Subpopulations of vomeronasal sensory neurons with coordinated coexpression of type 2 vomeronasal receptor genes are differentially dependent on Vmn2r1.

The mouse vomeronasal organ is specialized in the detection of pheromones. Vomeronasal sensory neurons (VSNs) express chemosensory receptors of two large gene repertoires, V1R and V2R, which encode G-protein-coupled receptors. Phylogenetically, four families of V2R genes can be discerned as follows: A, B, C, and D. VSNs located in the basal layer of the vomeronasal epithelium coordinately coexpress V2R genes from two families: Approximately half of basal VSNs coexpress Vmn2r1 of family C with a single V2R gene of family A8-10, B, or D ('C1 type of V2Rs'), and the other half coexpress Vmn2r2 through Vmn2r7 of family C with a single V2R gene of family A1-6 ('C2 type V2Rs'). The regulatory mechanisms of the coordinated coexpression of V2Rs from two families remain poorly understood. Here, we have generated two mouse strains carrying a knockout mutation in Vmn2r1 by gene targeting in embryonic stem cells. These mutations cause a differential decrease in the numbers of VSNs expressing a given C1 type of V2R. There is no compensatory expression of Vmn2r2 through Vmn2r7. VSN axons coalesce into glomeruli in the appropriate region of the accessory olfactory bulb in the absence of Vmn2r1. Gene expression profiling by NanoString reveals a differential and graded decrease in the expression levels across C1 type of V2Rs. There is no change in the expression levels of C2 type of V2Rs, with two exceptions that we reclassified as C1 type. Thus, there appears to be a fixed probability of gene choice for a given C2 type of V2R.

A family of nonclassical class I MHC genes contributes to ultrasensitive chemodetection by mouse vomeronasal sensory neurons.

The mouse vomeronasal organ (VNO) has a pivotal role in chemical communication. The vomeronasal sensory neuroepithelium consists of distinct populations of vomeronasal sensory neurons (VSNs). A subset of VSNs, with cell bodies in the basal part of the basal layer, coexpress Vmn2r G-protein-coupled receptor genes with H2-Mv genes, a family of nine nonclassical class I major histocompatibility complex genes. The in vivo, physiological roles of the H2-Mv gene family remain mysterious more than a decade after the discovery of combinatorial H2-Mv gene expression in VSNs. Here, we have taken a genetic approach and have deleted the 530 kb cluster of H2-Mv genes in the mouse germline by chromosome engineering. Homozygous mutant mice (ΔH2Mv mice) are viable and fertile. There are no major anatomical defects in their VNO and accessory olfactory bulb (AOB). Their VSNs can be stimulated with chemostimuli (peptides and proteins) to the same maximum responses as VSNs of wild-type mice, but require much higher concentrations. This physiological phenotype is displayed at the single-cell level and is cell autonomous: single V2rf2-expressing VSNs, which normally coexpress H2-Mv genes, display a decreased sensitivity to a peptide ligand in ΔH2Mv mice, whereas single V2r1b-expressing VSNs, which do not coexpress H2-Mv genes, show normal sensitivity to a peptide ligand in ΔH2Mv mice. Consistent with the greatly decreased VSN sensitivity, ΔH2Mv mice display pronounced deficits in aggressive and sexual behaviors. Thus, H2-Mv genes are not absolutely essential for the generation of physiological responses, but are required for ultrasensitive chemodetection by a subset of VSNs.

Identification of transcriptional regulatory elements for Ntng1 and Ntng2 genes in mice.

BACKGROUND: Higher brain function is supported by the precise temporal and spatial regulation of thousands of genes. The mechanisms that underlie transcriptional regulation in the brain, however, remain unclear. The Ntng1 and Ntng2 genes, encoding axonal membrane adhesion proteins netrin-G1 and netrin-G2, respectively, are paralogs that have evolved in vertebrates and are expressed in distinct neuronal subsets in a complementary manner. The characteristic expression patterns of these genes provide a part of the foundation of the cortical layer structure in mammals. RESULTS: We used gene-targeting techniques, bacterial artificial chromosome (BAC)-aided transgenesis techniques, and in vivo enhancer assays to examine transcriptional mechanisms in vivo to gain insight into how the characteristic expression patterns of these genes are acquired. Analysis of the gene expression patterns in the presence or absence of netrin-G1 and netrin-G2 functional proteins allowed us to exclude the possibility that a feedback or feedforward mechanism mediates their characteristic expression patterns. Findings from the BAC deletion series revealed that widely distributed combinations of cis-regulatory elements determine the differential gene expression patterns of these genes and that major cis-regulatory elements are located in the 85-45 kb upstream region of Ntng2 and in the 75-60 kb upstream region and intronic region of Ntng1. In vivo enhancer assays using 2-kb evolutionarily conserved regions detected enhancer activity in the distal upstream regions of both genes. CONCLUSIONS: The complementary expression patterns of Ntng1 and Ntng2 are determined by transcriptional cis-regulatory elements widely scattered in these loci. The cis-regulatory elements characterized in this study will facilitate the development of novel genetic tools for functionally dissecting neural circuits to better understand vertebrate brain function.

Monoclonal antibodies discriminating netrin-G1 and netrin-G2 neuronal pathways.

Netrin-G1 and netrin-G2, belonging to a vertebrate-specific subfamily of the netrin family, distribute on axons of distinct neuronal pathways. To add to the array of molecular probes available for labeling unique neuronal circuits, we generated monoclonal antibodies against the netrin-G1 and netrin-G2 proteins. The monoclonal antibody clones 171A18 and 30B15 differentially labeled specific neuronal circuits, the so-called netrin-G1 or netrin-G2 circuits in mice, respectively. Epitope mapping revealed linear epitopes for these monoclonal antibodies, which are common among splicing variants, and suggested that the anti-netrin-G1 monoclonal antibodies are applicable to various species including humans.

Axonal netrin-Gs transneuronally determine lamina-specific subdendritic segments.

Axons from a distinct group of neurons make contact with dendritic trees of target neurons in clearly segregated and laminated patterns, thereby forming functional units for processing multiple inputs of information in the vertebrate central nervous system. Whether and how dendrites acquire lamina-specific properties corresponding to each pathway is not known. We show here that vertebrate-specific membrane-anchored members of the UNC-6/netrin family, netrin-G1 and -G2, organize the lamina/pathway-specific differentiation of dendrites. Netrin-G1 and -G2 distribute on axons of different pathways and specifically interact with receptors NGL-1 and -2, respectively. In the hippocampus, parietal cortex, and piriform cortex, NGL-1 is concentrated in the dendritic segments corresponding to the lamina-specific termination of netrin-G1-positive axons, and NGL-2 is concentrated in distinct dendritic segments corresponding to the termination of netrin-G2-positive axons. In netrin-G1- and -G2-deficient mice, in which axonal path-finding is normal, the segmental distribution of NGL-1 and -2 is selectively disrupted, and the individual receptors are diffused along the dendrites. These findings indicate that transneuronal interactions of netrin-Gs and their specific receptors provide a molecular basis for the axonal innervation-dependent mechanism of postsynaptic membrane organization, and provide insight into the formation of the laminar structure within the dendrites.