Role of Rab3 GDP/GTP Exchange Protein in Synaptic Vesicle Trafficking at the Mouse Neuromuscular Junction

The Rab3 small G protein family consists of four members, Rab3A, -3B, -3C, and -3D. Of these members, Rab3A regulates Ca2+-dependent neurotransmitter release. These small G proteins are activated by Rab3 GDP/GTP exchange protein (Rab3 GEP). To determine the function of Rab3 GEP during neurotransmitter release, we have knocked out Rab3 GEP in mice. Rab3 GEP−/− mice developed normally but died immediately after birth. Embryos at E18.5 showed no evoked action potentials of the diaphragm and gastrocnemius muscles in response to electrical stimulation of the phrenic and sciatic nerves, respectively. In contrast, axonal conduction of the spinal cord and the phrenic nerve was not impaired. Total numbers of synaptic vesicles, especially those docked at the presynaptic plasma membrane, were reduced at the neuromuscular junction ∼10-fold compared with controls, whereas postsynaptic structures and functions appeared normal. Thus, Rab3 GEP is essential for neurotransmitter release and probably for formation and trafficking of the synaptic vesicles.

Homologs of the Xenopus developmental gene DG42 are present in zebrafish and mouse and are involved in the synthesis of Nod-like chitin oligosaccharides during early embryogenesis.

The Xenopus developmental gene DG42 is expressed during early embryonic development, between the midblastula and neurulation stages. The deduced protein sequence of Xenopus DG42 shows similarity to Rhizobium Nod C, Streptococcus Has A, and fungal chitin synthases. Previously, we found that the DG42 protein made in an in vitro transcription/translation system catalyzed synthesis of an array of chitin oligosaccharides. Here we show that cell extracts from early Xenopus and zebrafish embryos also synthesize chitooligosaccharides. cDNA fragments homologous to DG42 from zebrafish and mouse were also cloned and sequenced. Expression of these homologs was similar to that described for Xenopus based on Northern and Western blot analysis. The Xenopus anti-DG42 antibody recognized a 63-kDa protein in extracts from zebrafish embryos that followed a similar developmental expression pattern to that previously described for Xenopus. The chitin oligosaccharide synthase activity found in extracts was inactivated by a specific DG42 antibody; synthesis of hyaluronic acid (HA) was not affected under the conditions tested. Other experiments demonstrate that expression of DG42 under plasmid control in mouse 3T3 cells gives rise to chitooligosaccharide synthase activity without an increase in HA synthase level. A possible relationship between our results and those of other investigators, which show stimulation of HA synthesis by DG42 in mammalian cell culture systems, is provided by structural analyses to be published elsewhere that suggest that chitin oligosaccharides are present at the reducing ends of HA chains. Since in at least one vertebrate system hyaluronic acid formation can be inhibited by a pure chitinase, it seems possible that chitin oligosaccharides serve as primers for hyaluronic acid synthesis.

Distribution of parthenogenetic cells in the mouse brain and their influence on brain development and behavior.

A systematic analysis of parthenogenetic (PG) cell fate within the central nervous system (CNS) was made throughout fetal development and neonatal and adult life. Chimeras were made between PG embryos carrying a ubiquitously expressed lacZ transgene and normal fertilized embryos. After detailed histological analysis, we find that the developmental potential of PG cells is spatially restricted to certain parts of the brain. PG cells are prevalent in telencephalic structures and are largely excluded from diencephalic structures, especially the hypothalamus. These spatial restrictions are established early in development. Behavioral studies with chimeras identified an increase in male aggression when the proportion of PG cells in the brain was high. These studies demonstrate that imprinted genes play key roles in development of the CNS and may be involved in behavior.

The preimplantation mouse embryo is a target for cannabinoid ligand-receptor signaling.

Using a reverse transcription-coupled PCR, we demonstrated that both brain and spleen type cannabinoid receptor (CB1-R and CB2-R, respectively) mRNAs are expressed in the preimplantation mouse embryo. The CB1-R mRNA expression was coincident with the activation of the embryonic genome late in the two-cell stage, whereas the CB2-R mRNA was present from the one-cell through the blastocyst stages. The major psychoactive component of marijuana (-)-delta-9-tetrahydrocannabinol [(-)-THC] inhibited forskolin-stimulated cAMP generation in the blastocyst, and this inhibition was prevented by pertussis toxin. However, the inactive cannabinoid cannabidiol (CBD) failed to influence this response. These results suggest that cannabinoid receptors in the embryo are coupled to inhibitory guanine nucleotide binding proteins. Further, the oviduct and uterus exhibited the enzymatic capacity to synthesize the putative endogenous cannabinoid ligand arachidonylethanolamide (anandamide). Synthetic and natural cannabinoid agonists [WIN 55,212-2, CP 55,940, (-)-THC, and anandamide], but not CBD or arachidonic acid, arrested the development of two-cell embryos primarily between the four-cell and eight-cell stages in vitro in a dose-dependent manner. Anandamide also interfered with the development of eight-cell embryos to blastocysts in culture. The autoradiographic studies readily detected binding of [3H]anandamide in embryos at all stages of development. Positive signals were present in one-cell embryos and all blastomeres of two-cell through four-cell embryos. However, most of the binding sites in eight-cell embryos and morulae were present in the outer cells. In the blastocyst, these signals were primarily localized in the mural trophectoderm with low levels of signals in the polar trophectoderm, while little or no signals were noted in inner cell mass cells.These results establish that the preimplantation mouse embryo is a target for cannabinoid ligands. Consequently, many of the adverse effects of cannabinoids observed during pregnancy could be mediated via these cannabinoid receptors. Although the physiological significance of the cannabinoid ligand-receptor signaling in normal preimplantation embryo development is not yet clear, the regulation of embryonic cAMP and/or Ca2+ levels via this signaling pathway may be important for normal embryonic development and/or implantation.