Cloning and identification of Rab cDNAs from Limulus polyphemus.

Small GTPases of the Rab family are essential for the control of membrane transport between intracellular compartments. Trafficking of the sodium-dependent facilitative insulin responsive glucose transporter (GLUT 4) has been shown to be associated with the intracellular redistribution of Rabs 4, 5 and 11 in adipose and muscle tissues. As a prelude to studies of the endosomal trafficking of the choline cotransporter (ChCoT), we describe herein our initial efforts to identify Rab proteins in Limulus polyphemus central nervous system (CNS) tissue. The studies were initiated after results from Microarray analysis of Limulus RNA hybridized to mouse gene chips suggested the presence of RNA transcripts for Rab 7 protein. Subsequently, more than 30 sequences for different Rab proteins were aligned and several consensus segments were selected for degenerate primer design to produce Rabs 2, 4, 7, 9 and 11. The expected PCR fragment sizes were obtained using RT-PCR and subcloned into pCR II TOPO vector and transferred into E. coli Top 10. The nucleotide sequences indicated that the recombinants encoded partial amino acid sequences for Rabs 1a, 1b, 1c, 2, 2a, 2b, 3a, 4, 5a, 7a, 7b, 11a, 11b, 14, 33b1 and 33b2. Northern blot analyses showed that the molecular sizes of Limulus Rabs 3a, 4, 7, 11a and 11b ranged from approximately 1.94.6 Kb. These Rab proteins, particularly Rabs 4, 7 and 11, will be studied further to determine their possible roles in the trafficking of the Limulus ChCoT

Molecular cloning of a cDNA for a putative choline co-transporter from Limulus CNS.

It is well documented that the sodium dependent, hemicholinium-3 sensitive, high affinity choline co-transporter is rate limiting in the biosynthesis of acetylcholine and is essential to cholinergic transmission. Until recently this transporter had eluded cloning. Okuda et al. (2000. Nature Neurosci. 3, 120-125) recently reported the successful cloning of the choline co-transporter in Caenorhabditis elegans (CHO-1) and rat (CHT1). We report herein the cloning of the choline co-transporter in the horseshoe crab, Limulus polyphemus. Through the use of a series of degenerate primers selected from consensus sequences of CHO-1 and CHT1, we generated two probes that were used to search a Limulus cDNA library produced from central nervous system (CNS) tissue. The full length nucleotide sequence of the Limulus homolog consists of 3368 bp which includes an open reading frame (ORF) that predicts a protein of 579 amino acids and two non-translation regions (NTR), one at the 3' end and the other at the 5' end. The amino acid sequence has 46% identity with rat CHT1 and 50% identity with both CHO-1 in C. elegans and the recently cloned human co-transporter (hCHT; Apparsundaram et al., 2000. Biochem. Biophys. Res. Commun. 276, 862-867; Okuda and Haga, 2000. FEBS Lett. 484, 92-97). Hydropathy plot analysis predicts the Limulus choline co-transporter (LChCoT) to have thirteen transmembrane domains (TMD), with the N-terminus oriented extracellularly and the C-terminus oriented intracellularly. Northern blot analyses using cDNA probes designed from LChCoT cDNA sequences revealed its distribution specifically in central nervous system structures. On the other hand it was not found in non-nervous tissues. The successful cloning of LChCoT, which was shown to be a member of the sodium-dependent glucose transporter family (SLGT), should prove useful in the determination of its physiological regulation, including its intracellular trafficking.

Comparative studies in synaptosome formation: preparation of synaptosomes from the ventral nerve cord of the lobster (Homarus americanus).

A flotation method for preparing synaptosomes, previously developed for work with squid nervous tissue, has now been successfully applied to the ventral nerve cord of lobster. Perhaps due to the greater content of connective tissue, homogenization of the lobster nerve cord was more difficult than with squid optic lobes and the yield of synaptosomes was lower. The synaptosomes fraction showed a 3.8-fold enrichment of bound acetylcholine relative to the homogenate and was almost 10 times richer in acetylcholine than a guinea pig cerebral cortical synaptosome fraction. The lobster synaptosomes accumulated choline rapidly when incubated at room temperature in sea water, and showed a high degree of occlusion of lactate dehydrogenase, thus confirming that they are sealed structures. The lobster can thus be added to the wide range of species from whose nervous systems synaptosomes can be isolated, and merits further study as a possibly rich source of cholinergic synaptosomes.