Projections to the superior colliculus from inferior parietal, ventral premotor, and ventrolateral prefrontal areas involved in controlling goal-directed hand actions in the macaque.

We found that the macaque inferior parietal (PFG and anterior intraparietal [AIP]), ventral premotor (F5p and F5a), and ventrolateral prefrontal (rostral 46vc and intermediate 12r) areas forming a network involved in controlling purposeful hand actions ("lateral grasping network") are a source of corticotectal projections. Based on injections of anterograde tracers at the cortical level, the results showed that all these areas displayed relatively dense projections to the intermediate and deep gray layers of the ipsilateral superior colliculus (SC) and to the ventrally adjacent mesencephalic reticular formation. In the SC, the labeling tended to be richer in the lateral part along almost the entire rostro-caudal extent, that is, in regions controlling microsaccades and downward gaze shifts and hosting arm-related neurons and neurons modulated by the contact of the hand with the target. These projections could represent a descending motor pathway for controlling proximo-distal arm synergies. Furthermore, they could broadcast to the SC information related to hand action goals and object affordances extraction and selection. This information could be used in the SC for controlling orienting behavior (gaze and reaching movements) to the targets of object-oriented actions and for the eye-hand coordination necessary for appropriate hand-object interactions.

Connectional heterogeneity of the ventral part of the macaque area 46.

We found that the ventral part of the prefrontal area 46 (46v) is connectionally heterogeneous. Specifically, the rostral part (46vr) displayed an almost exclusive and extensive intraprefrontal connectivity and extraprefrontal connections limited to area 24 and inferotemporal areas. In contrast, the caudal part (46vc) mostly displayed intraprefrontal connectivity with ventrolateral areas and robust connectivity with frontal and parietal sensorimotor areas. Based on a topographic organization of these connections, 3 fields were identified in area 46vc. A caudal field (caudal 46vc) was preferentially connected to oculomotor prearcuate (8/FEF, 45B, and 8r) and inferior parietal areas. The other 2, located more rostrally, in the bank of the principal sulcus (rostral 46vc/bank) and on the ventrolateral convexity cortex (rostral 46vc/convexity), respectively, were connected with hand/mouth-related (F5a, 44) ventral premotor areas, area SII, and the insula. However, rostral 46vc/convexity was also connected to the hand-related area AIP, whereas rostral 46vc/bank to hand/arm-related areas PFG and PG, to PGop, and to areas 11 and 24. The present data suggest a differential role in executive functions of areas 46vr and 46vc and a differential involvement of different parts of area 46vc in higher level integration for oculomotor behavior and goal-directed arm, hand, and mouth actions.

Aggressive behaviour and physiological responses to pheromones are strongly impaired in mice deficient for the olfactory G-protein -subunit G8.

Heterotrimeric G-proteins are critical players in the transduction mechanisms underlying odorant and pheromonal signalling. In the vomeronasal organ (VNO) of the adult mouse, two different G-protein complexes have been identified. Gαoß2γ8 is preferentially expressed in the basal neurons and coexpresses with type-2 vomeronasal pheromone receptors (V2Rs) whereas Gαi2ß2γ2 is found in the apical neurons and coexpresses with type-1 vomeronasal pheromone receptors (V1Rs). V2R-expressing neurons project to the posterior accessory olfactory bulb (AOB) whereas neurons expressing V1Rs send their axon to the anterior AOB. Gγ8 is also expressed in developing olfactory neurons where this protein is probably associated with Go. Here, we generated mice with a targeted deletion of the Gγ8 gene and investigated the behavioural effects and the physiological consequences of this mutation. Gγ8(-/-) mice show a normal development of the main olfactory epithelium; moreover, they do not display major deficits in odour perception. In contrast, the VNO undergoes a slow but remarkable loss of basal neurons starting from the fourth postnatal week, with a 40% reduction of cells at 2 months and 70% at 1 year. This loss is associated with a reduced early-gene expression in the posterior AOB of mice stimulated with pheromones. More interestingly, the Gγ8 deletion specifically leads to a reduced pheromone-mediated aggressiveness in both males and females, all other socio-sexual behaviours remaining unaltered. This study defines a specific role for Gγ8 in maintenance of the neuronal population of the VNO and in the mechanisms of pheromonal signalling that involve the aggressive behaviour towards conspecifics.

Neuropeptide Y in the olfactory microvillar cells.

This paper examines a possible role of microvillar cells in coordinating cell death and regeneration of olfactory epithelial neurons. The olfactory neuroepithelium of mammals is a highly dynamic organ. Olfactory neurons periodically degenerate by apoptosis and as a consequence of chemical or physical damage. To compensate for this loss of cells, the olfactory epithelium maintains a lifelong ability to regenerate from a pool of resident multipotent stem cells. To assure functional continuity and histological integrity of the olfactory epithelium over a period of many decades, apoptosis and regeneration require to be precisely coordinated. Among the factors that have been implicated in mediating this regulation is the neuropeptide Y (NPY). Knockout mice that lack functional expression of this neurogenic peptide show defects in embryonic development of the olfactory epithelium and in its ability to regenerate in the adult. Here we show that, in postnatal olfactory epithelia, NPY is exclusively expressed by a specific population of microvillar cells. We previously characterized these cells as a novel type of putative chemosensory cells, which are provided with a phosphatidyl-inositol-mediated signal transduction cascade. Our findings allow for the first time to suggest that microvillar cells are involved in connecting apoptosis to neuronal regeneration by stimulus-induced release of NPY.