Bird and insect pollinators differ in specialization and potential pollination services along disturbance and resource gradients

Combined studies of the communities and interaction networks of bird and insect pollinators are rare, especially along environmental gradients. Here, we determined how disturbance by fire and variation in sugar resources shape pollinator communities and interactions between plants and their pollinating insects and birds. We recorded insect and bird visits to 21 Protea species across 21 study sites and for 2 years in Fynbos ecosystems in the Western Cape, South Africa. We recorded morphological traits of all pollinator species (41 insect and nine bird species). For each site, we obtained estimates of the time since the last fire (range: 2–25 calendar years) and the Protea nectar sugar amount per hectare (range: 74–62 000 g/ha). We tested how post-fire age and sugar amount influence the total interaction frequency, species richness and functional diversity of pollinator communities, as well as pollinator specialization (the effective number of plant partners) and potential pollination services (pollination service index) of insects and birds. We found little variation in the total interaction frequency, species richness and functional diversity of insect and bird pollinator communities, but insect species richness increased with post-fire age. Pollinator specialization and potential pollination services of insects and birds varied differently along the environmental gradients. Bird pollinators visited fewer Protea species at sites with high sugar amount, while there was no such trend for insects. Potential pollination services of insect pollinators to Protea species decreased with increasing post-fire age and resource amounts, whereas potential pollination services of birds remained constant along the environmental gradients. Despite little changes in pollinator communities, our analyses reveal that insect and bird pollinators differ in their specialization on Protea species and show distinct responses to disturbance and resource gradients. Our comparative study of bird and insect pollinators demonstrates that birds may be able to provide more stable pollination services than insects.     

Suppression of allogeneic reactivity in vitm by the syncytiotrophoblast membrane glycocalyx of the human term placenta is carbohydrate dependent

Immunosuppressive factors isolated from trophoblast are knownto block both innate and major histocompatability complex (MHC)-dependentcell-mediated immune responses in vitro and, in some cases,in vivo. We investigated the biochemical nature of these factors,which is presently unknown. Immunosuppressive activity, assessedby inhibition of two-way MLR, was extracted from term syncytiotrophoblastmicrovilli using 3 M KCl. The activity resisted both extensivepronase digestion and heating to 90°C for 1 h, demonstratingthat intact membrane proteins were not required. Although purifiedprotein-linked oligosaccharides released by hydrazinolysis fromthe syncytiotrophoblast membrane were themselves inactive, theyblocked the immunosuppressive activity of the KCl extract. Afterpronase digestion, the activity could be fractionated by TSK55S gel filtration, followed by C18 reverse-phase chromatography.Sequential exoglycosidase digestion of hydrazine-released sugarsof the active fraction demonstrated that it contained neutralN-linked oligomannose and hybrid oligosaccharides, which normallymake up <3% of the total syncytiotrophoblast-derived proteinglycan Library. These glycopeptides of the active fraction wereassociated with membrane phospholipid micelles. The possiblemechanism by which incompletely processed N-linked oligosaccharidesexpressed by a variety of syncytiotrophoblast membrane glycoproteinsmay block allogeneic reactivity when presented as polyvalentsugar groups is discussed. glycoprotein immunosuppression oligosaccharides pregnancy trophoblast     

Enhanced brain natriuretic peptide response to peak exercise in heart transplant recipients

We investigatedthe atrial (ANP) and brain natriuretic peptides (BNP), catecholamines,heart rate, and blood pressure responses to graded upright maximalcycling exercise of eight matched healthy subjects andcardiac-denervated heart transplant recipients (HTR). Baseline heart rate and diastolic blood pressure, together with ANP(15.2 ± 3.7 vs. 4.4 ± 0.8 pmol/l;P < 0.01) and BNP (14.3 ± 2.6 vs. 7.4 ± 0.6 pmol/l; P < 0.01), were elevated in HTR, but catecholamine levels were similarin both groups. Peak exercise O₂uptake and heart rate were lower in HTR. Exercise-inducedmaximal ANP increase was similar in both groups (167 ± 34 vs. 216 ± 47%). Enhanced BNP increase was significant only in HTR (37 ± 8 vs. 16 ± 8%; P < 0.05).Similar norepinephrine but lower peak epinephrine levels were observedin HTR. ANP and heart rate changes from rest to 75% peak exercise werenegatively correlated (r = 0.76, P < 0.05),and BNP increase was correlated with left ventricular mass index(r = 0.83, P < 0.01) after hearttransplantation. Although ANP increase was notexaggerated, these data support the idea that the chronotropiclimitation secondary to sinus node denervation might stimulate ANPrelease during early exercise in HTR. Furthermore, the BNPresponse to maximal exercise, which is related to the left ventricularmass index of HTR, is enhanced after heart transplantation.

     

Relative Contribution of Apices and Mature Tissues to ABA Synthesis in Droughted Maize Root Systems

We investigated whether different parts of maize root systemscould contribute to ABA synthesis, and whether a previous cycleof soil dehydration-rehydration would modify the ability ofroots to synthesize ABA. Maize (Zea mays L.) root tissues, i.e.mature primary root sections, young and unbranched primary rootsections, secondary roots and primary root tips, from both wellwatered plants and previously drought-rewatered plants, weresubjected to different degrees of dehydration and their ABAconcentration changes were assayed. All categories of rootsfrom always well watered plants, including mature tissues containingno apex, could synthesize ABA when dehydrated. Mature primaryroot sections and their previously associated secondary rootsaccumulated less ABA in response to dehydration than the youngprimary roots and primary root tips did, and their ABA accumulationwas not substantial until dehydration was below 65% of relativewater content (RWC). Previous soil dehydration-rehydration cyclessubstantially reduced ABA accumulation in these roots in responseto dehydration again. Young primary root sections and primaryroot tips accumulated ABA much more sensitively in responseto dehydration than mature root sections, although considerablevariations existed among different batches of young primaryroot sections. Results are discussed in the context of the relativecontribution of different categories of roots to ABA synthesiswhen the root system is in drying soil. We concluded that primaryroot apices should not contribute by more than 2% to the totalABA synthesis by the root system. (Received December 15, 1995; Accepted April 19, 1996)     

A model for Acartia tonsa: effect of turbulence and consequences for the related physiological processes

A mathematical model of the energy budget of the coped Acartiatonsa is proposed. It takes into account the processes of ingestion(encounter, capture, ingestion sensu stricto), digestion (assimilation,gut transit and egestion), catabolic expenses and biomass production.In order to represent the potential effects of small-scale turbulenceon the whole physiological processes of a copepod, some processsubmodels already published are combined. A major assumptionof the model is a satiety effect resulting from midgut filling,which leads to a decrease in the feeding activity. The modelpermits the simulation of the short-term dynamics of ingestionunder different food and turbulence conditions, as well as anintegrated physiological balance over 24 h. The model is validatedthrough comparison with data at both scales Simulations showthat turbulence increases ingestion rates and gut contents,and causes a decrease in gut passage time and assimilation efficiency.As a consequence, the dependent physiological processes areaffected differently by turbulence, which preferentially increasesegestion and egg-production rates Simulated daily ingestionrates of A.tonsa, for suspension feeding on. Thalassiosira weissflogiiand for ambush predation on Strombidium sulcatum, are in goodagreement wth the available experimental observations. The concurrentdirect effect of turbulence on the copepod's metabolism, dueto increased escape reactions, is also simulated. Results ofthe model show that a switch from suspension feeding on diatomsin calm condition to ambush predation on ciliates in turbulentconditions, might allow A.tonsa to maintain its gross growthefficiency at the same level. It is suggested that a dynamicrepresentation of processes occurring over a time scale of afew seconds is necessary to obtain, once integrated over 24h, the correct simulation of the effect of microscale turbulenceon ingestion and the related physiological processes.     

Gas exchange and photosynthesis of Eucalyptus camaldulensis seedlings inoculated with different ectomycorrhizal symbionts

Eucalyptus camaldulensis Dehnh. seedlings inoculated with Pisolithus tinctorius (Pers.) Coker & Couch and Thelephora terrestris Ehrl. per Fr. were grown in well watered soil (_s –0.03 MPa) or subjected to a long-term soil water stress of up to –1.0 MPa over 13-week period in a glasshouse. After 13 weeks, all seedling containers were watered to field capacity and then water was withheld from the E. camaldulensis seedlings to induce a short-term drought. Diurnal measurements of seedling photosynthesis rate (A), leaf stomatal conductance (g) and leaf water potential (_p) were completed before, during, and after the short term drought. Although they were growing in an equal soil volume, photosynthesis rate (A), leaf stomatal conductance and leaf water potential (_p) of larger seedlings with P. tinctorius ectomycorrhizae were similar to those of smaller seedlings colonized with T. terrestris during the short-term drought period. Seedlings inoculated with Pisolithus tinctorius maintained higher photosynthesis rates over the course of the short-term drought. Thus, P. tinctorius ectomycorrhizae appear to be more efficient than those of T. terrestris in assisting seedlings to maintain gas exchange and photosynthesis under limited soil moisture conditions.     

The importance of initial seed size in wheat plant response to salinity

Large initial seed size frequently confers distinct advantages on cereal crops in terms of seedling vigor, hardiness, improved stand establishment, and higher productivity. This study was conducted to determine if these advantages inherent in the plants grown from large seeds persist when the crop is subjected to salinity stress. Two hard red spring wheat cultivars, Yecora Rojo and Anza were grown in greenhouse sand cultures from seed of two size classes that differed in weight by a factor of 2. The cultures were irrigated four times daily with complete nutrient solutions to which NaCl and CaCl₂ (2:1 molar ratio) were added to achieve osmotic potentials of –0.05. –0.55, and –0.70 MPa with electrical conductivities of 1.8, 12.8, and 15.8 dS m^-1, respectively. In response to both salinity and small initial seed size, the following plant characteristics decreased: leaf appearance rate, blade area, tillers per plant, spikelets per spike and seeds per spike. Plants grown from large seeds out-yielded those from small seeds by 8, 37, and 27% for Yecora Rojo and by 15, 30, and 23% for Anza at osmotic potentials of –0.05, –0.55 and –0.70 MPa, respectively. Compared to the corresponding nonsaline controls, the yield of Yecora Rojo grown at –0.55 MPa was 51% for the plants from large seed and 35% from the small seeds. For Anza salinized at –0.55 MPa, these values were 49 and 40%, respectively. Exploitation of the benefits derived from large initial seed size may be a cost-effective management strategy for improving wheat productivity in salt-affected areas.     

Absorption and metabolism of oral zinc gluconate in humans in fasting state,during, and after a meal

The absorption and metabolism of zinc in a commercial form for oral use (Rubozinc^®, 15 mg zinc as gluconate) were investigated in 10 subjects by a kinetic study of the serum zinc profile after administration of 45 mg zinc under three conditions: after an overnight fast, during a standardized breakfast, and 2 h after this meal. The pharmacokinetic parameters were calculated by a method suitable to the characterization of rebound effects (recycling of the element in the gastrointestinal tract). In fasting state, the parameters were comparable to those previously collected in the same subjects with oral 45 mg zinc as sulfate, except with very significantly higherC _max and area under curve (AUC), showing a better bioavailability for zinc in the commercial form. The light meal perturbed the absorption process as evidenced by the significant increases in the lag time (+180%), thet _max (+57%), and the lag times for the first two cycles during the meal. However, the parameters returned to normal values 2 h after the meal. TheC _max only moderately decreased during the meal (31%) as did the AUC (?28%). An important delay in the absorption of zinc in the commercial form when taken during a meal was therefore demonstrated, but the effect on zinc bioavailability was only moderate.     

Effects of mutations in the central helix of troponin C on its biological activity

To investigate the role of the central helix of skeletal muscle troponin C (TnC), five deletion mutants (Dobrowolski, Z., Xu, G.Q., and Hitchcock-DeGregori, S.E. (1991) J. Biol. Chem. 266, 5703-5710) of chicken TnC in the D/E linker region (K87EDAKGKSEEE97), dEDA, dKG, dKGK, dSEEE, and dKED-AKGK, were assayed for their ability to regulate muscle contraction by testing their effectiveness in restoring force and Ca2+ regulation to TnC-depleted rabbit skinned skeletal muscle fibers. By comparison with rabbit skeletal TnC, wild-type TnC, and chicken TnC, all mutants except dKG equally restored force development and Ca2+ regulation to TnC-depleted skinned muscle fibers. In contrast, approximately 4 times more dKG than rabbit skeletal TnC was required to reach 50% force restoration. Also, the pCa50 for dKG activation of force was significantly decreased. Thus, most of the TnC mutants that we studied did not have significantly altered biological activity in the skinned fiber assay. However, the 2-residue deletion in the central helix (dKG) significantly affected TnC activity. This deletion would be expected to produce a 160 degree rotation in the alpha-helix versus 60 degrees for dKGK and dEDA, 40 degrees in dSEEE, and 20 degrees in dKEDAKGK. Therefore, the change in orientation of the two Ca2(+)-binding domains appears to be a major parameter affecting TnC activity. The shift in the Ca2+ dependence in force activation may result from the inability of the Ca2(+)-specific domain to properly interact with its binding site on troponin I, an interaction which is known to increase the affinity of TnC for Ca2+ (Potter, J.D., and Gergely, J. (1975) J. Biol. Chem. 250, 4628-4633). In addition, the length of the central helix of TnC, Gly92, and the negatively charged cluster, EEE, appear not to be crucial for TnC activity.