen of microdissected sensory epithelia was undertaken, using primers targeted at conserved sequences in tyrosine kinase domains. Tissue was taken from the maculae of the mouse vestibular organs, and consisted mainly of hair cells and their supporting cells. Of 80 clones sequenced, 49 coded for tyrosine kinases, and 11 for other known molecules. Further analysis of one of the sequences, for FGF receptor 4, showed a novel variant, expressed in the inner ear and elsewhere, with a variation in the intracellular domain which suggests differential activation of known signalling pathways. Other clones coded for tyrosine kinases expected to be involved in cell surface and intracellular signalling. The technique forms a powerful tool for analysing a range of the tyrosine kinases expressed, and provides a starting point for the analysis of cell-cell signalling in the inner ear.