铜绿假单胞菌对镉胁迫苗期水稻根系活力及叶片生理特性的影响

为揭示耐镉铜绿假单胞菌缓解镉胁迫水稻的生理效应,以无镉处理为对照,通过添加菌液、空载体、菌剂及20μmol·L^-1 Cd进行水培试验,分析了菌株对苗期水稻根系活力及叶片生理特性的影响.结果表明:镉胁迫显著抑制了水稻的根系活力,降低了叶片光合效率、抗氧化酶活性及可溶性蛋白、类黄酮与总酚含量,提高了叶片丙二醛(MDA)和超氧阴离子(O2-)含量.与镉处理相比,添加菌液、菌剂处理的水稻根系活力分别提高了36.1%~42.5%、49.4%~53.0%;叶片净光合速率提高了118.5%~147.1%、137.6%~156.9%;可溶性蛋白含量提高了37.0%~49.3%、37.7%~72.6%.菌剂处理的水稻叶片超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)活性分别比Cd处理提高了36.9%~42.6%、82.7%~92.6%、43.3%~52.2%,菌液处理的SOD、POD、CAT则分别比Cd处理提高了25.8%~36.6%、40.9%~55.9%、24.0%~29.2%,菌剂对水稻叶片抗氧化酶的促进效应显著高于菌液;菌剂、菌液处理的水稻叶片MDA含量分别比Cd处理降低了44.8%~54.7%、29.4%~41.9%;O2-含量减少了9.9%~10.2%、3.0%~7.1%;菌剂处理后类黄酮、总酚含量分别比Cd处理提高了125.4%~135.7%、100.8%~119.4%;菌液处理后则分别提高了139.4%~146.7%、115.0%~134.7%.可见,铜绿假单胞菌及其菌剂通过提高苗期水稻根系活力、光合作用促进了苗期水稻的生长.铜绿假单胞菌通过增强水稻抗氧化酶活性、提高类黄酮和总酚等抗氧化物质含量,表现出显著的缓解镉胁迫效应.     

Structural insights into the catalytic mechanism of 5-methylthioribose 1-phosphate isomerase

5-Methylthioribose 1-phosphate isomerase (M1Pi) is a crucial enzyme involved in the universally conserved methionine salvage pathway (MSP) where it is known to catalyze the conversion of 5-methylthioribose 1-phosphate (MTR-1-P) to 5-methylthioribulose 1-phosphate (MTRu-1-P) via a mechanism which remains unspecified till date. Furthermore, although M1Pi has a discrete function, it surprisingly shares high structural similarity with two functionally non-related proteins such as ribose-1,5-bisphosphate isomerase (R15Pi) and the regulatory subunits of eukaryotic translation initiation factor 2B (eIF2B). To identify the distinct structural features that lead to divergent functional obligations of M1Pi as well as to understand the mechanism of enzyme catalysis, the crystal structure of M1Pi from a hyperthermophilic archaeon Pyrococcus horikoshii OT3 was determined. A meticulous structural investigation of the dimeric M1Pi revealed the presence of an N-terminal extension and a hydrophobic patch absent in R15Pi and the regulatory α-subunit of eIF2B. Furthermore, unlike R15Pi in which a kink formation is observed in one of the helices, the domain movement of M1Pi is distinguished by a forward shift in a loop covering the active-site pocket. All these structural attributes contribute towards a hydrophobic microenvironment in the vicinity of the active site of the enzyme making it favorable for the reaction mechanism to commence. Thus, a hydrophobic active-site microenvironment in addition to the availability of optimal amino-acid residues surrounding the catalytic residues in M1Pi led us to propose its probable reaction mechanism via a cis-phosphoenolate intermediate formation.     

Spinal cord tissue affects sprouting from aortic fragments in ex vivo co‐culture

It is a well‐known fact, that there is a close interconnection between vascular and neural structures in both embryonic development and postnatal life. Different models have been employed to dissect the mechanisms of these interactions, ranging from in vitro systems (e.g., co‐culture of neural and endothelial cells) to in vivo imaging of central neural system recovery in laboratory animals after artificially induced trauma. Nevertheless, most of these models have serious limitations. Here, we describe an ex vivo model, representing an organotypic co‐culture of aortic fragments (AF) with longitudinal slices of mouse neonatal spinal cord (SC) or dorsal root ganglia (DRG). The samples were co‐cultured in a medium adapted for SC tissue and lacking any pro‐angiogenic or neurotrophic growth factors. It was found, that cultivation of AFs in the SC injury zone (transversal dissection of a SC slice) resulted in the initiation of active aortic sprouting. Remarkably, the endothelial cells exiting the AFs never invaded the SC tissue, concentrating in a nearby area (negative taxis). In contrast, the DRGs, while also promoting the sprouting, were a target of active endothelial CD31⁺ cell invasion (positive taxis). Thus, the tissues of both central and peripheral nervous systems have a prominent positive effect on aortic sprouting, while the vector of endothelial cell expansion is strictly nervous‐tissue‐type dependent. The ex vivo AF co‐culture with SC or DRG appeared to be a useful and promising model for a further endeavor into the mechanisms driving the complex interactions between neural and endothelial tissues.     

Anthropogenic nitrogen enrichment enhances soil carbon accumulation by impacting saprotrophs rather than ectomycorrhizal fungal activity

There is evidence that anthropogenic nitrogen (N) deposition enhances carbon (C) sequestration in boreal forest soils. However, it is unclear how free‐living saprotrophs (bacteria and fungi, SAP) and ectomycorrhizal (EM) fungi responses to N addition impact soil C dynamics. Our aim was to investigate how SAP and EM communities are impacted by N enrichment and to estimate whether these changes influence decay of litter and humus. We conducted a long‐term experiment in northern Sweden, maintained since 2004, consisting of ambient, low N additions (0, 3, 6, and 12 kg N ha^?1 year^?1) simulating current N deposition rates in the boreal region, as well as a high N addition (50 kg N ha^?1 year^?1). Our data showed that long‐term N enrichment impeded mass loss of litter, but not of humus, and only in response to the highest N addition treatment. Furthermore, our data showed that EM fungi reduced the mass of N and P in both substrates during the incubation period compared to when only SAP organisms were present. Low N additions had no effect on microbial community structure, while the high N addition decreased fungal and bacterial biomasses and altered EM fungi and SAP community composition. Actinomycetes were the only bacterial SAP to show increased biomass in response to the highest N addition. These results provide a mechanistic understanding of how anthropogenic N enrichment can influence soil C accumulation rates and suggest that current N deposition rates in the boreal region (≤12 kg N ha^?1 year^?1) are likely to have a minor impact on the soil microbial community and the decomposition of humus and litter.     

Positive Effects of Biochar on the Degraded Forest Soil and Tree Growth in China: A Systematic Review

Soil degradation threatens the forest sustainable productivity, particularly in afforestation system. Biochar derived from agroforestry waste or biomass can potentially improve the degraded forest soil and promote the tree growth. To expand the application of biochar for forestry productivity improvement, we here reviewed the effects and the underlying mechanisms of biochar on the degraded forest soil and tree growth. Totally 96 studies that conducted from pot to field investigations in China were summarized. The result suggested that biochar generally exerted positive effects on restoration of degraded forest soil such as that with compaction, acidification or soil erosion, which are mainly manifested by improving soil porosity, increasing pH, enhancing erosion resistance and mitigating greenhouse gas emissions. Furthermore, biochar incorporation promoted the growth of tested trees in most cases, which effect was mainly attributing to directly supplying nutrients, improving soil physio-chemical properties, enhancing the root’s nutrient absorption capacity, and enlarging the living space. In summary, current studies demonstrate that biochar has a unique potential for improving degraded forest soils and promoting tree growth. However, investigations on the underlying mechanisms and the long-term effects should be strengthened.