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Eleven grape cultivars were analysed to explore the variety differences of fresh grape phenolic profiles. The results showed that free phenolics were predominant in grape skins and pulps, and showed the higher antioxidant activities than bound. In 11 cultivars, Muscat Kyoho extracts had the highest total phenolic content in skins(10.525 mg GAE g~(–1) FW) and pulps(1.134 mg GAE g~(–1) FW), and exhibited the highest DPPH radical scavening capacity(EC_(50)=11.7 μg mL~(–1)) and oxygen radical absorbance capacity(ORAC) value(190.57 μmol TE g~(–1) FW) of free phenolic in skin. In addition, the most abundant phenolics in grape skins were found to be flavonoids such as kaempferol in Kyoho skin(541.2 μg g~(–1) FW), rutin, catechin and epicatechin in Muscat Kyoho skin(262.3, 86.3 and 70.0 μg g~(–1) FW, respectively). Furthermore, the principal component analysis showed a strong difference of phenolic profiles with the cultivars, existing forms and distributions. Pearson correlation coefficient analysis showed a significant linear correlation between total phenolic content and antioxidant activity(P0.05). Therefore, both skins and pulps were rich sources of bioactive phenolic compounds, and Muscat Kyoho was the ideal source among all samples. 相似文献
84.
以蒙古黄芪-根腐病菌(Fusarium solani和F. acuminatum)为互作体系,测定苯丙烷途径关键酶苯丙氨酸解氨酶(PAL)、肉桂酸-4-羟化酶(C4H)及4-香豆酸-辅酶A连接酶(4CL)活性的变化,以期获得黄芪抗根腐病菌侵染机制的信息,为抗病育种工作提供参考。试验采用幼苗浸根法接种病菌,分光光度法测定3种酶的动态变化。结果表明,F. solani侵染黄芪后,PAL和C4H活性与对照相比明显升高,并在7、21天出现2个酶活高峰;4CL活性则随着时间的延长持续上升,7、21天时也显著高于对照。F. acuminatum侵染黄芪后,PAL、C4H和4CL的活性均在21天显著高于对照。可见2种病原菌在侵染黄芪过程中,苯丙烷途径的关键酶被不同程度地激活,但2种病菌激活各酶的时间和规律有所差异,表明黄芪对这2种病菌的抗性机制明显不同。 相似文献
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采用盆栽的方法,分析磁处理对豌豆根际土壤生物学性状的影响,旨在探究磁处理对豌豆根际土壤肥力及健康状况的影响。试验设置无处理(对照CK),添加铁粉(A)、磁化铁粉(B)、场强为0.2特斯拉(T)磁铁+铁粉(C)以及0.2 T磁铁(D)的处理,基于高通量测序技术分析磁处理对豌豆根际土壤生物学性状的影响。结果表明:C处理显著增加豌豆根际土壤中可培养细菌和真菌数量,同时微生物生物量C、N、P与CK相比分别增加了34.0%、46.0%、44.2%;β-葡萄糖苷酶、氨肽酶、磷酸酶酶活性分别增加了24.6%、23.7%、31.8%;另一方面,C处理中土壤细菌丰富度和多样性指数Ace、Chao1、Shannon指数显著高于CK;属(Genus)分类水平韦恩图分析中上,CK处理特有的属细菌主要有3个:Sneathiella、Desulfurispora、nannocystaceae;A处理特有的属细菌有7个;B处理特有的属细菌亦有7个;C处理特有的属细菌有11个;D处理特有的属细菌有8个。综上所述,C处理能够显著提高豌豆根际土壤中可培养微生物数量、微生物生物量(C、N、P)、酶活性和细菌多样性等多项指示土壤肥力和健康状况的生物学指标,表明磁场强度为0.2 T的磁铁+5 g磁化铁粉处理具有提高土壤肥力抵御土传病害的能力。 相似文献
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Nitrification plays a central role in global nitrogen cycle, which is affected by biological interaction between soil microfauna and microorganisms. However, the complexity of soil biotic communities made it difficult to reveal organizational principles of the community and the interactions among species. Here, we used the network analysis to decipher the interactions between nematodes and ammonia oxidizers within aggregate fractions under 10-year manure application, and examine their associations with soil variables and potential nitrification activity (PNA). Three aggregate fractions included large macroaggregates (>2000 μm, LA), small macroaggregates (250–2000 μm, SA), and inter-aggregate soil and space (<250 μm, IA). Aggregate factions showed a remarkable effect on association networks of nematodes and ammonia oxidizers. The average connectivity (avgK) and the number of edges in overall networks increased with increasing aggregate sizes, while the average geodesic distance (GD) followed the opposite trend. The LA network could be viewed as a better organized or a better operational soil food web with more functional interrelated members than the SA and IA networks. The modules related to PNA were significantly correlated and clustered together as meta-modules in networks of aggregate fractions. The role-shifts prevailed among the network members such as significant module memberships (MMs) and generalist/specialist operational taxonomic units (OTUs). A half of shared nodes were further identified as shared MMs, dominated by ammonia-oxidizing bacteria (AOB) especially for Nitrosospira cluster 3a and 10. Soil pH could explain partly the shift of module hubs in different networks, while grazing by bacterivores might account for three exclusively connecters related to Nitrososphaera clusters 1.1. The strongly coupled modules correlated positively to pH and total carbon (TC), regardless of aggregate fractions. The network analysis approach provided new insights into potential importance of network interactions between nematodes and ammonia oxidizers in soil nitrogen cycling. 相似文献
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Our 1988 paper, describing the effects of cultivation on microbial biomass and activity in different aggregate size classes, brought together the ‘aggregate hierarchy theory’ and the ‘microbial biomass concept’. This enabled us to identify the relationships between microbial and microhabitat (aggregate) properties and organic matter distribution and explain some of their responses to disturbance. By combining biochemical and direct microscopy based quantification of microbial abundance with enzyme activities and process measurements, this study provided evidence for the role of microbial biomass (especially fungi) in macroaggregate dynamics and carbon and nutrient flush following cultivation. In the last ten years environmental genomic techniques have provided much new knowledge on bacterial composition in aggregate size fractions yet detailed information about other microbial groups (e.g. fungi, archaea and protozoa) is lacking.We now know that soil aggregates are dynamic entities – constantly changing with regard to their biological, chemical and physical properties and, in particular, their influences on plant nutrition and health. As a consequence, elucidation of the many mechanisms regulating soil C and nutrient dynamics demands a better understanding of the role of specific members of microbial communities and their metabolic capabilities as well as their location within the soil matrix (e.g. aggregates, pore spaces) and their reciprocal relationship with plant roots. In addition, the impacts of environment and soil type needs to be quantified at the microscale using, wherever possible, non-destructive ‘in situ’ techniques to predict and quantify the impacts of anthropogenic activities on soil microbial diversity and ecosystem level functions. 相似文献