Biological nitrogen fixation by soybean (Glycine max [L.] Merr.), a novel, high protein crop in Scotland, requires inoculation with non-native bradyrhizobia
M. Maluk, M. Giles, G. Wardell, Aminin Taqrir Akramin, Francesc Ferrando-Molina, Ashley Murdoch, Marta Barros, C. Beukes, M. Vasconcelos, Ellie Harrison, T. Daniell, R. Quilliam, P. Iannetta, E. James
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引用次数: 1
Abstract
It is currently not recommended to grow soybean (Glycine max [L.] Merr.) further than 54° North, but climate change and the development of new high latitude-adapted varieties raises the possibility that it could be introduced into Scotland as a novel high protein crop deriving most of its nitrogen (N) requirements through biological N fixation (BNF). This was evaluated via field trials in 2017 and 2018 near Dundee (56.48°N). As there are no native soybean-nodulating bacteria (SNB) in UK soils, soybean requires inoculation to exploit its BNF potential. In 2017, three commercial inoculants containing elite Bradyrhizobium strains significantly increased plant biomass in plot trials with a soybean 000 maturity group variety (ES Comandor). Rhizobia were isolated from the nodules and identified as the original inoculant species, B. diazoefficiens and B. japonicum. One inoculant (Rizoliq Top) was used for larger-scale trials in 2018 with two varieties (ES Comandor, ES Navigator); inoculation doubled the grain yield to 1 t ha-1 compared to the uninoculated crop. The inoculated soybean obtained most of its N through BNF in both years regardless of plant genotype i.e. >73%Ndfa, with BNF contributions to aerial biomass exceeding 250 kg N ha-1 yr-1 in 2017 and that to grain 50 kg N ha-1 yr-1 in 2018. These data suggest that N-fixing soybean could be grown in Scotland without mineral N-fertiliser, either for forage as animal feed, or as green pods for human consumption (“edamame”), and potentially, even as dry grain. The potential for survival of the Bradyrhizobium inoculant strains in soils was also demonstrated through the detection of the inoculant strain B. diazoefficiens SEMIA 5080 at relatively high populations (104 g-1 dry soil) using a qRT-PCR method with SNB-specific nodZ primers. Microbiome data obtained from soil using 16S rRNA primers demonstrated that the diversity of bacteria belonging to the genus Bradyrhizobium increased in soybean-cropped soils compared to bulk soil regardless of inoculation status. The economic and practical implications of residual inoculum, as well as those arising from introducing a non-native plant and alien bacteria into Scottish soils in terms of their impact on the native soil microbiota are discussed.
目前不建议在北纬54°以上种植大豆(Glycine max[L.]Merr.),但气候变化和适应高纬度的新品种的开发增加了将其作为一种新型高蛋白作物引入苏格兰的可能性,这种作物通过生物固氮(BNF)获得了大部分氮需求。这是通过2017年和2018年在Dundee(56.48°N)附近的田间试验进行的评估。由于英国土壤中没有本地大豆结瘤菌(SNB),大豆需要接种疫苗来开发其BNF潜力。2017年,在大豆000成熟组品种(ES Comando)的小区试验中,三种含有优质慢生根瘤菌菌株的商业接种剂显著增加了植物生物量。从根瘤中分离出根瘤菌,并鉴定为原始接种种,即重氮效率芽孢杆菌和日本血吸虫。2018年,一种接种剂(Rizoliq Top)用于两个品种(ES Comandor、ES Navigator)的大规模试验;与未接种的作物相比,接种使粮食产量翻了一番,达到1Tha-1。无论植物基因型如何,接种后的大豆在这两年都通过BNF获得了大部分氮,即>73%的Ndfa,2017年BNF对地上生物量的贡献超过250 kg N ha-1 yr-1,2018年对粮食的贡献超过50 kg N ha-1yr-1。这些数据表明,在苏格兰,固定氮的大豆可以在没有矿物氮肥的情况下种植,既可以作为动物饲料,也可以作为人类食用的绿色豆荚(“毛豆”),甚至可以作为干谷物。通过使用具有SNB特异性nodZ引物的qRT-PCR方法在相对较高的群体(104g-1干土)中检测接种菌株B.dizoefficiiens SEMIA 5080,也证明了慢生根瘤菌接种菌株在土壤中存活的潜力。使用16S rRNA引物从土壤中获得的微生物组数据表明,与散装土壤相比,无论接种状态如何,大豆种植土壤中属于慢生根瘤菌属的细菌多样性都有所增加。讨论了残留接种物的经济和实际意义,以及将非本土植物和外来细菌引入苏格兰土壤对本土土壤微生物群的影响。