The innate immune receptor MDA5 limits rotavirus infection but promotes cell death and pancreatic inflammation

Melanoma differentiation‐associated protein 5 (MDA5) mediates the innate immune response to viral infection. Polymorphisms in IFIH1, the gene coding for MDA5, correlate with the risk of developing type 1 diabetes (T1D). Here, we demonstrate that MDA5 is crucial for the immune response to enteric rotavirus infection, a proposed etiological agent for T1D. MDA5 variants encoded by minor IFIH1 alleles associated with lower T1D risk exhibit reduced activity against rotavirus infection. We find that MDA5 activity limits rotavirus infection not only through the induction of antiviral interferons and pro‐inflammatory cytokines, but also by promoting cell death. Importantly, this MDA5‐dependent antiviral response is specific to the pancreas of rotavirus‐infected mice, similar to the autoimmunity associated with T1D. These findings imply that MDA5‐induced cell death and inflammation in the pancreas facilitate progression to autoimmune destruction of pancreatic β‐cells.     

Allocation of Photosynthate to Individual Tubers of Solanum tuberosum L.: II. RELATIONSHIP BETWEEN GROWTH RATE, CARBOHYDRATE CONCENTRATION AND 14C-PARTITIONING WITHIN TUBERS

Potato plants (Solanum tuberosum L.) were grown in water culturein a controlled environment. The growth rates of individualtubers were closely reflected by their ¹⁴C-content 20 h after¹⁴CO₂ had been applied to the aerial parts of the shoot for4 h. The ¹⁴C-content of the tuber (sink strength) was significantlycorrelated to the ¹⁴C-concentration of the tuber tissue (¹⁴Cg^–1 fr. wt.=sink activity). The sink activity, which differedbetween individual tubers by up to a factor of 10, was alsoclosely related to the conversion rates of ¹⁴C into the starchand the remainder as well as to the ¹⁴C-content in the ethanolsoluble fraction. This indicates the simultaneous use of photosynthatefor growth and storage in the growing tubers. No preferenceof photosynthate utilization for either of these processes couldbe detected in relation to the sink activity of the tubers.Tubers with high sink activity imported ¹⁴C-labelled photosynthateat higher rates although their tissue contained higher concentrationsof reducing sugars and sucrose than the tissue of tubers withlow sink activity. Despite the close relationship between sinkactivity and the rate of starch synthesis (¹⁴C-conversion intostarch), no significant correlation was found between sink activityand the actual starch concentration of the tissue. The applicationof zeatin riboside directly onto individual tubers increasedtheir growth rates in comparison to non-treated tubers of thesame plant. The results indicate the importance of both growthand storage processes for the regulation of sink activity inyoung potato tubers. Key words: Potato tuber, ¹⁴C-photosynthate partitioning, zeatin riboside application     

Carbon and water fluxes in a calcareous grassland under elevated CO2

1. As part of a long-term study of the effects of elevated CO₂ on biodiversity and ecosystem function in a calcareous grassland, we measured ecosystem carbon dioxide and water-vapour fluxes over 24-h periods during the 1994 and 1995 growing seasons. Data were used to derive CO₂ and H₂O gas-exchange response functions to quantum flux density (QFD).
2. The relative increase in net ecosystem CO₂ flux (NEC) owing to CO₂ enrichment increased as QFD rose. Daytime NEC at high QFD under elevated CO₂ increased by 25% to 60%, with the greatest increases in the spring and after mowing in June when above-ground biomass was lowest. There was much less stimulation of NEC in early June and again in October when the canopy was fully developed. Night-time NEC was not significantly altered under elevated CO₂.
3. Short-term reversal of CO₂ concentrations between treatments after two seasons of CO₂ exposure provided evidence for a 50% downward adjustment of NEC expressed per unit above-ground plant dry weight. However, when expressed on a land area basis, this difference disappeared because of a c. 20% increase in above-ground biomass under elevated CO₂.
4. Ecosystem evapotranspiration (ET) was not significantly altered by elevated CO₂ when averaged over all measurement dates and positions. However, ET was reduced 3–18% at high QFD in plots at the top of the slope at our study site. In summary, CO₂ enrichment resulted in a large stimulation of ecosystem CO₂ capture, especially during periods of a large demand of carbon in relationship to its supply, and resulted in a relatively small and variable effect on ecosystem water consumption.     

Le Cortex de la Vacuole Contractile et son Ultrastructure chez les Ciliés

SYNOPSIS. In various ciliates the contractile vacuole is a permanent organelle, delimited by a differentiated cortex.
The cortex is made up of a dense reticulum of anastomosing tubules limited by a smooth membrane, and vesicles. This "spongiome" can be considered as a localized and specialized condensation of the endoplasmic reticulum.     

曲酸生产菌的复合诱变选育*

以黄曲霉(Aspergillus flavus.)为出发菌株,经3次紫外线、1次^60Co、3次亚硝基胍多重复合诱变处理,选育获得曲酸生产菌UCN7—17,配以最佳培养条件,发酵7d,曲酸产量由原来的0．926％,提高到6．3％。实验证明采用多因子复合诱变,能有效改变菌株对诱变因素敏感性,提高变异率,逐步提高突变株的产酸水平。     

Auxin perception and polar auxin transport are not always a prerequisite for differential growth

Using time-lapse photography, we studied the response kinetics of low light intensity-induced upward leaf-movement, called hyponastic growth, in Arabidopsis thaliana. This response is one of the traits of shade avoidance and directs plant organs to more favorable light conditions. Based on mutant- and pharmacological data we demonstrated that among other factors, functional auxin perception and polar auxin transport (PAT) are required for the amplitude of hyponastic growth and for maintenance of the high leaf angle, upon low light treatment. Here, we present additional data suggesting that auxin and PAT antagonize the hyponastic growth response induced by ethylene treatment. We conclude that ethylene- and low light-induced hyponastic growth occurs at least partly via separate signaling routes, despite their strong similarities in response kinetics.Key words: hyponastic growth, petiole, Arabidopsis, ethylene, low light, auxin, polar auxin transport, differential growthUpward leaf movement (hyponastic growth) is a trait of several plant species to escape from growth-limiting conditions.^1,2 Interestingly, Arabidopsis thaliana induces a marked hyponastic growth response triggered by various environmental stimuli, including complete submergence, high temperature, canopy shade and spectral neutral low light intensities (Fig. 1).^3–6 The paper of Millenaar et al. in the New Phytologist 2009,⁷ provides a detailed analysis of low light intensity-induced hyponastic growth and components of the signal transduction are characterized using time-lapse photography. Low light intensity-induced hyponastic growth is a component of the so-called shade avoidance syndrome. Light-spectrum manipulations and mutant analyses indicated that predominantly the blue light wavelength region affects petiole movement and fast induction of hyponastic growth to low light conditions involves the photoreceptor proteins Cryptochrome 1 (Cry1), Cry2, Phytochrome-A (PhyA) and PhyB. Moreover, we show that also photosynthesis-derived signals can induce differential growth.Open in a separate windowFigure 1Typical hyponastic growth phenotype of Arabidopsis thaliana. Side view of Columbia-0 plants treated 10 h with ethylene (5 µl l⁻¹) or low light (20 µmol m⁻² s⁻¹). Plants in control light conditions were in 200 µmol m⁻² s⁻¹. Both stimuli induce a clear leaf inclination (hyponasty) relative to the horizontal by differential growth of the petioles. Plants kept in control conditions only show modest diurnal leaf movement and leaf angles gradually decline over time due to maturation of the leaves. Note that the paint droplets were applied to facilitate quantitative measurement of leaf angle kinetics in a time-lapse camera setup.⁷The hyponastic growth response to low light intensity was not affected in several ethylene-insensitive mutant lines. Moreover, low light did not affect expression of ethylene inducible marker genes nor differences in ethylene release were noted. Therefore, we concluded that low light-induced hyponastic growth is independent of ethylene signaling. This is perhaps surprising, because ethylene is the main trigger of hyponastic growth induced by complete submergence in several species. Interestingly, both ethylene and low light can induce hyponastic growth in Arabidopsis with similar kinetics.³We showed that plants mutant in auxin perception components (transport inhibitor response1 (tir1) and tir1 afb1 afb2 afb3 quadruple, containing additional mutant alleles of TIR1 homologous F-box proteins) and plants mutant in (polar) auxin transport (tir3-1, pin-formed3 (pin3) and pin7) components had a lower hyponastic growth amplitude in low light conditions.⁷ Moreover, these mutants were less able to maintain the high leaf angles after the response maximum. Both characteristics were also noted in plants pre-treated with the polar auxin transport (PAT) inhibitor 2,3,5-triiodobenzoic acid (TIBA). We therefore concluded that auxin perception and PAT are involved in the regulation of low light-induced hyponastic growth.⁷ Interestingly, we observed that TIBA pretreatment did not inhibit ethylene-induced hyponastic growth. In fact, the response upon ethylene treatment was even modestly enhanced. In agreement with this observation, we show here that the above mentioned auxin perception and PAT mutants also showed a slightly enhanced hyponastic growth response upon ethylene treatment (Fig. 2).Open in a separate windowFigure 2Auxin involvement in ethylene induced hyponasty. Effect of exposure to ethylene (5 µl l⁻¹) on the kinetics of hyponastic petiole growth (A) in Arabidopsis thaliana Columbia-0 plants treated with 50 µm TIBa (open circles) or a mock treatment (line) adapted from Supporting Information Figure S3 of Millenaar et al. (2009)⁷ and (B–F) in Arabidopsis auxin signaling and polar auxin transport mutants (closed circles), compared to the wild type response to low light (lines). Petiole angles are pair wise subtracted, which corrects for diurnal petiole movement in control conditions. For details on this procedure, growth conditions, treatments, data acquirement and analysis see.^7,13 Error bars represent standard errors; n ≥ 12. mutants were obtained from the Nottingham Arabidopsis Stock Center (accession numbers are shown between brackets) or from the authors describing the lines. tir1-1 (n3798,¹⁴), tir1-1 afb1-1 afb2-1 (in a mixed Columbia/Wassilewskija background),¹⁵ tir3-1,¹⁴ pin3-4 (n9363,¹⁶) and pin7-1 (n9365,¹⁰).Despite that auxin and PAT are required for many differential growth responses such as phototropism and gravitropism,^8,11 these data indicate that auxin perception and PAT are not obligatory for ethylene-induced hyponasty in Arabidopsis per se. In fact, one might even conclude that auxin and PAT antagonizes ethylene-induced hyponasty. These results are partly in agreement with observations on the wetland species Rumex palustris, were pretreatment with the auxin-efflux carrier 1-naphthylphthalamic acid (NPA) resulted in doubling of the lag-phase for hyponastic growth under water, but hardly affected the amplitude of the response.¹²Together, this indicates that auxin is not always a prerequisite for differential growth responses. Based on the apparent contrasting effects of auxin perception and PAT in low light- and ethylene-induced hyponastic growth, we conclude that ethylene and low light induce hyponastic growth, at least partly, via separate signaling routes.     

Taphonomy and compositional fidelity of Quaternary fossil assemblages of terrestrial gastropods from carbonate-rich environments of the Canary Islands

Quaternary aeolian deposits of the Canary Islands contain well‐preserved terrestrial gastropods, providing a suitable setting for assessing the taphonomy and compositional fidelity of their fossil record over ~13 kyr. Nine beds (12, 513 shells) have been analysed in terms of multivariate taphonomic and palaeoecological variables, taxonomic composition, and the stratigraphic and palaeontological context. Shells are affected by carbonate coatings, colour loss and fragmentation. Shell preservation is size‐specific: juveniles are less fragmented and show colour preservation more commonly than adults. In palaeosols, the adult shell density correlates negatively with the proportion of fragmented adults, negatively with the proportion of juveniles, and positively with the proportion of adults with coatings. High bioturbation intensity in palaeosols is associated with low shell fragmentation and high proportion of shells with coatings. These relationships imply that high adult density in palaeosols was driven by an increase in shell production rate (related to a decrease in predation rates on adults and a decrease in juvenile mortality) and a decrease in shell destruction rate (related to an increase in durability enhanced by carbonate precipitation). In dunes, the relationships between taphonomic alteration, shell density and bioturbation are insignificant. However, dune assemblages are characterized by a lower frequency of shells with coatings and higher rates of colour loss, indicating lower shell durability in dunes than in palaeosols. Additionally, non‐random differences in the coating proportion among palaeosols imply substantial temporal variation in the rate of carbonate crust formation, reflecting long‐term changes in bioturbation intensity that covaries positively with shell preservation. Dunes and palaeosols do not differ in species abundances despite differences in the degree of shell alteration, suggesting that both weakly and strongly altered assemblages offer data with a high compositional fidelity. Carbonate‐rich terrestrial deposits originating in arid conditions can enhance the preservation of gastropods and result in fossil assemblages that are suitable for palaeoecological and palaeoenvironmental studies of terrestrial ecosystems.     

Efficacy of neem and diatomaceous earth against cowpea aphids and their deleterious effect on predating Coccinelidae

Philippine vegetable farmers commonly use synthetic insecticides to control insect pests on yardlong beans ( Vigna unguiculata ssp. sesquipedalis ). An important pest on yardlong beans is the cowpea aphid, Aphis craccivora Koch. Overuse of chemical insecticides and the adverse consequences for farmer health and for the environment have been reported. The natural enemies of A. craccivora , such as the coccinelidae beetle, Menochilus sexmaculatus (Fabr.), do not provide economic control on their own. In the present study the efficacy of the biological insecticide neem (both commercial and homemade) alone, and in combination with diatomaceous earth against A. craccivora was evaluated. The same insecticides were also examined to investigate their deleterious effect on M. sexmaculatus . The efficacies of different treatments with biological insecticides were compared with the use of the synthetic insecticide Hostathion (triazophos). Experiments were conducted under Philippine lowland conditions during the dry season when the occurrence of pest problems in yardlong beans is very great. Commercial neem, NeemAzal-T/S (Trifolio-M GmbH, Lahnau, Germany), significantly reduced the number of A. craccivora . NeemAzal-T/S and diatomaceous earth in combination produced the best control of A. craccivora and were less toxic to M. sexmaculatus than treatment with Hostathion (triazophos). Aqueous homemade neem solution did not control the A. craccivora populations.