BEN as a presumptive target recognition molecule during the development of the olivocerebellar system.

It has been shown previously that in the chick embryo the cell adhesion molecule BEN/SC1/DM-GRASP is expressed by neurons in the inferior olive (IO) and by their terminal axonal arbors in the cerebellar cortex, the climbing fibers (Porquié et al., 1992b). Here, new information on the expression of BEN during the formation of the olivocerebellar projection adds the important notion that BEN is also expressed by the cerebellar targets of inferior olivary axons, Purkinje cells (PCs) and deep nuclear neurons. This expression is transient, starting at E7-E8 and vanishing shortly after hatching. More importantly, BEN expression is restricted to precise subsets of IO neurons and PCs. In the cerebellar cortex, BEN-immunoreactive (BEN-IR) structures are not found randomly but are distributed according to a reproducible pattern of parasagittal stripes. A maximum of four distinct sagittal stripes is found in each lobule, along the whole rostrocaudal extent of the cerebellum. Moreover, BEN-expressing stripes belong to two classes; one contains BEN-IR climbing fibers terminating on BEN-IR PCs and the other, more frequent class is solely composed of BEN-IR climbing fibers. Organotypic cultures of isolated cerebella have shown that the expression of BEN in the IO and in the cerebellum arise independently, probably because of an intrinsic developmental program. Thus, the cell adhesion molecule BEN meets all criteria for a recognition molecule involved in the formation of the olivocerebellar projection.

[Early ontogeny of the human hematopoietic system]. / Ontogénèse précoce du système hématopoïétique humain.

Immunohistochemistry was used to detect markers of the vascular, stromal and hematopoietic cell compartments in the human embryo and early fetus, from 3 to 15 weeks of gestation. CD34 expression was consistently observed at the surface of vascular endothelial cells from off earliest stages tested, at the single exception of embryonic liver blood vessels. Yolk sac hematopoiesis was very transient and limited to primitive erythropoiesis. Clusters of erythroblasts, monocytes and granulocytes appeared from 4 to 5 weeks of gestation in the liver rudiment. The early development of the bone marrow was marked by the rapid invasion, at 8 weeks, of long bone cartilaginous rudiments by CD68+ osteoclast precursors, CD34+ endothelial cells and by preosteoblasts, leading to the development of large vascular sinuses between ossifying trabeculae. Endogenous erythro- and granulopoiesis developed from week 11 in primary logettes always organized around an arteriole, in a loose stromal mesenchymal network established between the media of these arterioles and the sinusal endothelium. Round, hematopoietic CD34+ cells were seen occasionally in yolk sac blood vessels. In the liver they were rare and intermingled as single cells in the hepatocyte cords; strikingly, CD34+ hematopoietic cells could seldom be detected in the developing bone marrow. In contrast, compact clusters of non-endothelial, round CD34+ CD45+ hematopoietic cells were detected, during the 5th week of development, in close association with the ventral wall of the dorsal aorta. These cells exhibit phenotypic and functional characteristics of very primitive hematopoietic progenitors. This observation is in striking correlation with the evidence accumulated in animal models that stem cells for the late embryonic and adult hematopoietic systems develop inside the embryo per se, in the vicinity of the dorsal aorta. We thus suggest that these aorta-associated CD34+ cells, that exhibit an anatomic localization similar to that of the intraembryonic stem cells identified in the avian and murine embryo, are the real stem of human hematopoiesis.