Buffalograss decreases ramet propagation in infertile patches to enhance interconnected ramet proliferation in fertile patches

Buffalograss (Buchloë dactyloides) is known for its low-nutrient tolerance. However, in natural habitats, nutrients are usually patchily distributed. For clonal plants like buffalograss, physiological integration is an important strategy to cope with adverse environmental conditions. In order to examine how integration helps buffalograss to survive in patchy conditions, a greenhouse experiment was conducted for 91 days. Interconnected ramet pairs of stoloniferous buffalograss were planted in two partitioned same-sized containers, and subjected to identical or contrasting nutrient supply. In contrast to normally perceived resource-sharing concepts, results showed that buffalograss genets reduced production of new ramets in nutrient-poor patches promoting at the same time propagation of interconnected ramets in nutrient-rich patches. Ramets in nutrient-rich patches gained significant benefit from heterogeneous treatments, whereas nutrient-poor ramets performed even worse than in uniform low-nutrient treatment. Younger ramets developed more biomass than elder ramets with the same amounts of nutrient supply under homogeneous treatment, while elder ramets were more tolerant when nutrients were scarce. Heterogeneity had a particular strong effect on stolons and new ramet production in nutrient-rich patches. Rooted ramets in nutrient-poor patches suffered from a by-pass of nutrients to interconnected ramets on nutrient-rich substrate that probably resulted from different transpiration rates. We conclude that this resource-sharing strategy is advantageous for buffalograss to concentrate more ramets in fertile patches, and facilitate the survivorship of more buffalograss ramets in adverse environments with uneven nutrient supply.     

The plant growth-promoting rhizobacterium Bacillus cereus AR156 induces systemic resistance in Arabidopsis thaliana by simultaneously activating salicylate- and jasmonate/ethylene-dependent signaling pathways

Bacillus cereus AR156 is a plant growth-promoting rhizobacterium that induces resistance against a broad spectrum of pathogens including Pseudomonas syringae pv. tomato DC3000. This study analyzed AR156-induced systemic resistance (ISR) to DC3000 in Arabidopsis ecotype Col-0 plants. Compared with mock-treated plants, AR156-treated ones showed an increase in biomass and reductions in disease severity and pathogen density in the leaves. The defense-related genes PR1, PR2, PR5, and PDF1.2 were concurrently expressed in the leaves of AR156-treated plants, suggesting simultaneous activation of the salicylic acid (SA)- and the jasmonic acid (JA)- and ethylene (ET)-dependent signaling pathways by AR156. The above gene expression was faster and stronger in plants treated with AR156 and inoculated with DC3000 than that in plants only inoculated with DC3000. Moreover, the cellular defense responses hydrogen peroxide accumulation and callose deposition were induced upon challenge inoculation in the leaves of Col-0 plants primed by AR156. Also, pretreatment with AR156 led to a higher level of induced protection against DC3000 in Col-0 than that in the transgenic NahG, the mutant jar1 or etr1, but the protection was absent in the mutant npr1. Therefore, AR156 triggers ISR in Arabidopsis by simultaneously activating the SA- and JA/ET-signaling pathways in an NPR1-dependent manner that leads to an additive effect on the level of induced protection.     

Synthesis and evaluation of new iRGD peptide analogs for tumor optical imaging

Recently, a disulfide-based cyclic RGD peptide called iRGD, that is, c(CRGDKGPDC), has been reported to interact with both integrin and neuropilin-1 receptors for cellular and deep tissue penetration to improve the imaging sensitivity and therapeutic efficacy. In this study, two new near-infrared fluorescent iRGD conjugates, that is, Ac-Cys(IRDye®800CW)-iRGD (1), and its dual labeling analog DOTA-Cys(IRDye®800CW)-iRGD (2) were synthesized via the specific mercapto-maleimide reaction for tumor imaging. Both 1 and 2 showed significant tumor localization in optical imaging of MDA-MB-435 tumor-bearing mice. The potential of such iRGD compounds in tumor-targeted imaging and drug delivery deserves further exploration.     

Structural basis of γH2AX recognition by human PTIP BRCT5-BRCT6 domains in the DNA damage response pathway

Human Pax2 transactivation domain-interacting protein (hPTIP), containing six BRCT domains, is an essential protein required for the IR induced DDR process with an unclear role. Here we report that the tandem BRCT5–BRCT6 domain of hPTIP recognizes the γH2AX tail, and this interaction depends on the phosphorylation of H2AX Ser139 and binding with the carboxyl ending peptide to the aminoacyl ending peptide. The 2.15 Å crystal structure of hPTIP BRCT5/6–γH2AX complex and mutation analysis provide molecular evidence for direct interactions between PTIP and γH2AX. This interaction proffers a new clue to identify the role of PTIP in DDR pathways.

Structured summary of protein interactions

PTIP and gamma H2AXbind by fluorescence polarization spectroscopy (View Interaction: 1, 2, 3, 4, 5, 6).PTIP and gamma H2AXbind by X-ray crystallography (View interaction).     

Targeted introgression of a wheat stem rust resistance gene by DNA marker-assisted chromosome engineering

Chromosome engineering is a useful strategy for transfer of alien genes from wild relatives into modern crops. However, this strategy has not been extensively used for alien gene introgression in most crops due to low efficiency of conventional cytogenetic techniques. Here, we report an improved scheme of chromosome engineering for efficient elimination of a large amount of goatgrass (Aegilops speltoides) chromatin surrounding Sr39, a gene that provides resistance to multiple stem rust races, including Ug99 (TTKSK) in wheat. The wheat ph1b mutation, which promotes meiotic pairing between homoeologous chromosomes, was employed to induce recombination between wheat chromosome 2B and goatgrass 2S chromatin using a backcross scheme favorable for inducing and detecting the homoeologous recombinants with small goatgrass chromosome segments. Forty recombinants with Sr39 with reduced surrounding goatgrass chromatin were quickly identified from 1048 backcross progenies through disease screening and molecular marker analysis. Four of the recombinants carrying Sr39 with a minimal amount of goatgrass chromatin (2.87-9.15% of the translocated chromosomes) were verified using genomic in situ hybridization. Approximately 97% of the goatgrass chromatin was eliminated in one of the recombinants, in which a tiny goatgrass chromosome segment containing Sr39 was retained in the wheat genome. Localization of the goatgrass chromatin in the recombinants led to rapid development of three molecular markers tightly linked to Sr39. The new wheat lines and markers provide useful resources for the ongoing global effort to combat Ug99. This study has demonstrated great potential of chromosome engineering in genome manipulation for plant improvement.     

IFN-γ acts on the airway epithelium to inhibit local and systemic pathology in allergic airway disease

Inhibiting allergic airway inflammation is the goal of therapy in persistent asthma. Administration of medication via the airways delivers drug directly to the site of inflammation and avoids systemic side effects but often fails to modulate systemic features of asthma. We have shown that Th1 cells, through production of IFN-γ, inhibit many Th2-induced effector functions that promote disease. Using a newly generated mouse that expresses IFN-γR only on airway epithelial cells, we show that the airway epithelium controls a range of pathological responses in asthma. IFN-γ acting only through the airway epithelium inhibits mucus, chitinases, and eosinophilia, independent of Th2 cell activation. IFN-γ signaling through the airway epithelium inhibits eosinophil generation in the bone marrow, indicating that signals on the airway mucosal surface can regulate distant functions to inhibit disease. IFN-γ actions through the airway epithelium will limit airway obstruction and inflammation and may be therapeutic in refractory asthma.     

PSI-driven cyclic electron flow allows intertidal macro-algae Ulva sp. (Chlorophyta) to survive in desiccated conditions

Ulva sp. (Chlorophyta) is a representative species of the intertidal macro-algae responsible for the green tides that occurred along the shores of Qingdao in 2008 and had detrimental effects on the preparation for the 2008 Beijing Olympic Games sailing competition. In view of its significance, we have investigated the photosynthetic performance of the photosystems and the changes in photosynthetic electron transport that occur during desiccation and rehydration of Ulva sp. The PSII activity in Ulva sp. declined gradually during the course of desiccation, which was reflected by the decreased maximum quantum yield and effective quantum yield, whereas the PSI activity fluctuated significantly. In contrast, the electron transport rates of PSII approached zero at severe levels of desiccation, but the electron transport of PSI, which still operated, could be suppressed effectively by a specific inhibitor. Furthermore, the electron transport of PSI during rehydration of desiccated thalli was recovered faster than that of PSII. All these results implied that the linear electron flow was abolished in desiccated Ulva sp., whereas the cyclic PSI activity was significantly elevated, was still active at severe levels of desiccation and could be restored faster than PSII activity. Based on these results, we concluded the PSI-driven cyclic electron flow might provide desiccation tolerance and additional flexibility for the cell physiology of Ulva sp. under desiccation conditions, which might be one of the most important factors that make Ulva sp. well suited to experience daily cycles of desiccation at low tide and rehydration at high tide.     

Resource availability, species composition and sown density effects on productivity of experimental plant communities

Productivity of artificial grassland communities was investigated in a 6-year field experiment on the Qinghai-Tibetan Plateau. In the experiment, assemblages varying in seven species compositions and four density gradients were grown in fertilized and non-fertilized subplots. We measured biomass of sown species as an indicator of community productivity. In general, 6-years of experiments indicated that: (i) species composition had a significant influence on community productivity. During the initial phase of the experiment, sown density significantly affected community productivity, but the effects disappear with the increase of grown years. This productivity increased with biodiversity increase and fertilization, while the biodiversity effects disappeared when the influence of composition was removed. (ii) The increase of community productivity with biodiversity was resulted from joint effects of selection and complementarity. (iii) With an increase of growth time, the selection effects become weaker while complementarities become enhanced. Influence of density on both effects was significantly different in early stages, but ultimately this all became insignificant. Fertilization dramatically increased the complementarity effects in all experiment processes, but had different influences on selection effects during different experimental period.