Brain functions rely on specific patterns of connectivity. Teneurins are evolutionarily conserved transmembrane proteins that instruct synaptic partner matching in Drosophila and are required for vertebrate visual system development. The roles of vertebrate teneurins in connectivity beyond the visual system remain largely unknown and their mechanisms of action have not been demonstrated. Here we show that mouse teneurin-3 is expressed in multiple topographically interconnected areas of the hippocampal region, including proximal CA1, distal subiculum, and medial entorhinal cortex. Viral-genetic analyses reveal that teneurin-3 is required in both CA1 and subicular neurons for the precise targeting of proximal CA1 axons to distal subiculum. Furthermore, teneurin-3 promotes homophilic adhesion in vitro in a splicing isoform-dependent manner. These findings demonstrate striking genetic heterogeneity across multiple hippocampal areas and suggest that teneurin-3 may orchestrate the assembly of a complex distributed circuit in the mammalian brain via matching expression and homophilic attraction.
X-linked diseases typically exhibit more severe phenotypes in males than females. In contrast, protocadherin 19 (PCDH19) mutations cause epilepsy in heterozygous females but spare hemizygous males. The cellular mechanism responsible for this unique pattern of X-linked inheritance is unknown. We show that PCDH19 contributes to adhesion specificity in a combinatorial manner such that mosaic expression of Pcdh19 in heterozygous female mice leads to striking sorting between cells expressing wild-type (WT) PCDH19 and null PCDH19 in the developing cortex, correlating with altered network activity. Complete deletion of PCDH19 in heterozygous mice abolishes abnormal cell sorting and restores normal network activity. Furthermore, we identify variable cortical malformations in PCDH19 epilepsy patients. Our results highlight the role of PCDH19 in determining cell adhesion affinities during cortical development and the way segregation of WT and null PCDH19 cells is associated with the unique X-linked inheritance of PCDH19 epilepsy.
Protocadherin 19 (Pcdh19) is an X-linked gene belonging to the protocadherin superfamily, whose members are predominantly expressed in the central nervous system and have been implicated in cell-cell adhesion, axon guidance and dendrite self-avoidance. Heterozygous loss-of-function mutations in humans result in the childhood epilepsy disorder PCDH19 Girls Clustering Epilepsy (PCDH19 GCE) indicating that PCDH19 is required for brain development. However, understanding PCDH19 function in vivo has proven challenging and has not been studied in mammalian models. Here, we validate a murine Pcdh19 null allele in which a β-Geo reporter cassette is expressed under the control of the endogenous promoter. Analysis of β-Geo reporter activity revealed widespread but restricted expression of PCDH19 in embryonic, postnatal and adult brains. No gross morphological defects were identified in Pcdh19+/β-Geo and Pcdh19Y/β-Geo brains and the location of Pcdh19 null cells was normal. However, in vitro migration assays revealed that the motility of Pcdh19 null neurons was significantly elevated, potentially contributing to pathogenesis in patients with PCDH19 mutations. Overall our initial characterization of Pcdh19+/β-Geo, Pcdh19β-Geo/β-Geo and Pcdh19Y/β-Geomice reveals that despite widespread expression of Pcdh19 in the CNS, and its role in human epilepsy, its function in mice is not essential for brain development.
Mammalian medial and lateral hippocampal networks preferentially process spatial- and object-related information, respectively. However, the mechanisms underlying the assembly of such parallel networks during development remain largely unknown. Our study shows that, in mice, complementary expression of cell surface molecules teneurin-3 (Ten3) and latrophilin-2 (Lphn2) in the medial and lateral hippocampal networks, respectively, guides the precise assembly of CA1-to-subiculum connections in both networks. In the medial network, Ten3-expressing (Ten3+) CA1 axons are repelled by target-derived Lphn2, revealing that Lphn2- and Ten3-mediated heterophilic repulsion and Ten3-mediated homophilic attraction cooperate to control precise target selection of CA1 axons. In the lateral network, Lphn2-expressing (Lphn2+) CA1 axons are confined to Lphn2+ targets via repulsion from Ten3+ targets. Our findings demonstrate that assembly of parallel hippocampal networks follows a “Ten3→Ten3, Lphn2→Lphn2” rule instructed by reciprocal repulsions.
Gene duplication provides spare genetic material that evolution can craft into new functions. and are evolutionarily related genes with overlapping and unique sites of expression during embryogenesis. It is currently unclear whether SOX2 and SOX3 have identical or different functions. Here, we use CRISPR/Cas9-assisted mutagenesis to perform a gene-swap, replacing the ORF with the ORF to investigate their functional equivalence in the brain and testes. We show that increased expression of SOX2 can functionally replace SOX3 in the development of the infundibular recess/ventral diencephalon, and largely rescues pituitary gland defects that occur in null mice. We also show that ectopic expression of SOX2 in the testes functionally rescues the spermatogenic defect of null mice, and restores gene expression to near normal levels. Together, these data provide strong evidence that SOX2 and SOX3 proteins are functionally equivalent.
Spatial-and object-related signals are preferentially processed through the medial and lateral hippocampal networks (MHN and LHN), respectively 1,2 . MHN comprises interconnected medial entorhinal cortex, proximal CA1 (pCA1), and distal subiculum (dSub), whereas the LHN comprises interconnected lateral entorhinal cortex, distal CA1, and proximal subiculum 3,4 . Previously, we showed that Teneurin-3 (Ten3) has matching expression in all interconnected regions of the MHN and is required in both CA1 and subiculum for the precise pCA1→dSub axon targeting through homophilic attraction 5 . Can matching gene expression in interconnected nodes of the LHN also contribute to hippocampal network assembly? Here, we discovered that latrophilin-2 (Lphn2), an adhesion GPCR known to bind teneurins 6-8 , has matching expression in the LHN that is complementary to Ten3. Viral-genetic perturbations in vivo revealed that Ten3+ pCA1 axons are repelled by ectopic expression of Lphn2 in dSub, and ectopically invade proximal subiculum deleted for Lphn2. Simultaneous subiculum deletion of Lphn2 and Ten3 causes Ten3+ pCA1 axon mistargeting reflecting loss of both repulsion and attraction. Our findings demonstrate that Lphn2 acts as a repulsive ligand for Ten3+ axons, identify Ten3 as a receptor for both repulsive and attractive ligands in the same axon during target choice, and reveal how a 'Ten3→Ten3, Lphn2→Lphn2' rule directs the precise assembly of functional hippocampal networks.In order for the central nervous system to accurately process information, neurons must connect precisely with their correct targets. Neuronal circuit assembly can generally be divided into three steps: 1) axons are guided to the appropriate anatomical region; 2) axons select specific target neurons within the region; and 3) axons form synapses with target neurons 9 . Molecular mechanisms underlying axon guidance and synapse formation/organization have been revealed over the last several decades 10-12 . Less is known about the mechanisms of target selection, particularly in complex circuits of the central mammalian brain. The differential expression of cell surface molecules plays a critical role in allowing discrete neuronal circuits to be formed precisely 9,13 . For example, a pair of evolutionarily conserved type II transmembrane proteins,
SummaryX-linked diseases typically exhibit more severe phenotypes in males than females. In contrast, Protocadherin 19 (PCDH19) mutations cause epilepsy in heterozygous females but spare hemizygous males. The cellular mechanism responsible for this unique pattern of X-linked inheritance is unknown. We show that PCDH19 contributes to highly specific combinatorial adhesion codes such that mosaic expression of Pcdh19 in heterozygous female mice leads to striking sorting between WT PCDH19-and null PCDH19-expressing cells in the developing cortex, correlating with altered network activity. Complete deletion of PCDH19 in heterozygous mice abolishes abnormal cell sorting and restores normal network activity. Furthermore, we identify variable cortical malformations in PCDH19 epilepsy patients. Our results highlight the role of PCDH19 in determining specific adhesion codes during cortical development and how disruption of these codes is associated with the unique X-linked inheritance of PCDH19 epilepsy.
The formation of neural circuits requires extensive interactions of cell-surface proteins to guide axons to their correct target neurons. Trans-cellular interactions of the adhesion G protein-coupled receptor latrophilin-2 (Lphn2) with its partner teneurin-3 instruct the precise assembly of hippocampal networks by reciprocal repulsion. Lphn2 acts as a receptor in distal CA1 neurons to direct their axons to proximal subiculum, and as a repulsive ligand in proximal subiculum to direct proximal CA1 axons to distal subiculum. It remains unclear if Lphn2-mediated intracellular signaling is required for its role in either context. Here, we show that Lphn2 couples to Gα12/13 in heterologous cells, which is increased by constitutive exposure of the tethered agonist. Specific mutations of Lphn2’s tethered agonist region disrupt its G protein coupling and autoproteolytic cleavage, whereas mutating the autoproteolytic cleavage site prevents cleavage but preserves a functional tethered agonist. Using an in vivo misexpression assay, we demonstrate that wild-type Lphn2 misdirects proximal CA1 axons to proximal subiculum and that Lphn2 tethered agonist activity is required for its role as a repulsive receptor. By contrast, neither tethered agonist activity nor autoproteolysis was necessary for Lphn2’s role as a repulsive ligand. Thus, tethered agonist activity is required for Lphn2-mediated neural circuit assembly in a context-dependent manner.
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