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.

•App-KI mice carrying NL-G-F mutations showed deficits in broad cognitive domains.•App-KI mice carrying NL-F mutations showed moderate abnormalities.•Gender effects were detected histopathologically in NL-G-F mice.•App-KI mice are useful as animal models for AD.Transgenic mouse models of Alzheimer’s disease (AD) with nonphysiologic overexpression of amyloid precursor protein (APP) exhibit various unnatural symptoms/dysfunctions. To overcome this issue, mice with single humanized App knock-in (KI) carrying Swedish (NL), Beyreuther/Iberian (F), and Arctic (G) mutations in different combinations were recently developed. The validity of these mouse models of AD from a behavioral viewpoint, however, has not been extensively evaluated. Thus, using an automated behavior monitoring system, we analyzed various behavioral domains, including executive function, and learning and memory. The App-KI mice carrying NL-G-F mutations showed clear deficits in spatial memory and flexible learning, enhanced compulsive behavior, and reduced attention performance. Mice carrying NL-F mutations exhibited modest abnormalities. The NL-G-F mice had a greater and more rapid accumulation of Aβ deposits and glial responses. These findings reveal that single pathologic App-KI is sufficient to produce deficits in broad cognitive domains and that App-KI mouse lines with different levels of pathophysiology are useful models of AD.Download high-res image (124KB)Download full-size image

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.

•ADHD mouse models have diversified due to the progress in human genetics.•Causal genes act on monoaminergic signaling, synaptic plasticity, and development.•Gene–gene interactions have crucial roles in attention and impulsivity.•Gene–environment interactions have crucial roles in attention and impulsivity.•Mouse models have several advantages for future studies.Increasing evidence suggests complex genetic factors for attention-deficit/hyperactivity disorder (ADHD). Animal models with definitive genetic characteristics are indispensable for gaining an understanding of the molecular, cellular, and neural circuit mechanisms underlying ADHD. Toward this aim, mice have several advantages because of their well-controlled genetic backgrounds and the relative ease with which functions of defined neuronal circuits can be manipulated. Dopamine signaling dysfunction was once the major pathogenic focus of interest in ADHD research, but hypotheses have expanded to include functionally distinct molecules. Forward and reverse genetic approaches have produced diverse mouse genetic models for genes involved in monoaminergic signaling, synaptic plasticity, and neuronal circuit formation. Data suggest crucial roles of gene–gene interactions and gene–environment interactions in the pathophysiology of ADHD.

S100B is a small calcium binding protein synthesized and secreted mostly by astrocytes. Mice devoid of S100B (S100B-KO) develop without detectable anatomic abnormalities of the brain, but exhibit enhanced hippocampal long-term potentiation and enhanced performance in hippocampus-dependent learning and memory tasks, indicating that S100B has a crucial role in hippocampal neuronal plasticity. In the present study, we examined whether S100B has a similar role in the cerebellar regions, because Bergmann glia, a specialized subset of astrocytes in the cerebellar cortex, express a particularly large amount of S100B under physiologic conditions. Unlike in the hippocampus-dependent tasks, S100B-KO mice were indistinguishable from wild-type mice in both cerebellum-dependent motor coordination and delay eyeblink conditioning, a well-established paradigm for cerebellum-dependent learning and memory. These results suggest that S100B has differential roles in the hippocampus and cerebellum.Research highlights▶ Astrocytic S100B is a crucial neuromodulator in the hippocampus. ▶ S100B is most abundant in the cerebellar cortex. ▶ Behavioral tests suggest normal cerebellar function in S100B-knockout mice. ▶ S100B does not act as a crucial neuromodulator in the cerebellum.