Impact of temperature on the relationship between respiration and nitrogen concentration in roots: an analysis of scaling relationships, Q10 values and thermal acclimation ratios

* The impact of nitrogen (N) supply on the temperature response of root respiratory O(2) uptake (R) was assessed in several herbaceous species grown in solution culture. Warm-grown (25 : 20 degrees C, day:night) plants differing in root N concentration were shifted to 13 : 8 degrees C for 7 d to cold-acclimate. * Log-log plots of root R vs root N concentration both showed that R increased with increasing tissue N concentration, irrespective of the growth temperature. Although the regression slopes of the log-log plots did not differ between the warm-grown and cold-acclimated plants, cold-acclimated plants did exhibit a higher y-axis intercept than their warm-grown counterparts. This suggests that cold acclimation of root R is not entirely dependent on cold-induced increases in tissue N concentration and that scaling relationships (i.e. regression equations fitted to the log-log plots) between root R and N concentration are not fixed. * No systematic differences were found in the short-term Q(10) (proportional change in R per 10 degrees C change in temperature), or degree of cold acclimation (as measured by the proportional difference between warm- and cold-acclimated roots) among roots differing in root N concentration. The temperature response of root R is therefore insensitive to tissue N concentration. * The insensitivity of Q(10) values and acclimation to tissue N concentration raises the possibility that root R and its temperature sensitivity can be predicted for a range of N supply scenarios.     

Thermostability of irreversible unfolding alpha-amylases analyzed by unfolding kinetics

For most multidomain proteins the thermal unfolding transitions are accompanied by an irreversible step, often related to aggregation at elevated temperatures. As a consequence the analysis of thermostabilities in terms of equilibrium thermodynamics is not applicable, at least not if the irreversible process is fast with respect the structural unfolding transition. In a comparative study we investigated aggregation effects and unfolding kinetics for five homologous alpha-amylases, all from mesophilic sources but with rather different thermostabilities. The results indicate that for all enzymes the irreversible process is fast and the precedent unfolding transition is the rate-limiting step. In this case the kinetic barrier toward unfolding, as measured by unfolding rates as function of temperature, is the key feature in thermostability. The investigated enzymes exhibit activation energies (E(a)) between 208 and 364 kJmol(-1) and pronounced differences in the corresponding unfolding rates. The most thermostable alpha-amylase from Bacillus licheniformis (apparent transition temperature, T(1/2) approximately 100 degrees C) shows an unfolding rate which is four orders of magnitude smaller as compared with the alpha-amylase from pig pancreas (T(1/2) approximately 65 degrees C). Even with respect to two other alpha-amylases from Bacillus species (T(1/2) approximately 86 degrees C) the difference in unfolding rates is still two orders of magnitude.     

Characterization of mice lacking the tetraspanin superfamily member CD151

The tetraspanin membrane protein CD151 is a broadly expressed molecule noted for its strong molecular associations with integrins, especially alpha3beta1, alpha6beta1, alpha7beta1, and alpha6beta4. In vitro functional studies have pointed to a role for CD151 in cell-cell adhesion, cell migration, platelet aggregation, and angiogenesis. It has also been implicated in epithelial tumor progression and metastasis. Here we describe the generation and initial characterization of CD151-null mice. The mice are viable, healthy, and fertile and show normal Mendelian inheritance. They have essentially normal blood and bone marrow cell counts and grossly normal tissue morphology, including hemidesmosomes in skin, and expression of alpha3 and alpha6 integrins. However, the CD151-null mice do show phenotypes in several different tissue types. An absence of CD151 leads to a minor abnormality in hemostasis, with CD151-null mice showing longer average bleeding times, greater average blood loss, and an increased incidence of rebleeding occurrences. CD151-null keratinocytes migrate poorly in skin explant cultures. Finally, CD151-null T lymphocytes are hyperproliferative in response to in vitro mitogenic stimulation.     

Intraspecific transfer of carbon between plants linked by a common mycorrhizal network

To quantify the involvement of arbuscular mycorrhiza (AM) fungi in the intraspecific transport of carbon (C) between plants we fumigated established Festuca ovina turf for one week with air containing depleted ¹³C. This labelled current assimilate in a section of mycorrhizal or non-mycorrhizal turf. Changes in the ^13/12C ratio of adjacent, unfumigated plants, therefore, allowed the movement of C between labelled and unlabelled plants to be estimated. In mycorrhizal turves, 41% of the C exported to the roots from the leaves was transported to neighbouring plants. The most likely explanation of this is was the transport of C via a common hyphal network connecting the roots of different plants. No inter-plant transport of C was detected in non-mycorrhizal turves. There was no evidence that the C left fungal structures and entered the roots of receiver plants. Mycorrhizal colonisation increased carbon transport from leaves to root from 10% of fixed carbon when non-mycorrhizal to 36% in mycorrhizal turves. These results suggest that AM fungi impose a significantly greater C drain on host plants than was previously thought.     

Characterization of monoclonal antibodies to protoplast membranes of Nicotiana tabacum identified by an enzyme-linked immunosorbent assay

Murine monoclonal antibodies to protoplast membrne antigens were generated using mouse myelomas and spleen cells from mice immunized with Nicotiana tabacum L. leaf protoplasts. For selecting antibody-secreting clones, a sensitive and rapid enzyme-linked immunosorbent assay (ELISA) for monoclonal antibody binding to immobilized cellular membrane preparations or immobilized protoplasts was developed. With intact protoplasts as immobilized antigen, the ELISA is selective for antibodies that bind to plasma-membrane epitopes present on the external surface of protoplasts. Using the membrane ELISA, a total of 24 hybridoma lines were identified that secreted antibodies to plant membrane epitopes. The protoplast ELISA and subsequent immunofluorescence studies identified four hybridoma lines as secreting antibodies which bound to the external surface of protoplasts and cells. The corresponding antigens were not species- or tissue-specific, were periodatesensitive, and were located in membranes which equilibrated broadly throughout a linear sucrose gradient. When protein blots of electrophoretically separated membrane proteins were probed with these antibodies, a band of M_r 14 kilodaltons (kDa) and a smear of bands of M_r 45–120 kDa were labeled. An additional set of three antibodies appeared by immunofluorescence to bind to the plasma membrane of broken but not intact protoplasts and labeled membranes equilibrating at a density of approx. 1.12 kg·l^-1 in a linear sucrose density gradient. These classes of monoclonal antibodies enlarge the library of monoclonal antibodies (Norman et al. 1986, Planta 167, 452–459) available for the study of plant plasma-membrane structure and function.Abbreviations ELISA Enzyme-linked immunosorbent assay - Ig immunoglobulin - kDa kilodalton - M_r relative molecular mass - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis     

Non-motile mini-transposon mutants of Bordetella bronchiseptica exhibit altered abilities to invade and survive in eukaryotic cells

Non-motile mutants of Bordetella bronchiseptica were generated after mini-transposon mutagenesis. One non-motile mutant (designated VMM1) was derived from the bvg-positive strain BB7865 and four mutants (designated AMM1–4) were derived from the isogenic bvg-negative strain BB7866. Southern hybridisation analysis indicated that loss of motility was not due to the disruption of the flagellin subunit gene. Western blot and transmission electron microscopic analysis indicated that three of the five mutants expressed neither the flagellin subunit (40 kDa) nor flagella whereas one mutant expressed intact flagella under all conditions tested. One unique bvg-negative mutant, AMM4, exhibited temperature-dependent repression of flagella biosynthesis and motility at 37°C. The ability of AMM4 to invade and survive in HeLa cells was significantly decreased.     

Why plants bother: root proliferation results in increased nitrogen capture from an organic patch when two grasses compete

We investigated whether the capacities of Lolium perenne L. and Poa pratensis L. roots to proliferate locally and to alter local nitrogen (N) inflows in a decomposing organic matter patch were important in their capture of N when grown together. In the presence of a patch, plants of both species were significantly heavier and contained more N. Root length and weight densities increased in the patch, but specific root length was unaltered. Although both species proliferated roots in the patch, L. perenne produced greater root length densities than P. pratensis , and also captured more N from the patch. Indeed, total N uptake from the patch was related to root length density within the patch. N inflows (rate of N uptake per unit root length) in the patch were no faster than in the whole root system for both species. Under the conditions of this study, root proliferation in an organic patch was more important for N capture from the patch than alterations in N inflows. Local proliferation of roots may be a key factor in interspecific competition for non-uniformly distributed supplies of N in natural habitats, so resolving the previous uncertainty as to the 'adaptive' nature of root proliferation.