Functional comparison of full-length and N-terminal-truncated octopamine transporters from Lepidoptera.

We have cloned two new lepidopteran octopamine transporters (OATs), members of the solute-linked carrier family 6 (SLC6) of nutrient transporters, from the CNS of the European corn borer Ostrinia nubilalis and the cabbage white Pieris rapae. Comparison of these sequences with the previously cloned OAT from the cabbage looper Trichoplusia ni showed that the T. ni OAT sequence previously reported was truncated by 74 amino acids at the N-terminus. The cytoplasmic N-termini deduced here are considerably longer than the N-termini of other monoamine transporters in the SLC6 family and contain many more high-probability serine- and threonine-phosphorylation sites. Monoamine uptake and competitive inhibition studies on baculovirus-infected Sf9 cells expressing these three cloned OATs indicate that they are able to transport tyramine, octopamine and dopamine with high affinity (K(m) and K(i) range, 0.4 microM-2.7 microM) and capacity ((3)H-dopamine uptake by TrnOAT, 2.5 pmol/well/min). We aimed to examine the role of the N-terminus of OAT by comparing the properties of the full-length T. ni OAT with those of the previously reported N-truncated version. Results for the new full-length T. ni OAT showed no difference in the protein's affinity for octopamine or dopamine, although at low levels of viral infection it did show slightly higher transport activity ((3)H-dopamine uptake by truncated TrnOAT, 1.5 pmol/well/min). Treatment of Sf9 cells expressing full-length or truncated TrnOAT with a variety of protein kinase activators and inhibitors, however, did not change transporter activity. Neither an intact N-terminus, nor apparently a particular phosphorylation state of this extended N-terminus, is required for OAT to transport monoamines.

Ancestry of neuronal monoamine transporters in the Metazoa.

Selective Na(+)-dependent re-uptake of biogenic monoamines at mammalian nerve synapses is accomplished by three types of solute-linked carrier family 6 (SLC6) membrane transporter with high affinity for serotonin (SERTs), dopamine (DATs) and norepinephrine (NETs). An additional SLC6 monoamine transporter (OAT), is responsible for the selective uptake of the phenolamines octopamine and tyramine by insect neurons. We have characterized a similar high-affinity phenoloamine transporter expressed in the CNS of the earthworm Lumbricus terrestris. Phylogenetic analysis of its protein sequence clusters it with both arthropod phenolamine and chordate catecholamine transporters. To clarify the relationships among metazoan monoamine transporters we identified representatives in the major branches of metazoan evolution by polymerase chain reaction (PCR)-amplifying conserved cDNA fragments from isolated nervous tissue and by analyzing available genomic data. Analysis of conserved motifs in the sequence data suggest that the presumed common ancestor of modern-day Bilateria expressed at least three functionally distinct monoamine transporters in its nervous system: a SERT currently found throughout bilaterian phyla, a DAT now restricted in distribution to protostome invertebrates and echinoderms and a third monoamine transporter (MAT), widely represented in contemporary Bilateria, that is selective for catecholamines and/or phenolamines. Chordate DATs, NETs, epinephrine transporters (ETs) and arthropod and annelid OATs all belong to the MAT clade. Contemporary invertebrate and chordate DATs belong to different SLC6 clades. Furthermore, the genes for dopamine and norepinephrine transporters of vertebrates are paralogous, apparently having arisen through duplication of an invertebrate MAT gene after the loss of an invertebrate-type DAT gene in a basal protochordate.

Molecular cloning and functional characterization of a neuronal choline transporter from Trichoplusia ni.

A cDNA encoding a high-affinity Na(+)-dependent choline transporter (TrnCHT) was isolated from the CNS of the cabbage looper Trichoplusia ni using an RT-PCR-based approach. The deduced amino acid sequence of the CHT cDNA predicts a 594 amino acid protein of 64.74 kDa prior to glycosylation. TrnCHT has 80%, 79%, 76%, and 58% amino acid identity to putative CHTs from Anopheles gambiae, Drosophila melanogaster and Apis mellifera, and a cloned CHT from Limulus polyphemus, respectively. In situ hybridization of TrnCHT cRNA in whole-mount preparations of caterpillar CNS revealed that TrnCHT mRNA is expressed by hundreds of presumably cholinergic neurons present in both the brain and cortex of all segmental ganglia. Na(+)-dependent [(3)H]-choline uptake was induced in Sf9 cells in vitro following infection with a TrnCHT-expressing recombinant baculovirus. Virally induced [(3)H]-choline uptake was found to approximately equal the endogenous rate of choline uptake in insect cells, seen either after infection with a control virus or in TrnCHT-infected cells exposed to [(3)H]-choline in the absence of Na(+). The Na(+)-dependent component of [(3)H]-choline uptake by TrnCHT-infected cells was saturable with a K(m) for choline transport of 8.4 microM. Several compounds reported to be potent blockers of [(3)H]-choline uptake by cloned vertebrate choline transporters proved to be relatively weak inhibitors of choline uptake by Sf9 cells expressing TrnCHT. Hemicholinium-3 (K(i)=4.1 microM) and two oxoquinuclidium analogues of choline, quireston-A (K(i) approximately 10 microM) and quireston (K(i) approximately 100 microM) inhibited 50% of control uptake only at micromolar concentrations. The endogenous low-affinity Na(+)-independent uptake of [(3)H]-choline was also inhibited by high micromolar concentrations of hemicholinium-3.

Functionally distinct dopamine and octopamine transporters in the CNS of the cabbage looper moth.

A cDNA was cloned from the cabbage looper Trichoplusia ni based on similarity to other cloned dopamine transporters (DATs). The total nucleotide sequence is 3.8 kb in length and contains an open reading frame for a protein of 612 amino acids. The predicted moth DAT protein (TrnDAT) has greatest amino acid sequence identity with Drosophila melanogasterDAT (73%) and Caenorhabditis elegansDAT (51%). TrnDAT shares only 45% amino acid sequence identity with an octopamine transporter (TrnOAT) cloned recently from this moth. The functional properties of TrnDAT and TrnOAT were compared through transient heterologous expression in Sf9 cells. Both transporters have similar transport affinities for DA (Km 2.43 and 2.16 micro m, respectively). However, the competitive substrates octopamine and tyramine are more potent blockers of [3H]dopamine (DA) uptake by TrnOAT than by TrnDAT. D-Amphetamine is a strong inhibitor and l-norepinephrine a weak inhibitor of both transporters. TrnDAT-mediated DA uptake is approximately 100-fold more sensitive to selective blockers of vertebrate transporters of dopamine and norepinephrine, such as nisoxetine, nomifensine and dibenzazepine antidepressants, than TrnOAT-mediated DA uptake. TrnOAT is 10-fold less sensitive to cocaine than TrnDAT. None of the 15 monoamine uptake blockers tested was TrnOAT-selective. In situ hybridization shows that TrnDAT and TrnOAT transcripts are expressed by different sets of neurons in caterpillar brain and ventral nerve cord. These results show that the caterpillar CNS contains both a phenolamine transporter and a catecholamine transporter whereas in the three invertebrates whose genomes have been completely sequenced only a dopamine-selective transporter is found.