Localization and coexistence of atrial natriuretic peptide (ANP) and neuropeptide Y (NPY) in vertebrate adrenal chromaffin cells immunoreactive to TH,DBH and PNMT

Antisera specific for mammalian atrial natriuretic peptied (ANP) and neuropeptide Y (NPY) were applied to examine, in immunofluorescence, the occurrence of cells immunoreactive to ANP and NPY in the adrenal organs of mammals, birds, reptiles, amphibians, and bony fish. Catecholamine-containing cells were identified using antisera against tyrosine-hydroxylase, dopamine--hydroxylase, and phenylethanolamine-N-methyl-transferase. In all vertebrates studied, immunoreactivities to ANP and NPY occurred in adrenal chromaffin cells but were absent from the cortex or its homolog, the interrenal. The majority of immunoreactivities to ANP and NPY was confined to the adrenaline cells. In mammals, the number of ANP-immuno-reactive cells (60%–80% of the total cell population) exceeded that of the NPY-immunoreactive cells (35%–45%). In birds, reptiles, and Amphibia, the numbers of ANP-immunoreactive (35%–40%) and NPY-immunoreactive (30%–35%) cells were in a similar range. The bony fish showed a density of both ANP-immunoreactive (80%–90%) and NPY-immunoreactive (35%–40%) cells. In all species studied, immunoreactivities to ANP and NPY partially coexisted. Generally, 30%–55% of the ANP-immunoreactive cells also contained NPY-immunoreactivity. In rat, coexistence amounted to almost 100% and in quail to 95%. Except for the rat, three subpopulations of chromaffin cells seemed to occur: ANP-immunoreactive non-NPY-immunoreactive, ANP-immunoreactive+NPY-immunoreactive and NPY-immunoreactive non-ANP-immunoreactive cells. Thus, adrenal ANP and NPY share a conservative history and coexist as early as at the level of bony fish. The endocrine actions of ANP and NPY derived from medullary cells on cortical cells as found in mammals might be based on an ancestoral paracrine system. In submammalians, ANP and NPY may not only act as endocrine hormones, but also influence steroid-producing interrenal cells in a paracrine manner, and act as modulators on chromaffin cells.Dedicated to Professor dr. Angela Nolte (Münster, Germany) on the occasion of the 50th anniversary of her Ph.D. graduation     

Pectin May Hinder the Unfolding of Xyloglucan Chains during Cell Deformation： Implications of the Mechanical Performance of Arabidopsis Hypocotyls with Pectin Alterations

Plant cell walls, like a multitude of other biological materials, are natural fiber-reinforced composite materials. Their mechanical properties are highly dependent on the interplay of the stiff fibrous phase and the soft matrix phase and on the matrix deformation itself. Using specific Arabidopsis thaliana mutants, we studied the mechanical role of the matrix assembly in primary cell walls of hypocotyls with altered xyloglucan and pectin composition. Standard microtensile tests and cyclic loading protocols were performed on tour1 hypocotyls with affected RGII borate diester cross-links and a hindered xyloglucan fucosylation as well as qua2 exhibiting 50% less homogalacturonan in comparison to wild-type. As a control, wild-type plants （Col-0） and mur2 exhibiting a specific xyloglucan fucosylation and no differences in the pectin network were utilized. In the standard tensile tests, the ultimate stress levels （-tensile strength） of the hypocotyls of the mutants with pectin alterations （mur1, qua2） were rather unaffected, whereas their tensile stiffness was noticeably reduced in comparison to Col-0. The cyclic loading tests indicated a stiffening of all hypocotyls after the first cycle and a plastic deformation during the first straining, the degree of which, however, was much higher for tour1 and qua2 hypocotyls. Based on the mechanical data and current cell wall models, it is assumed that folded xyloglucan chains between cellulose fibrils may tend to unfold during straining of the hypocotyls. This response is probably hindered by geometrical constraints due to pectin rigidity.     

Attractiveness of CO2 released by root respiration fades on the background of root exudates

Plants are endangered at their roots by soil-dwelling rhizophagous insects. These below-ground living herbivores may orient to the source of carbon dioxide (CO₂), an ubiquitous volatile released by respiring plant roots. Here, we studied the interaction of CO₂ and other plant root-derived chemical stimuli with regard to the chemical orientation of the polyphagous larvae of Melolontha melolontha L. (Scarabaeidae). A soil arena was developed that enabled both determination of the actual soil CO₂ concentration and the behavioural response of an insect to (a) CO₂ gradients per se, (b) chemical stimuli released from respiring, undamaged roots of plants potted into vermiculite in this arena and (c) combinations of CO₂ gradients and root-derived stimuli. In a root-free arena, larvae of M. melolontha oriented to the source of synthetic CO₂. However, similar CO₂ gradients generated by host plant roots did not attract the larvae. Neither did a synthetic CO₂ gradient combined with aqueous extracts from rhizospheres with undamaged plant roots elicit an attractive effect. Our data suggest that orientation of cockchafer larvae within CO₂ gradients generated by respiring roots is ‘masked’ by an aqueous extract from a rhizosphere with undamaged roots. The results emphasise that effects of behaviour modifying plant-derived compounds need to be investigated against the background of naturally co-occurring chemicals. The significance of our results for orientation of soil living insects is discussed with respect to abiotic conditions in natural soil and the role of soil microorganisms for the attractiveness of plant roots.     

Interaction of 4-chloroindole-3-acetic acid and gibberellins in early pea fruit development

In pea, normal pod (pericarp) growth requires the presence of seeds; and in the absence of seeds, gibberellins (GAs) and/or auxins can stimulate pericarp growth. To further characterize the function of naturally occurring pea GAs and the auxin, 4-chloroindole-3-acetic acid (4-Cl-IAA), on pea fruit development, profiles of the biological activities of GA3, GA1, and 4-Cl-IAA on pericarp growth were determined separately and in combination on pollinated deseeded ovaries (split-pericarp assay) and nonpollinated ovaries. Nonpollinated ovaries (pericarps) responded differently to exogenous GAs and 4-Cl-IAA than pollinated deseeded pericarps. In nonpollinated pericarps, both GA3 and 4-Cl-IAA stimulated pericarp growth, but GA3 was significantly more active in stimulating all measured parameters of pericarp growth than 4-Cl-IAA. 4-Cl-IAA, GA1, and GA3 were observed to stimulate pericarp growth similarly in pollinated deseeded pericarps. In addition, the synergistic effect of simultaneous application of 4-Cl-IAA and GAs on pollinated deseeded pericarp growth supports the hypothesis that GAs and 4-Cl-IAA are involved in the growth and development of pollinated ovaries.     

4-Chloroindole-3-acetic acid and plant growth

4-Chloroindole-3-acetic acid (4-Cl-IAA) is a potent auxin in various auxin bioassays. Researchers have used 4-Cl-IAA as well as other halogenated auxins in biological assays to understand the structural features of auxins required to induce auxin mediated growth in plants. 4-Cl-IAA is a naturally occurring auxin in plants from the Vicieae tribe of the Fabaceae family; and 4-Cl-IAA has also been identified in one species outside the Vicieae tribe, Pinus sylvestris. The apparent function of the unique auxin 4-Cl-IAA in normal plant growth and development will be discussed with a focus on Pisum sativum and Vicia faba     

Expression of endogenous and exogenous growth hormone (GH) messenger (m) RNA in a GH-transgenic tilapia (<Emphasis Type="Italic">Oreochromis niloticus</Emphasis>)

We have previously produced transgenic fish from crosses between a wild-type female tilapia (Oreochromis niloticus) and a G1 transgenic male. This line of growth-enhanced tilapia carries a single copy of a chinook salmon (s) growth hormone (GH) gene spliced to an ocean pout antifreeze promoter (OPAFPcsGH) co-ligated to a carp -actin/lacZ reporter gene construct, integrated into the tilapia genome. Because little is known about the expression sites of transgenes, we have characterised the gene expression patterns of sGH and tilapia (t)GH in transgenic tilapia using a newly established real-time PCR to measure the absolute mRNA amounts of both hormones. The sGH gene, which was expected to be expressed mainly in liver, was also found to be expressed in other organs, such as gills, heart, brain, skeletal muscle, kidney, spleen, intestine and testes. However, in pituitary no sGH mRNA but only tGH mRNA was found. Tilapia GH mRNA in wild-type pituitary amounted to 226 ± 30 pg/g total RNA but in transgenics only to 187 ± 43 pg/g total RNA. Liver exhibited the highest level of sGH mRNA (8.3 ± 2.5 pg/g total RNA) but the extrahepatic sites expressed considerable amounts of sGH mRNA ranging from 4.1 ± 2.0 pg/g total RNA in gills to 0.2 ± 0.08 pg/g total RNA in kidney. The widespread expression of the sGH gene is assumed to be due to the tissue specificity of the type III AFP gene promoter. It is assumed that our transgenic experiments, which in contrast to some other approaches caused no obvious organ abnormalities, mimick the GH expression during ontogeny. Because sGH mRNA is expressed both in liver and in extrahepatic sites it may not only promote secretion and release of liver-derived (endocrine) IGF-I leading to an overall growth enhancement but also stimulate IGF-I expression within the different organs in a paracrine/autocrine manner and, thus, further promote organ growth.     

Phenol--another cockchafer attractant shared by Melolontha hippocastani Fabr. and M. melolontha L

The response of the two most abundant cockchafer species in central Europe, Melolontha hippocastani and M. melolontha, towards phenol, mixtures of phenol with the leaf alcohol (Z)-3-hexen-1-ol and the known cockchafer pheromones, 1,4-benzoquinone (M. hippocastani) and toluquinone (M. melolontha), was investigated in the field. During the swarming period at dusk, phenol attracted males of both species, and enhanced the known attraction of cockchafer males towards (Z)-3-hexen-1-ol. A mixture of phenol plus (Z)-3-hexen-1-ol was less attractive for M. hippocastani males than a mixture of (Z)-3-hexen-1-ol plus 1,4-benzoquinone, whereas phenol plus (Z)-3-hexen-1-ol attracted as many M. melolontha males as a mixture of (Z)-3-hexen-1-ol plus toluquinone. In both species three component mixtures containing phenol, (Z)-3-hexen-1-ol, and the respective benzoquinone did not capture more males than two component mixtures consisting of only (Z)-3-hexen-1-ol and the benzoquinone. A possible role of phenol as another cockchafer sex pheromone component is discussed.     

Control of myoblast proliferation with a synthetic ligand

Skeletal myoblast grafts can form contractile tissue to replace scar and repair injured myocardium. Although potentially therapeutic, generating reproducible and sufficiently large grafts remains a challenge. To control myoblast proliferation in situ, we created a chimeric receptor composed of a modified FK506-binding protein (F36V) fused with the fibroblast growth factor receptor-1 cytoplasmic domain. Mouse MM14 myoblasts were transfected with this construct and treated with AP20187, a dimeric F36V ligand, to induce receptor dimerization. Transfected myoblasts proliferated in response to dimerizer (comparable with basic fibroblast growth factor (bFGF) treatment), whereas the dimerizer had no effect on non-transfected cells. Similar to bFGF treatment, dimerizer treatment blocked myotube formation and myosin heavy chain expression and stimulated mitogen-activated protein (MAP) kinase phosphorylation in transfected cells. Non-transfected cells differentiated normally and showed no MAP kinase phosphorylation with dimerizer treatment. Furthermore, myoblasts treated with dimerizer for 30 days in culture reduced MAP kinase phosphorylation, withdrew from the cell cycle, and differentiated normally upon drug withdrawal, demonstrating reversibility of the effect. Thus, forced dimerization of the fibroblast growth factor receptor-1 cytoplasmic domain reproduces critical aspects of bFGF signaling in myoblasts. We hypothesize that in vivo administration of AP20187 following myoblast grafting may allow control over graft size and ultimately improve cardiac function.