Localisation of mRNA and co-expression and molecular forms of GRP gene products in endocrine cells of fetal human lung

The presence of bombesin (gastrin-releasing peptide, GRP)-like immunoreactivity in mucosal endocrine cells of human fetal lung is well established. In this study we have investigated the localisation of pro-GRP mRNA and GRP gene products and compared the distribution and levels of extractable GRP- and C-terminal flanking peptide of human pro-GRP-like immunoreactivity in order to verify synthesis and to investigate their coexistence and molecular forms. Human fetal lungs (14 to 23 weeks gestation) were immunostained, and extracts were assayed using region-specific antisera to pro-GRP. Additional antisera to chromogranin and protein gene product 9.5 (PGP 9.5) were used for immunostaining by the peroxidase anti-peroxidase technique and for double immunofluorescence staining using antisera raised in two species. Immunoreactivity for both bombesin (GRP) and flanking peptide was seen mainly in the same endocrine cells, but more cells were stained with antisera to flanking peptide than with antiserum to bombesin (GRP). In situ hybridisation showed that pro-GRP mRNA was present and thus synthesis of the peptides was taking place. Endocrine cells and nerve fibres were PGP 9.5-immunoreactive, and a subset of cells was immunoreactive for bombesin gene products. Radioimmunoassay and chromatography show that pro-GRP is present in both the uncleaved and cleaved forms, and, in agreement with immunocytochemistry results, that an excess of C-terminal peptide of pro-GRP is detectable. It is therefore concluded that GRP-like peptides and flanking peptide are co-localised in human pulmonary endocrine cells, but the latter is found in larger concentrations than free GRP. Thus GRP-like peptides may be secreted separately from the flanking peptide(s) of pro-GRP.(ABSTRACT TRUNCATED AT 250 WORDS)     

A field study of seasonal neuronal incorporation into the song control system of a songbird that lacks adult song learning

Adult songbirds can incorporate new neurons into HVc, a telencephalic song control nucleus. Neuronal incorporation into HVc is greater in the fall than in the spring in adult canaries (open‐ended song learners) and is temporally related to seasonal song modification. We used the western song sparrow, a species that does not modify its adult song, to test the hypothesis that neuronal incorporation into adult HVc is not seasonally variable in age‐limited song learners. Wild song sparrows were captured during the fall and the spring, implanted with osmotic pumps containing [³H]thymidine, released onto their territories, and recaptured after 30 days. The density, proportion, and number of new HVc neurons were all significantly greater in the fall than in the spring. There was also a seasonal change in the incorporation of new neurons into the adjacent neostriatum that was less pronounced than the change in HVc. This is the first study of neuronal recruitment into the song control system of freely ranging wild songbirds. These results indicate that seasonal changes in HVc neuronal incorporation are not restricted to open‐ended song learners. The functional significance of neuronal recruitment into HVc therefore remains elusive. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 316–326, 1999     

Synergism,Bifunctionality, and the Evolution of a Gradual Sensory Trade-off in Hummingbird Taste Receptors

Sensory receptor evolution can imply trade-offs between ligands, but the extent to which such trade-offs occur and the underlying processes shaping their evolution is not well understood. For example, hummingbirds have repurposed their ancestral savory receptor (T1R1–T1R3) to detect sugars, but the impact of this sensory shift on amino acid perception is unclear. Here, we use functional and behavioral approaches to show that the hummingbird T1R1–T1R3 acts as a bifunctional receptor responsive to both sugars and amino acids. Our comparative analyses reveal substantial functional diversity across the hummingbird radiation and suggest an evolutionary timeline for T1R1–T1R3 retuning. Finally, we identify a novel form of synergism between sugars and amino acids in vertebrate taste receptors. This work uncovers an unexplored axis of sensory diversity, suggesting new ways in which nectar chemistry and pollinator preferences can coevolve.     

TIP,an integral membrane protein of the protein-storage vacuoles of the soybean cotyledon undergoes developmentally regulated membrane accumulation and removal

Protein storage vacuoles (PSVs) in soybean (Glycine max (L.) Merr.) cotyledon cells are formed by subdivision of the central vacuole early in seed maturation. They persist until the fifth or sixth day after germination when the central vacuole re-forms. The major integral membrane protein of PSVs, called Tonoplast Integral Protein or TIP, is highly conserved in the seeds of higher plants (K.D. Johnson et al. 1989, Plant Physiol. 91, 1006–1013). The primary sequence of TIP indicates that it may be a pore protein, although of unknown function (K.D. Johnson et al. 1990, Plant Cell 2, 525–532). TIP is apparently seed-specific and is localized in the protein-storage-vacuole membrane of the storageparenchyma cells and the tonoplast of provascular cells. Using correlated immunoblot and electron microscopicimmunocytochemical assays, we have studied TIP accumulation during seed maturation and its disappearance during seed germination. We have determined that the accumulation of TIP in the protein-storage-vacuole membrane is not correlated with the presence or concentration of stored protein in the organelle. Accumulation of TIP occurs primarily after the division of the central vacuole into protein-storage vacuoles is complete and most of the stored protein has been deposited. Transport of TIP to the PSV membrane is apparently mediated by the Golgi apparatus. Quantitative SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis)-immunoblots indicate that, after germination is initiated, TIP abundance is unchanged for the first 4d, but that between days 5 and 7 of growth its abundance decreases drastically. TIP is removed from the PSV membrane prior to the completion of storageprotein mobilization and concurrently with re-formation of the central vacuole. The mechanism of TIP removal appears to involve autophagic sequestering of membrane inside the PSV. The developmental regulation of TIP insertion and removal indicates a physiological function of TIP during late seed maturation or early seedling growth.Abbreviations PSV protein storage vacuoles - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - TIP Tonoplast Integral Protein The mention of vendor or product does not imply that they are endorsed or recommended by the U.S. Department of Agriculture over vendors of similar products not mentionedWe are grateful to Drs. Ken D. Johnson and Maarten J. Chrispeels (University of California/San Diego, La Jolla, USA) for the gift of anti-TIP antiserum and for their continuing interest in this project. We are also grateful to Dr. Robert Yaklich (Plant Germplasm and Quality Enhancement Laboratory, U.S. Department of Agriculture, Beltsville, Md.) for the soybeans used in this study. We thank Dr. Maria L. Ghirardi for her assistance with the laser densitometry.