Jo Begbie

CLoNe is a new method to target single progenitors and study their progeny in mouse and chick

Cell lineage analysis enables us to address pivotal questions relating to: the embryonic origin of cells and sibling cell relationships in the adult body; the contribution of progenitors activated after trauma or disease; and the comparison across species in evolutionary biology. To address such fundamental questions, several techniques for clonal labelling have been developed, each with its shortcomings. Here, we report a novel method, CLoNe that is designed to work in all vertebrate species and tissues. CLoNe uses a cocktail of labelling, targeting and transposition vectors that enables targeting of specific subpopulations of progenitor types with a combination of fluorophores resulting in multifluorescence that describes multiple clones per specimen. Furthermore, transposition into the genome ensures the longevity of cell labelling. We demonstrate the robustness of this technique in mouse and chick forebrain development, and show evidence that CLoNe will be broadly applicable to study clonal relationships in different tissues and species.

Cranial neural crest cells form corridors prefiguring sensory neuroblast migration.

The majority of cranial sensory neurons originate in placodes in the surface ectoderm, migrating to form ganglia that connect to the central nervous system (CNS). Interactions between inward-migrating sensory neuroblasts and emigrant cranial neural crest cells (NCCs) play a role in coordinating this process, but how the relationship between these two cell populations is established is not clear. Here, we demonstrate that NCCs generate corridors delineating the path of migratory neuroblasts between the placode and CNS in both chick and mouse. In vitro analysis shows that NCCs are not essential for neuroblast migration, yet act as a superior substrate to mesoderm, suggesting provision of a corridor through a less-permissive mesodermal territory. Early organisation of NCC corridors occurs prior to sensory neurogenesis and can be recapitulated in vitro; however, NCC extension to the placode requires placodal neurogenesis, demonstrating reciprocal interactions. Together, our data indicate that NCC corridors impose physical organisation for precise ganglion formation and connection to the CNS, providing a local environment to enclose migrating neuroblasts and axonal processes as they migrate through a non-neural territory.

The formation of the cranial ganglia by placodally-derived sensory neuronal precursors

The generation of the sensory ganglia involves the migration of a precursor population to the site of ganglion formation and the differentiation of sensory neurons. There is, however, a significant difference between the ganglia of the head and trunk in that while all of the sensory neurons of the trunk are derived from the neural crest, the majority of cranial sensory neurons are generated by the neurogenic placodes. In this study, we have detailed the route through which the placodally-derived sensory neurons are generated, and we find a number of important differences between the head and trunk. Although, the neurogenic placodes release neuroblasts that migrate internally to the site of ganglion formation, we find that there are no placodally-derived progenitor cells within the forming ganglia. The cells released by the placodes differentiate during migration and contribute to the cranial ganglia as post-mitotic neurons. In the trunk, it has been shown that progenitor cells persist in the forming Dorsal Root Ganglia and that much of the process of sensory neuronal differentiation occurs within the ganglion. We also find that the period over which neuronal cells delaminate from the placodes is significantly longer than the time frame over which neural crest cells populate the DRGs. We further show that placodal sensory neuronal differentiation can occur in the absence of local cues. Finally, we find that, in contrast to neural crest cells, the different mature neurogenic placodes seem to lack plasticity. Nodose neuroblasts cannot be diverted to form trigeminal neurons and vice versa.

The formation of the superior and jugular ganglia: Insights into the generation of sensory neurons by the neural crest

The superior and jugular ganglia (S/JG) are the proximal ganglia of the IXth and Xth cranial nerves and the sensory neurons of these ganglia are neural crest derived. However, it has been unclear the extent to which their differentiation resembles that of the Dorsal Root Ganglia (DRGs). In the DRGs, neural crest cells undergo neuronal differentiation just after the onset of migration and there is evidence suggesting that these cells are pre‐specified towards a sensory fate. We have analysed sensory neuronal differentiation in the S/JG. We show, in keeping with previous studies, that neuronal differentiation initiates long after the cessation of neural crest migration. We also find no evidence for the existence of migratory neural crest cells pre‐specified towards a sensory phenotype prior to ganglion formation. Rather our results suggest that sensory neuronal differentiation in the S/JG is the result of localised spatiotemporal cues. Developmental Dynamics 239:439–445, 2010.

Structural Mechanism for Modulation of Synaptic Neuroligin-Neurexin Signaling by MDGA Proteins

Summary Neuroligin-neurexin (NL-NRX) complexes are fundamental synaptic organizers in the central nervous system. An accurate spatial and temporal control of NL-NRX signaling is crucial to balance excitatory and inhibitory neurotransmission, and perturbations are linked with neurodevelopmental and psychiatric disorders. MDGA proteins bind NLs and control their function and interaction with NRXs via unknown mechanisms. Here, we report crystal structures of MDGA1, the NL1-MDGA1 complex, and a spliced NL1 isoform. Two large, multi-domain MDGA molecules fold into rigid triangular structures, cradling a dimeric NL to prevent NRX binding. Structural analyses guided the discovery of a broad, splicing-modulated interaction network between MDGA and NL family members and helped rationalize the impact of autism-linked mutations. We demonstrate that expression levels largely determine whether MDGAs act selectively or suppress the synapse organizing function of multiple NLs. These results illustrate a potentially brain-wide regulatory mechanism for NL-NRX signaling modulation.

Migration of Neuroblasts from Neurogenic Placodes

Peripheral neurons involved in cephalic sensory systems are born in the ectoderm at a distance from the neural tube. The neuroblasts migrate internally, coalesce to form ganglia and extend axons to the central nervous system. This process has long been evident but little is known about the way it occurs. We have shown that coordination of the migration and integration with the hindbrain occurs through interaction with neural crest cells.

Separating Early Sensory Neuron and Blood Vessel Patterning

The anatomical association between sensory nerves and blood vessels is well recognised in the adult, and interactions between the two are important during development. Here we have examined the relationship between developing blood vessels and sensory neuronal cell bodies, which is less well understood. We show in the chick that the nascent dorsal root ganglia (DRG) lie dorsal to the longitudinal anastomosis, adjacent to the developing neural tube at the level of the sulcus limitans. Furthermore, the blood vessel is present prior to the neurons suggesting that it may play a role in positioning the DRG. We use the zebrafish cloche mutation to analyse DRG formation in the absence of blood vessels and show that the DRG are positioned normally. Thus, despite their close anatomical relationship, the patterning of the blood vessel and DRG alongside the neural tube is separable rather than interdependent. Developmental Dynamics 239:3297–3302, 2010.

Absence of Tangentially Migrating Glutamatergic Neurons in the Developing Avian Brain

Summary Several neuronal populations orchestrate neocortical development during mammalian embryogenesis. These include the glutamatergic subplate-, Cajal-Retzius-, and ventral pallium-derived populations, which coordinate cortical wiring, migration, and proliferation, respectively. These transient populations are primarily derived from other non-cortical pallial sources that migrate to the dorsal pallium. Are these migrations to the dorsal pallium conserved in amniotes or are they specific to mammals? Using in ovo electroporation, we traced the entire lineage of defined chick telencephalic progenitors. We found that several pallial sources that produce tangential migratory neurons in mammals only produced radially migrating neurons in the avian brain. Moreover, ectopic expression of VP-specific mammalian Dbx1 in avian brains altered neurogenesis but did not convert the migration into a mammal-like tangential movement. Together, these data indicate that tangential cellular contributions of glutamatergic neurons originate from outside the dorsal pallium and that pallial Dbx1 expression may underlie the generation of the mammalian neocortex during evolution.

Changes in gene expression and cell shape characterise stages of epibranchial placode‐derived neuron maturation in the chick

Sensory neurons in the head are largely generated from neurogenic placodes. Previous studies have revealed early events in placode development; however, the process of maturation has not been studied. In this study, it has been shown that placodal neurogenesis follows a sequential progression with distinct stages defined by expression of specific markers. These markers highlight domains of maturation within the stream of migratory neuroblasts that extend between the placode and the neural tube. Commitment to neurogenesis occurs in the apical placode, with the newborn neuroblasts delaminating basally and entering a transition zone. The neuroblasts migrate through the transition zone, differentiating further and becoming post‐mitotic as they approach the ganglionic anlage. It has further been demonstrated that this progression from the transition zone to the ganglionic anlage is accompanied by a switch from multipolar to bipolar cell morphology. This sequential progression parallels events observed elsewhere in the nervous system, but here the stages are distinct and anatomically segregated. It is proposed that placodal neurogenesis provides a tractable system to examine the transition between states in neurogenesis.

Identification of molecular signatures specific for distinct cranial sensory ganglia in the developing chick

BackgroundThe cranial sensory ganglia represent populations of neurons with distinct functions, or sensory modalities. The production of individual ganglia from distinct neurogenic placodes with different developmental pathways provides a powerful model to investigate the acquisition of specific sensory modalities. To date there is a limited range of gene markers available to examine the molecular pathways underlying this process.ResultsTranscriptional profiles were generated for populations of differentiated neurons purified from distinct cranial sensory ganglia using microdissection in embryonic chicken followed by FAC-sorting and RNAseq. Whole transcriptome analysis confirmed the division into somato- versus viscerosensory neurons, with additional evidence for subdivision of the somatic class into general and special somatosensory neurons. Cross-comparison of distinct ganglia transcriptomes identified a total of 134 markers, 113 of which are novel, which can be used to distinguish trigeminal, vestibulo-acoustic and epibranchial neuronal populations. In situ hybridisation analysis provided validation for 20/26 tested markers, and showed related expression in the target region of the hindbrain in many cases.ConclusionsOne hundred thirty-four high-confidence markers have been identified for placode-derived cranial sensory ganglia which can now be used to address the acquisition of specific cranial sensory modalities.