低温和GA_3对凤丹种子萌发及碳氮代谢物和内源激素含量的影响

研究了低温（4℃）和300 mg·L-1GA3对凤丹（Paeonia suffruticosa‘Fengdan’）种子萌发过程中子叶、上胚轴和叶原基形态及种胚中碳氮代谢物（包括淀粉、可溶性糖和可溶性蛋白质）和内源激素（包括ZR、IAA、ABA和GA）含量的影响。结果表明：GA3处理后第11天凤丹种子上胚轴萌发,且形态细长;经低温处理后第27天上胚轴萌发,且形态较粗壮。低温处理后种子萌发的幼苗叶片较大、株高居中、根系发育较好、须根多且长,生长状况总体上优于对照和GA3处理组。与处理后第3天相比,对照和低温处理后第27天以及GA3处理后第11天,种胚中淀粉、可溶性糖、ZR、IAA和GA含量升高,ABA含量降低;而对照和低温处理后第27天种胚中可溶性蛋白质含量降低,GA3处理后第11天可溶性蛋白质含量无显著变化。各处理组凤丹种子蛋白质电泳条带的相对分子质量多集中在12 000~80 000,在对照和低温处理后第27天蛋白质条带颜色均较处理后第11天略深,但条带数量不变。研究结果显示：低温及GA3处理均可导致凤丹种胚中碳氮代谢物和内源激素含量变化,促进种胚发育及上胚轴生长,但低温处理更有利于上胚轴萌发及幼苗生长。

环剥、环割对薄壳山核桃新梢生长和叶片碳氮代谢物积累影响

为研究环剥和环割这2种修剪措施对薄壳山核桃新梢生长和叶片碳氮代谢物积累的影响,以5年生薄壳山核桃幼树‘波尼’(‘Pawnee’)为试材,对同一规格长度(40~45 cm)新梢进行环剥处理(环剥1 mm、环剥2 mm和环剥3 mm)和环割处理(环割1圈、环割2圈和环割3圈)。不同宽度环剥和不同圈数环割处理对薄壳山核桃的影响不同。环剥和环割处理能抑制新梢伸长生长,促进粗度生长;环剥3 mm处理的叶片可溶性糖含量、淀粉含量、蛋白质含量和C/N比高于其他处理和对照,但与环剥2 mm无显著性差异;环割3圈处理的叶片可溶性糖含量、淀粉含量、蛋白质含量和C/N最高。综合考虑修剪措施可能对树体的影响,环剥2 mm或环割3圈为生产上新梢的适宜修剪方式。

不同修剪措施对薄壳山核桃枝条生长及枝条和叶片碳氮代谢物积累的影响

以薄壳山核桃品种‘马罕’（Caryaillinoensis‘Mahan’）的5年生嫁接苗为实验材料,研究枝条短截（1/4、1/3和1/2短截）以及枝条和主干的环剥和环割对其枝条生长及枝条和叶片中碳氮代谢物积累的影响。结果显示：经不同程度短截处理后,枝条萌芽率均显著高于对照（未经任何修剪）,新枝的数量、长度和直径也均不同程度高于对照,而比叶质量及叶绿素含量总体上与对照无显著差异；经1/2和1/3短截处理后,长度0-10cm和30cm以上的新枝比例明显提高；枝条和叶片中可溶性糖含量和C/N比均高于对照、全N含量均低于对照,枝条中淀粉含量低于对照而叶片中淀粉含量高于对照。经枝条环剥和环割处理后,枝条萌芽率和比叶质量均高于对照但无显著差异,枝条平均长度增长量和叶绿素含量均显著低于对照、枝条平均直径增长量均显著高于对照；枝条和叶片中可溶性糖和淀粉含量以及C/N比均高于对照,全N含量均低于对照。经主干环剥和环割处理后,枝条的萌芽率和平均直径增长量以及比叶质量均显著高于对照,枝条平均长度增长量和叶绿素含量均显著低于对照；枝条和叶片中可溶性糖和淀粉含量以及C/N比均高于对照,枝条中全N含量高于对照而叶片中全N含量则低于对照。此外,品种‘马罕’的结果枝长度为0-30cm,其中长度0-10cm的结果枝数量最多。研究结果表明：不同短截措施均能提高薄壳山核桃的萌芽率、促进新枝伸长和增粗；而枝条和主干的环剥和环割处理对枝条萌芽率无明显促进作用,但有利于枝条增粗；不同修剪措施总体上有利于其叶片及枝条中碳水化合物的合成和积累。总体上,1/3短截及枝条和主干的适度环剥可促进品种‘马罕’结果枝的形成。

不同施氮浓度对无芒雀麦和白三叶氮代谢物积累的影响

以无芒雀麦(Bromus inermis)和白三叶(Trifolium repens)为对象,研究了不同施氮浓度0、6、12、24g/(m2·a),对2种牧草的氮代谢物质积累的影响,结果表明,2种牧草的叶绿素、叶氮、可溶性蛋白、精氨酸和脯氨酸含量等氮代谢物指标均随氮处理浓度的增加出现显著增加(P<0.05)。除可溶性蛋白以外的各项指标在24g/(m2·a)处理时达到峰值。其中,白三叶和无芒雀麦叶绿素含量分别比对照增加了20.0%、122.9%,叶氮含量分别比对照增加了153.7%、76.5%,精氨酸含量分别比对照增加了142.5%、301.6%。说明不同施氮浓度对无芒雀麦和白三叶的氮代谢物积累有明显的促进作用,而且对无芒雀麦的促进作用比白三叶更明显。

植物生长调节剂对薄壳山核桃品种‘波尼’枝条生长和叶片碳氮代谢物积累的影响

以5年生薄壳山核桃品种‘波尼’(Carya illinoinensis‘Pawnee’)幼树为实验材料,根据L_9(3~3)正交试验设计进行3因子(包括植物生长调节剂的种类、质量浓度和喷施次数)3水平(植物生长调节剂分别为GA_3、PP_(333)和6-BA,植物生长调节剂质量浓度分别为100、200和300 mg·L^(-1),植物生长调节剂喷施次数分别为1、2和3)叶面喷施实验,研究不同处理对薄壳山核桃品种‘波尼’枝条生长和叶片碳氮代谢物积累的影响。结果表明:GA_3处理组薄壳山核桃品种‘波尼’枝条长度较CK(对照,蒸馏水喷施3次)组显著增加,其中,T2(200 mg·L^(-1)GA_3喷施2次)处理组的枝条长度最大,较CK组增加了35.7%;PP_(333)处理组的枝条粗度总体上较CK组显著增加,其中,T5(200mg·L^(-1)PP_(333)喷施1次)处理组的枝条粗度最大,较CK组增加了23.8%。处理后30~90 d,所有处理组薄壳山核桃品种‘波尼’枝条叶片中可溶性糖含量均呈逐渐升高的变化趋势,而叶片中淀粉和可溶性蛋白质含量以及C/N比总体上呈先升高后降低的变化趋势。PP_(333)和6-BA处理组叶片中可溶性糖、淀粉和可溶性蛋白质含量以及C/N比总体上显著高于CK组,其中,T5和T6(300 mg·L^(-1)PP_(333)喷施2次)处理组对叶片中可溶性糖和淀粉含量以及C/N比的促进效果较佳,而T4(100 mg·L^(-1)PP_(333)喷施3次)和T8(200 mg·L^(-1)6-BA喷施3次)处理组对叶片中可溶性蛋白质含量的促进效果较佳。极差分析结果表明:植物生长调节剂种类对薄壳山核桃品种‘波尼’枝条长度、叶片中可溶性糖和淀粉含量以及叶片C/N比的影响最大,植物生长调节剂喷施次数对枝条粗度和叶片中可溶性蛋白质含量的影响最大。研究结果显示:叶面喷施200 mg·L^(-1)GA_3对薄壳山核桃品种‘波尼’枝条伸长的促进效果最佳,喷施200 mg·L^(-1)PP_(333)对枝条增粗及叶片碳氮代谢物积累的促进效果最佳。

酿酒酵母氮代谢物阻遏效应及其对发酵食品安全的影响

综述了国内外发酵食品中氨(胺)类代谢物的研究进展,包括氨基甲酸乙酯的5种形成机制、生物胺和亚硝酸胺的形成机制,阐述了上述生物危害物形成的本质原因——发酵微生物的氮代谢阻遏效应;重点介绍了酿酒酵母胞内5大调控因子(Gln3p、Ure2p、Gat1p、Dal80p和Gzf3p)对其氮源利用的全局调控作用.并以精氨酸和尿素代谢为例,详细介绍了氮代谢阻遏效应的作用机理.酿酒酵母氮代谢物阻遏效应的研究结果,可为解决由于相关含氮有害代谢物积累导致的普遍存在于发酵中的食品安全问题提供理论依据和技术支撑.

氮高效利用水稻碳氮代谢物含量的变化特征

采用土培盆栽试验,研究氮高效利用水稻在不同供氮水平下碳氮代谢物含量的变化情况,并探讨其与氮素利用效率之间的关系。结果表明,氮高效利用水稻碳氮代谢物谷氨酸(Glu)、谷氨酰胺(Gln)、α-酮戊二酸(2-OG)和蔗糖的含量随生育进程的变化态势与氮低效利用水稻大致相同,但其含量的高低因品种、施氮量不同而异。Glu对氮的响应基本为随施氮量增加而增加。Gln在抽穗期、开花期和2-OG在抽穗期、开花期、成熟期对氮响应呈现先降后升再降的"S"型曲线变化规律;蔗糖在抽穗期随施氮量的增加而减少,而在成熟期表现为增加。抽穗期Gln与Glu呈极显著正相关;氮利用效率(NUE)与开花期的Gln呈显著负相关,与Glu呈显著正相关,与成熟期2-OG呈极显著负相关。施氮量和不同氮利用效率水稻对碳氮代谢物含量有影响,氮高效利用水稻在低氮条件下具有较高的Glu、2-OG和蔗糖含量;抽穗期不同供氮处理Gln含量均明显较高。

环割和摘心对薄壳山核桃枝条生长和叶片碳氮代谢物积累的影响

【目的】探索薄壳山核桃(Carya illinoensis)合理高效的修剪措施,提高薄壳山核桃结果枝的比例,为建立丰产优质的修剪技术体系提供理论依据。【方法】以5年生薄壳山核桃品种‘波尼’(‘Pawnee’)的幼树新梢为试验材料,研究环割和摘心处理对不同规格(以枝条长度进行划分)生长期枝条的生长和叶片中碳氮代谢物积累的影响。【结果】规格A(20~25 cm)、规格B(30~35 cm)和规格C(40~45 cm)枝条经环割处理后长度均低于对照,粗度和叶片碳氮代谢物含量均高于对照;其中规格A枝条长度低于对照22.09%,规格C枝条的粗度与对照的差异最大;可溶性糖含量一直呈上升趋势,而淀粉和可溶性蛋白含量均呈先上升后下降的趋势。规格A、B和C枝条摘心处理后长度均低于对照,粗度和叶片碳氮代谢物含量均高于对照;其中规格A枝条长度低于对照15.05%,规格B和C粗度与对照差异显著;叶片碳氮代谢物含量出现不同的变化趋势,其中规格B枝条碳氮代谢物含量与对照存在显著差异;规格C枝条平均萌发两条新枝,最大长度达26.75 cm,最大粗度达8.86 mm。【结论】环割和摘心处理均能抑制‘波尼’枝条长度生长并促进粗度生长,但在不同规格间的效果有差异;摘心对规格C枝条萌发新枝的促进效果最好。

土壤缺钾对冬小麦碳氮代谢的影响

为探明土壤缺钾对冬小麦产量、品质影响机理,以冬小麦耐低钾型品种科农9204和敏感型品种石新828为材料,采用盆栽试验方法,在土壤缺钾和正常供钾条件下,对冬小麦开花后6个时期(0 d、7 d、14 d、21 d、28 d和35 d)旗叶和籽粒钾含量,旗叶叶绿素含量、碳代谢物含量、蔗糖合成酶活性、蔗糖磷酸合成酶活性,籽粒氮代谢物含量、硝酸还原酶活性进行了测定和分析。结果表明,与正常供钾相比,土壤缺钾处理下耐低钾型冬小麦旗叶、籽粒钾、碳代谢物和氮代谢物含量虽有下降,但整体上变化不显著。土壤缺钾下敏感型冬小麦旗叶和籽粒钾含量总体上较正常供钾处理显著下降,降幅分别为5.01%~65.37%、4.74%~31.83%;旗叶叶绿素、碳含量分别降低5.27%~80.66%、3.29%~10.85%,且差异均显著;旗叶可溶性总糖、蔗糖、葡萄糖、果糖含量总体上呈显著增加趋势,增幅分别为14.37%~119.08%、16.63%~68.00%、16.63%~68.00%、23.41%~80.37%;蔗糖合成酶和蔗糖磷酸合成酶活性分别下降32.28%~538.67%、48.51%~421.48%。土壤缺钾导致敏感型冬小麦籽粒氮、粗蛋白质、清蛋白、醇溶蛋白、麦谷蛋白含量和硝酸还原酶活性均显著减少,降幅分别为29.87%~90.33%、15.56%~66.12%、3.73%~26.02%、17.92%~38.81%、6.33%~35.81%和13.89%~33.89%,使球蛋白含量提高2.57%~64.15%,而对耐低钾型冬小麦的籽粒蛋白组分含量和硝酸还原酶活性总体上影响不显著。综上,土壤缺钾导致冬小麦光合作用减弱和光合同化产物减少,抑制了蔗糖酶和硝酸还原酶活性,造成旗叶糖分累积和碳含量及籽粒氮、粗蛋白质含量降低,引起蛋白质组分发生变化,导致碳氮代谢失衡。

宫颈一氧化氮浓度与宫颈Bishop评分、宫颈管长度的相关性

目的:研究在妊娠妇女中前列腺素E2作用于宫颈引起一氧化氮的释放的效应,并分析了一氧化氮代谢产物、宫颈管长度和宫颈Bishop评分3者之间的关系。方法:选取了77例孕周≥37周的妊娠妇女,分别在使用前列腺素E2的前后检测宫颈分泌物中一氧化氮的浓度、进行宫颈Bishop评分、以及测量宫颈管的长度。结果:研究对象的平均年龄为(34±3.2)岁,平均孕龄为(284±9.2)d,其中初产妇占31.2%。在T0时间段,宫颈评分<4分的占74%(57/77),平均宫颈管长度为(28.6±5.8)mm,平均NOx的浓度为(208.6±103.8)μm/mL;而12 h后,在T12时间段,平均宫颈管长度减少到(19.5±8.8)mm,平均NOx的浓度增加到(316.7±240.9)μm/mL。而产次和需诱发宫缩的原因对数据没有影响。统计资料表明:宫颈一氧化氮代谢产物浓度的改变和宫颈Bishop评分的改善之间在统计学上呈显著的正相关P<0.01;r=0.494,一氧化氮代谢产物浓度的改变和宫颈管长度的缩短之间亦呈显著的正相关P<0.01;r=0.307。结论:前列腺素引起宫颈成熟的过程与宫颈局部一氧化氮的释放有相关性,故推测一氧化氮在宫颈组织重组的过程中起着重要作用。

血清NOx、ADM、ADPN联合检测对急性缺血性脑卒中病人脑血管事件再发的预测价值

目的探讨急性缺血性脑卒中病人血清一氧化氮代谢物(NOx)、肾上腺髓质素(ADM)、脂联素(ADPN)变化及联合检测对脑血管事件再发的预测价值。方法选取2015年1月—2017年12月我院住院的107例急性缺血性脑卒中病人,所有病人均进行美国国立卫生研究院卒中量表(NIHSS)评定,检测第1天、第3天及第7天血清NOx(比色法),采用酶联免疫吸附法检测ADM和ADNP;同时选取107名健康体检者作为健康对照组。比较脑卒中病人与正常对照组血清NOx、ADM和ADNP水平差异。将脑卒中病人根据NIHSS评分分组,比较不同NIHSS评分病人第1天、第3天及第7天血清NOx、ADM和ADNP水平变化。调查病人一般资料,随访脑血管意外事件再发生情况,采用Logistic多因素分析缺血性脑卒中的独立危险因素,建立各指标拟合诊断模型,绘制ROC曲线,评价各指标预测脑血管意外事件再发的AUC值。结果与正常对照组比较,脑卒中病人第1天、第3天血清NOx水平降低(t值分别为6.698,4.562,P<0.05),第1天血清ADM水平升高(t=4.021,P<0.05),第1天、第3天血清ADPN水平降低(t值分别为8.654,6.547,P<0.05)。NIHSS评分≥3分脑卒中病人第1天、第3天血清NOx和ADPN水平低于NIHSS评分<3分病人(t值分别为3.914,3.476,4.658,4.012,P<0.05);NIHSS评分≥3分脑卒中病人第1天血清ADM高于NIHSS评分<3分病人(t=3.525,P<0.05)。模型Logit(P)=0.212+0.632×NIHSS评分-0.212×第1天NOx+0.062×第1天ADM-0.314×第1天ADPN诊断脑血管事件再发的灵敏度为88.23%,特异度为94.12%,ROC曲线下面积为0.851,明显高于第1天NOx(0.723)、第1天ADM(0.702)、第1天ADPN(0.765)各个指标单独检测(Z值分别为6.219,8.267,5.216,P<0.05)。结论急性缺血性脑卒中病人血清NOx、ADM、ADPN明显变化,其联合检测对脑血管再发具有较高的预测价值。

单核细胞影响NK细胞抗K562细胞活性的实验研究

目的探讨单核细胞(MO)呼吸爆发过程中产生的反应性氮代谢物(RNM)、反应性氧代谢物(ROM)的情况及其对NK细胞抗K562细胞活性的影响。方法在NK+K562混合细胞培养体系中,观察加入MO或/和IL-2/PHA前后RNM、ROM产量、KIR及TNF-β、IFN-γ产量的相应变化。再观察加入二氢氯组胺、硫普罗宁后上述各指标的变化情况。结果①在NK+K562混合培养体系中,加入IL-2/PHA后,KIR逐渐升高;当按E/MO=10/2、10/5、10/10比例加入MO后,RNM、ROM产量随着MO数量的增加而增加,而TNF-β、IFN-γ的产量和KIR反而降低。对K562细胞数量作偏相关分析,RNM与KIR的负相关系数大于ROM。②加入药物后,ROM产量明显下降,KIR和TNF-β、IFN-γ产量明显升高,硫普罗宁还降低RNM的产量,但二氢氯组胺无效。结论①MO可通过产生ROM、RNM降低NK细胞的活性,抑制NK细胞抗K562细胞效应;②RNM对NK细胞的影响可能比ROM更强。③硫普罗宁通过清除ROM、RNM,可逆转MO对NK细胞的抑制作用。

Effect of Nitrogen on the Degradation of Cypermethrin and Its Metabolite 3-Phenoxybenzoic Acid in Soil

Increasing use of pyrethroid insecticides has resulted in concerns regarding potential effects on human health and ecosystems. Cypermethrin and its metabolite 3-phenoxybenzoic acid(PBA) have exerted adverse biological impacts on the environment;therefore,it is critically important to develop different methods to enhance their degradation. In this study,incubation experiments were conducted using samples of an Aquic Inceptisol supplied with nitrogen(N) in the form of NH4NO3 at different levels to investigate the effect of nitrogen on the degradation of cypermethrin and PBA in soil. The results indicated that appropriate N application can promote the degradation of cypermethrin and PBA in soil. The maximum degradation rates were 80.0% for cypermethrin after 14 days of incubation in the treatment with N at a rate of 122.1 kg ha-1 and 41.0% for PBA after 60 days of incubation in the treatment with N at a rate of 182.7 kg ha-1. The corresponding rates in the treatments without nitrogen were 62.7% for cypermethrin and 27.8% for PBA. However,oversupplying N significantly reduced degradation of these compounds. Enhancement of degradation could be explained by the stimulation of microbial activity after the addition of N. In particular,dehydrogenase activities in the soil generally increased with the addition of N,except in the soil where N was applied at the highest level. The lower degradation rate measured in the treatment with an oversupply of N may be attributed to the microbial metabolism shifts induced by high N.

Nitrogen Sources Affect Streptolydigin Production and Related Secondary Metabolites Distribution of Streptomyces lydicus AS 4.2501

The effects of nitrogen sources on streptolydigin production and distribution of secondary metabolites were investigated for flask cultured S.lydicus AS 4.2501.When peptone,asparamide,and glutamic acid were ex- amined as the nitrogen source,respectively,liquid chromatography-mass spectrometry(LC-MS)and photodiode array(PDA)analyses revealed the formation of two analogues of streptolydigin in the fermentation broth.When soybean meal was used as the source of nitrogen,three analogues of streptolydigin were detected.The use of am- monium sulfate as a source of nitrogen resulted in a lower pH value of the fermentation system,thus inhibiting streptolydigin biosynthesis and changing the metabolic profiling.Among the nitrogen sources that were made use of,glutamic acid was most favorable to the formation of streptolydigin.Simultaneously,this study also showed that the changing nitrogen sources resulted in altering the production and relative ratios of streptolydigin and its analogues.

A Functional-Structural Model of Rice Seedling Coupled with Nitrogen Metabolism

With the ability of representing the association and inner-feedback between plant morphological structure and physiological functions, functional-structural plant modeling （FSPM） approach has been used in many works, trying to better understand the mechanisms of integrating plant functions and its structure, and their communication with environmental factors. To do so, an FSPM of rice seedling was developed in this study, including structural morphogenetic model, photosynthetic model and biomass partitioning module. It can thus describe the developmental course of the rice structure dynamically based on the processes of biomass producing and partitioning. Furthermore, the processes of nitrogen metabolism, which influence the N content and growth dynamics of the virtual rice, were also considered. The model was developed with L-system on a platform established with Java programming language, which took over the parsing and visualization of the L-system strings to 3D objects using Java 3D extended library. The physiological processes in the model can be modified and further improved to gradually meet the needs for modeling the whole life cycle of rice, e.g., considering the respiration, and interaction with other environmental factors like CO2, temperature, etc.. The model was developed to provide a platform to systematically study and understand how plant systems like rice seedling work. The model and the virtualization platform can be expanded to provide decision support on N fertilizer application for the rice seedling and the other crops.

Forms of nitrogen uptake,translocation,and transfer via arbuscular mycorrhizal fungi:A review

Arbuscular mycorrhizal （AM） fungi are obligate symbionts that colonize the roots of more than 80% of land plants. Experi- ments on the relationship between the host plant and AM in soil or in sterile root-organ culture have provided clear evidence that the extraradical mycelia of AM fungi uptake various forms of nitrogen （N） and transport the assimilated N to the roots of the host plant. However, the uptake mechanisms of various forms of N and its translocation and transfer from the fungus to the host are virtually unknown. Therefore, there is a dearth of integrated models describing the movement of N through the AM fungal hyphae. Recent studies examined Ri T-DNA-transformed carrot roots colonized with AM fungi in ~SN tracer experi- ments. In these experiments, the activities of key enzymes were determined, and expressions of genes related to N assimilation and translocation pathways were quantified. This review summarizes and discusses the results of recent research on the forms of N uptake, transport, degradation, and transfer to the roots of the host plant and the underlying mechanisms, as well as re- search on the forms of N and carbon used by germinating spores and their effects on amino acid metabolism. Finally, a path- way model summarizing the entire mechanism of N metabolism in AM fungi is outlined.