David E. Lowery

Differential Activation of “Social” and “Solitary” Variants of the Caenorhabditis elegans G Protein-coupled Receptor NPR-1 by Its Cognate Ligand AF9

Natural variations of wild Caenorhabditis elegans isolates having either Phe-215 or Val-215 in NPR-1, a putative orphan neuropeptide Y-like G protein-coupled receptor, result in either “social” or “solitary” feeding behaviors (de Bono, M., and Bargmann, C. I. (1998) Cell 94, 679–689). We identified a nematode peptide, GLGPRPLRF-NH2 (AF9), as a ligand activating the cloned NPR-1 receptor heterologously expressed in mammalian cells. Shifting cell culture temperatures from 37 to 28 °C, implemented 24 h after transfections, was essential for detectable functional expression of NPR-1. AF9 treatments linked both cloned receptor variants to activation of Gi/Go proteins and cAMP inhibition, thus allowing for classification of NPR-1 as an inhibitory G protein-coupled receptor. The Val-215 receptor isoform displayed higher binding and functional activity than its Phe-215 counterpart. This finding parallels the in vivo observation of a more potent repression of social feeding by the npr-1 gene encoding the Val-215 form of the receptor, resulting in dispersing (solitary) animals. Since neuropeptide Y shows no sequence homology to AF9 and was functionally inactive at the cloned NPR-1, we propose to rename NPR-1 and refer to it as an AF9 receptor, AF9-R1.

Nucleotide sequence of UK and Australian isolates of feline calicivirus (FCV) and phylogenetic analysis of FCVs

We have determined the first complete genome sequence and capsid gene sequences of feline calicivirus (FCV) isolates from the UK and Australia. These were compared with other previously published sequences. The viruses used in the comparisons were isolated between 1957 and 1995 from various geographical locations and obtained from cats showing a range of clinical signs. Despite these diverse origins, comparisons between all strains showed a similar degree of sequence variation within both ORF1 (non-structural polyprotein) and ORF2 (major capsid protein) (amino acid distances of 7.7-13.0% and 8.8-18.6%, respectively). In contrast, ORF3 (putative minor structural protein) sequences indicated a more heterogenous distribution of FCV relatedness (amino acid distances of 1.9-17.9%). Phylogenetic analysis suggested that, unlike some other caliciviruses, FCV isolates within the current data set fall into one diverse genogroup. Within this group, there was an overall lack of geographic or temporal clustering which may be related to the epidemiology of FCV infection in cats. Analysis of regions of variability in the genome has shown that, as well as the previously identified variable regions in ORF2, similar domains exist within ORFs 1 and 3 also, although to a lesser extent. In ORF1, these variable domains largely fall between the putative non-structural protein functional domains.

FMRFamide‐like peptides encoded on the flp‐18 precursor gene activate two isoforms of the orphan Caenorhabditis elegans G‐protein‐coupled receptor Y58G8A.4 heterologously expressed in mammalian cells

Two alternatively spliced variants of an orphan Caenorhabditis elegans G‐protein‐coupled receptors (GPCRs; Y58G8A.4a and Y58G8A.4b) were cloned and functionally expressed in Chinese hamster ovary (CHO) cells. The Y58G8A.4a and Y58G8A.4b proteins (397 and 433 amino acid residues, respectively) differ both in amino acid sequence and length of the C‐terminal tail of the receptor. A calcium mobilization assay was used as a read‐out for receptor function. Both receptors were activated, with nanomolar potencies, by putative peptides encoded by the flp‐18 precursor gene, leading to their designation as FLP‐18R1a (Y58G8A.4a) and FLP‐18R1b (Y58G8A.4b). Three Ascaris suum neuropeptides AF3, AF4, and AF20 all sharing the same FLP‐18 C‐terminal signature, ‐PGVLRF‐NH2, were also potent agonists. In contrast to other previously reported C. elegans GPCRs expressed in mammalian cells, both FLP‐18R1 variants were fully functional at 37°C. However, a 37 to 28°C temperature shift improved their activity, an effect that was more pronounced for FLP‐18R1a. Despite differences in the C‐terminus, the region implicated in distinct G‐protein recognition for many other GPCRs, the same signaling pathways were observed for both Y58G8A.4 isoforms expressed in CHO cells. Gq protein coupling seems to be the main but not the exclusive signaling pathway, because pretreatment of cells with U‐73122, a phospholipase inhibitor, attenuated but did not completely abolish the Ca2+ signal. A weak Gs‐mediated receptor activation was also detected as reflected in an agonist‐triggered concentration‐dependent cAMP increase. The matching of the FLP‐18 peptides with their receptor(s) allows for the evaluation of the pharmacology of this system in the worm in vivo.

Gene contents in a 31-kb segment at the left genome end of bovine herpesvirus-1

We report the nucleotide sequence of a 31-kb segment at the left genome end of bovine herpesvirus-1 (BHV-1) and show that it comprises 19 different open reading frames (ORFs), including seven which have been described previously (circ, dUTPase, UL49.5, alpha TIF, VP8, glycoprotein C, and ribonucleotide reductase small subunit). The new sequence resulted in a correction at the C-terminus of glycoprotein C. All 19 ORFs exhibited strong amino acid sequence homology to the gene products of other alphaherpesviruses. The BHV-1 ORFs were arranged colinearly with the prototype sequence of herpes simplex virus 1 (HSV-1) in the range of the UL54 to UL37 genes. No BHV-1 homologs of the HSV-1 UL56, UL55, and UL45 genes were identified. The BHV-1 circ gene was the only gene without a HSV-1 counterpart. The additional ORFs 1 and 2 found at the left genome end of equine herpesvirus-1 (EHV-1) were absent in BHV-1. Among the newly sequenced BHV-1 ORFs are homologs of ICP27 (UL54), glycoprotein K (UL53), helicase-primase (UL52), DNA polymerase accessory protein (UL42), ribonucleotide reductase large subunit (UL39), and several virion proteins (UL49, UL46, UL43, UL41, UL38, UL37), most of which are strongly conserved in all herpesviruses. The possible functions of the proteins encoded within the sequenced region are assessed and features found are discussed.