Hematopoietic origin of pathological grooming in Hoxb8 mutant mice.

Mouse Hoxb8 mutants show unexpected behavior manifested by compulsive grooming and hair removal, similar to behavior in humans with the obsessive-compulsive disorder spectrum disorder trichotillomania. As Hox gene disruption often has pleiotropic effects, the root cause of this behavioral deficit was unclear. Here we report that, in the brain, Hoxb8 cell lineage exclusively labels bone marrow-derived microglia. Furthermore, transplantation of wild-type bone marrow into Hoxb8 mutant mice rescues their pathological phenotype. It has been suggested that the grooming dysfunction results from a nociceptive defect, also exhibited by Hoxb8 mutant mice. However, bone marrow transplant experiments and cell type-specific disruption of Hoxb8 reveal that these two phenotypes are separable, with the grooming phenotype derived from the hematopoietic lineage and the sensory defect derived from the spinal cord cells. Immunological dysfunctions have been associated with neuropsychiatric disorders, but the causative relationships are unclear. In this mouse, a distinct compulsive behavioral disorder is associated with mutant microglia.

A Microglia Sublineage Protects from Sex-Linked Anxiety Symptoms and Obsessive Compulsion.

Aberrant microglia activity is associated with many neurological and psychiatric disorders, yet our knowledge about the pathological mechanisms is incomplete. Here, we describe a genetically defined microglia sublineage in mice which has the ability to suppress obsessive compulsion and anxiety symptoms. These microglia derive from precursors expressing the transcription factor Hoxb8. Selective ablation of Hoxb8-lineage microglia or the Hoxb8 gene revealed that dysfunction in this cell type causes severe over-grooming and anxiety-like behavior and stress responses. Moreover, we show that the severity of the pathology is set by female sex hormones. Together, our findings reveal that different microglia lineages have distinct functions. In addition, our data suggest a mechanistic link between biological sex and genetics, two major risk factors for developing anxiety and related disorders in humans.

The KLP-6 kinesin is required for male mating behaviors and polycystin localization in Caenorhabditis elegans.

BACKGROUND: Male mating behavior of the nematode Caenorhabditis elegans offers an intriguing model to study the genetics of sensory behavior, cilia function, and autosomal dominant polycystic kidney disease (ADPKD). The C. elegans polycystins LOV-1 and PKD-2 act in male-specific sensory cilia required for response and vulva-location mating behaviors. RESULTS: Here, we identify and characterize a new mating mutant, sy511. sy511 behavioral phenotypes were mapped to a mutation in the klp-6 locus, a gene encoding a member of the kinesin-3 family (previously known as the UNC-104/Kif1A family). KLP-6 has a single homolog of unknown function in vertebrate genomes, including fish, chicken, mouse, rat, and human. We show that KLP-6 expresses exclusively in sensory neurons with exposed ciliated endings and colocalizes with the polycystins in cilia of male-specific neurons. Cilia of klp-6 mutants appear normal, suggesting a defect in sensory neuron function but not development. KLP-6 structure-function analysis reveals that the putative cargo binding domain directs the motor to cilia. Consistent with a motor-cargo association between KLP-6 and the polycystins, klp-6 is required for PKD-2 localization and function within cilia. Genetically, we find klp-6 regulates behavior through polycystin-dependent and -independent pathways. CONCLUSION: Multiple ciliary transport pathways dependent on kinesin-II, OSM-3, and KLP-6 may act sequentially to build cilia and localize sensory ciliary membrane proteins such as the polycystins. We propose that KLP-6 and the polycystins function as an evolutionarily conserved ciliary unit. KLP-6 promises new routes to understanding cilia function, behavior, and ADPKD.

Distinct protein domains regulate ciliary targeting and function of C. elegans PKD-2.

TRPP2 (transient receptor potential polycystin-2) channels function in a range of cells where they are localized to specific subcellular regions including the endoplasmic reticulum (ER) and primary cilium. In humans, TRPP2/PC-2 mutations severely compromise kidney function and cause autosomal dominant polycystic kidney disease (ADPKD). The Caenorhabditis elegans TRPP2 homolog, PKD-2, is restricted to the somatodendritic (cell body and dendrite) and ciliary compartments of male specific sensory neurons. Within these neurons PKD-2 function is required for sensation. To understand the mechanisms regulating TRPP2 subcellular distribution and activity, we performed in vivo structure-function-localization studies using C. elegans as a model system. Our data demonstrate that somatodendritic and ciliary targeting requires the transmembrane (TM) region of PKD-2 and that the PKD-2 cytosolic termini regulate subcellular distribution and function. Within neuronal cell bodies, PKD-2 colocalizes with the OSM-9 TRP vanilloid (TRPV) channel, suggesting that these TRPP and TRPV channels may function in a common process. When human TRPP2/PC-2 is heterologously expressed in transgenic C. elegans animals, PC-2 does not visibly localize to cilia but does partially rescue pkd-2 null mutant defects, suggesting that human PC-2 and PKD-2 are functional homologs.