Functional expression of recombinant G-protein-coupled receptors monitored by video imaging of pigment movement in melanophores.

Xenopus laevis melanophores are capable of functionally expressing recombinant receptors which couple via G-proteins to adenylate cyclase or phospholipase C (PLC). Receptor-mediated stimulation of either of these enzymes causes dispersion of melanosomes while receptor stimulation leading to inhibition of adenylate cyclase induces their aggregation. Translocation of melanosomes within thousands of individual pigment cells was simultaneously tracked by capturing gray scale video images before and after receptor activation. Digital subtraction of poststimulation from prestimulation images was performed on a microcomputer, generating bitplane images containing pixels with nonzero gray scale values wherever melanosome movement had occurred. Movement in both centripetal and centrifugal directions was detectable. The assay was tested using four receptors: a human beta 2-adrenergic receptor which stimulates adenylate cyclase, murine substance P and bombesin receptors which stimulate PLC, and a human D2 dopamine receptor which inhibits adenylate cyclase. Based on melanosome translocation following application of ligands, expression of functional receptors could be consistently detected in melanophores which received only single copies of a plasmid encoding any of the four receptors. By imaging fields containing up to 11,000 melanophores, the presence of a plasmid coding for a receptor could be detected when its frequency was one per 10,000 plasmids transfected. Combining receptor-mediated pigment translocation in melanophores with the rapid data-handling ability of video technology should provide a bioassay useful for investigating the function of G-protein-coupled receptors and for screening cDNA libraries for clones encoding new receptors.

cDNA sequence of the rat U snRNP-associated protein N: description of a potential Sm epitope.

Anti-Sm antibodies from a patient with systemic lupus erythematosus (SLE) were used to isolate cDNA clones encoding the snRNP-associated protein N from a rat brain derived cDNA library. The predicted primary structure of the 240 amino acid protein has a proline rich carboxyl terminus and shares a region of sequence similarity with other snRNP polypeptides, A and B/B'. Anti-Sm sera recognize a beta-galactosidase fusion protein containing only the carboxyl-terminal 80 amino acids of N; antibodies eluted from this fusion protein also react with A, B/B' and N on immunoblots, suggesting that these proteins share an Sm epitope located within this segment. Polyclonal antibodies raised against a 23 amino acid synthetic peptide derived from this conserved region of N recognize A, N and B/B' on immunoblots and can immunoprecipitate the Sm class of U snRNAs. These results confirm that this sequence defines a potential Sm epitope. RNA blotting analyses demonstrate that a 1.6 kb mRNA expressed predominantly in brain encodes the N polypeptide in both rats and humans. At low stringency rat N cDNA also hybridizes to a 1.3 kb mRNA species which encodes B/B', suggesting that N is structurally related to, but distinct from B/B'. Although B/B' proteins are thought to be expressed in all human cells, only N and B, but not B', are observed on immunoblots of human brain proteins probed with anti-Sm sera. The apparent difference in the complement of proteins associated with snRNP particles in human brain versus elsewhere suggests a possible mechanism for the regulation of brain-specific mRNA splicing.

Characterization and cDNA cloning of the pheromone-binding protein from the tobacco hornworm, Manduca sexta: a tissue-specific developmentally regulated protein.

cDNA encoding pheromone-binding protein (PBP), the major soluble protein in olfactory sensilla of male moths, has been cloned from the tobacco hornworm, Manduca sexta. A study of the developmental time course of PBP reveals that it is first synthesized just prior to eclosion and that the percentage of antennal mRNA encoding PBP shifts from zero to about 20% at that time. PBP is also found in sensilla from female M. sexta antennae. No amino acid sequence homology is observed between PBP and the vertebrate odorant-binding protein.