Cloning and gene map assignment of the Xiphophorus DNA ligase 1 gene

Fishes represent the stem vertebrate condition and have maintained several gene arrangements common to mammalian genomes throughout the 450 Myr of divergence from a common ancestor. One such syntenic arrangement includes the GPI-PEPD enzyme association on Xiphophorus linkage group IV and human chromosome 19. Previously we assigned the Xiphophorus homologue of the human ERCC2 gene to linkage group U5 in tight association with the CKM locus. CKM is also tightly linked to the ERCC2 locus on human chromosome 19, leading to speculation that human chromosome 19 may have arisen by fusion of two ancestral linkage groups which have been maintained in fishes. To investigate this hypothesis further, we isolated and sequenced Xiphophorus fish genomic regions exhibiting considerable sequence similarity to the human DNA ligase 1 amino acid sequence. Comparison of the fish DNA ligase sequence with those of other species suggests several modes of amino acid conservation in this gene. A 2.2-kb restriction fragment containing part of an X. maculatus DNA ligase 1 exon was used in backcross hybrid mapping with 12 enzyme or RFLP loci. Significant linkage was observed between the nucleoside phosphorylase (NP2) and the DNA ligase (LIG1) loci on Xiphophorus linkage group VI. This assignment suggests that the association of four DNA repair-related genes on human chromosome 19 may be the result of chance chromosomal rearrangements.      

Electrophysiological and biochemical responses of mouse vomeronasal receptor cells to urine-derived compounds: possible mechanism of action

Receptor cells of the vomeronasal organ (VNO) are thought to detect pheromone-like molecules important for reproductive physiology. Several compounds derived from male mouse urine have been demonstrated to affect endocrine events in female mice. In the present study, the ability of these compounds to affect VNO activity was tested. In dissociated VNO cells held under voltage clamp conditions, application of dehydro-exo-brevicomin (DHB) evoked an outward current at negative holding potentials and an inward current at positive holding potentials. Under current clamp, DHB reduced action potential firing. Since DHB application caused a decrease in membrane conductance, this compound appeared to act by reducing inward current through closing an ion channel. Biochemical experiments tested the effects of DHB and 2- (sec-butyl)-4,5-dihydrothiazole (SBT) on cAMP levels in the VNO. A mixture of DHB and SBT decreased cAMP levels in VNO sensory tissue and had no effect on VNO non-sensory tissue. The results suggest that pheromones have an inhibitory influence on action potential generation and on cAMP levels in receptor cells of the VNO.      

Phylogenetic analysis of carbamoylphosphate synthetase genes: complex evolutionary history includes an internal duplication within a gene which can root the tree of life

Carbamoylphosphate synthetase (CPS) catalyzes the first committed step in pyrimidine biosynthesis, arginine biosynthesis, or the urea cycle. Organisms may contain either one generalized or two specific CPS enzymes, and these enzymes may be heterodimeric (encoded by linked or unlinked genes), monomeric, or part of a multifunctional protein. In order to help elucidate the evolution of CPS, we have performed a comprehensive phylogenetic analysis using the 21 available complete CPS sequences, including a sequence from Sulfolobus solfataricus P2 which we report in this paper. This is the first report of a complete CPS gene sequence from an archaeon, and sequence analysis suggests that it encodes an enzyme similar to heterodimeric CPSII. We confirm that internal similarity within the synthetase domain of CPS is the result of an ancient gene duplication that preceded the divergence of the Bacteria, Archaea, and Eukarya, and use this internal duplication in phylogenetic tree construction to root the tree of life. Our analysis indicates with high confidence that this archaeal sequence is more closely related to those of Eukarya than to those of Bacteria. In addition to this ancient duplication which created the synthetase domain, our phylogenetic analysis reveals a complex history of further gene duplications, fusions, and other events which have played an integral part in the evolution of CPS.