水稻灌浆期籽粒中3个与淀粉合成有关的酶活性变化

在水培和盆栽条件下 ,研究了 6个水稻品种 (含籼 /粳杂交组合、新株型品系 )灌浆期强、弱势粒中 ADPG焦磷酸酶 (EC 2 .7.7.2 1)、淀粉合成酶 (EC 2 .4 .1.2 1)和淀粉分枝酶或 Q-酶 (EC 2 .4 .1.18)的活性变化及其与灌浆充实的关系。 3个酶的活性变化与籽粒灌浆动态相关联 :淀粉酶最高活性出现的时间稍前或同步于最大灌浆速率的时间 ;ADPG焦磷酸酶活性峰值的时间在籽粒达最大重量前的 3～ 6 d;Q-酶最高活性在籽粒重量接近最大时出现。灌浆期各个酶活性的平均值、最高值以及灌浆前期(花后 3～ 12 d)酶的活性与平均灌浆速率、最大灌浆速率、粒重及谷粒充实率均呈显著或极显著的正相关 ,尤以 Q-酶的相关值最大。籼 /粳杂交稻组合籽粒中酶的活性的高低与其亲本有关。在抽穗期通过剪叶、疏花或施用氮素等调节灌浆初期的源库关系或植株体内的营养水平 ,能增加或降低籽粒中特别是弱势粒中酶的活性。这些结果表明 :上述 3个酶尤其是 Q-酶对籽粒灌浆起着重要的调控作用 ;在育种上注意选择籽粒中酶活性高的亲本 ,可望培育出籽粒充实好的品种或杂种后代 ;通过栽培等措施提高灌浆前期籽粒中酶的活性 ,可提高结实率和粒重。

红香芋试管球茎膨大过程中主要碳水化合物含量以及淀粉合成相关酶活性的动态研究

为了探讨芋(Colocasia esculenta(L.)Schott)试管球茎膨大期间糖类物质积累特点,以红香芋无菌试管苗为材料,研究了高浓度蔗糖诱导条件下,红香芋试管球茎形成及膨大过程中主要碳水化合物的变化规律,以及与相关酶活性的关系。结果表明:(1)在红香芋试管球茎膨大过程中,果糖、葡萄糖和总可溶性糖含量均呈先升高后降低的变化趋势,果糖含量在诱导至第27天时达到最大值,而总可溶性糖和葡萄糖含量均在第34天达到峰值;蔗糖含量呈现先上升、后下降、再上升的变化趋势,在培养第48天时积累量达到最大值。(2)红香芋试管球茎总淀粉含量、直链和支链淀粉含量均随培养时间的延长而增加,至膨大后期总淀粉含量达到最大值,淀粉总含量约占干重的76%,并以支链淀粉含量为主。(3)解剖学观察发现,随着试管球茎的形成与膨大,贮藏组织中淀粉粒密度不断增大,至球茎膨大后期,淀粉粒布满薄壁细胞,并且处于比较稳定的水平。(4)诱导培养至第41天时,试管球茎的ADPG焦磷酸化酶和Q-酶活性均达到最大值,分别为1.22和2.39μmol·g^(-1)·min^(-1)。相关性分析发现,从茎基部开始膨大(20d)至ADPG焦磷酸化酶和Q-酶活性达峰值(41d)时,ADPG焦磷酸化酶活性与总淀粉含量、Q-酶活性与支链淀粉含量的相关系数分别为0.819和0.738,二者均呈极显著正相关。研究认为,淀粉的积累以及可溶性糖类含量的变化与红香芋试管球茎的膨大发育密切相关,并受到相关酶的调控。

莲藕膨大过程中淀粉合成相关酶的活性变化及其与淀粉积累的关系

【目的】研究莲藕根状茎膨大过程中淀粉合成相关酶的活性,探讨其与莲藕淀粉积累的关系。【方法】以4个莲藕主栽品种为试材,采用比色法,分析了根状茎膨大过程中葡萄糖、果糖、蔗糖、可溶性总糖、淀粉含量及腺苷二磷酸葡萄糖焦磷酸化酶(ADPGPase)、淀粉合成酶(SSase)和淀粉分支酶(Q-酶)活性的变化。【结果】果糖、葡萄糖和可溶性总糖、蔗糖的含量高峰分别出现在莲藕根茎的膨大前期、中期、后期。总淀粉、直链淀粉、支链淀粉含量在膨大中期前上升缓慢,到后期含量急增,总淀粉含量可达鲜重的11.1%～12.7%,其中支链淀粉始终约占总淀粉的70%。ADPGPase和SSase在各相同膨大时期品种间差异明显,而Q-酶差异较小;3种酶表达上存在明显的时段特征,SSase表达最早,膨大前期即达峰值,ADPGPase和Q-酶活性的表达则相对较迟,均在中期达最大值;ADPGPase和SSase的活性峰值与后期总淀粉含量呈极显著和显著正相关,相关系数分别为0.9830(P<0.01;n=12)和0.8458(P<0.05;n=12);Q-酶活性峰值与后期支链淀粉含量呈显著正相关,相关系数为0.7690(P<0.05;n=12)。【结论】ADPG焦磷酸化酶和淀粉合成酶活性对成熟期莲藕根茎的总淀粉含量起关键调控作用;淀粉分支酶则调控根茎支链淀粉的含量。

Screening and functional evaluation of the glucose-lowering active compounds of total saponins of Baibiandou(Lablab Semen Album)

Objective To screen forα-glucosidase inhibitor active compounds in the total saponins of Baibiandou(Lablab Semen Album)based on UHPLC-Q-Exactive Orbitrap MS technology and to evaluate its hypoglycemic activity in vivo.Methods Acarbose was used as the positive control,and the median inhibitory concentration(IC50)was used as the evaluation index ofα-glucosidase inhibitory activity to establish an in vitroα-glucosidase inhibition model.Further,UHPLC-Q-Exactive Orbitrap MS technology was used to screen and identify the active compounds ofα-glucosidase inhibitors in the total saponins of Baibiandou(Lablab Semen Album)in order to further verify the activity of the main active monomer and to perform homologous modeling and molecular docking of yeast-derivedα-glucosidase and human-derivedα-glucosidase,while the hypoglycemic activity was evaluated in diabetic mice.Results This study successfully identified 15 compounds with potentialα-glucosidase inhibitory activity,including Chikusetsusaponin IVa,from the total saponins of Baibiandou(Lablab Semen Album).Simultaneously,we verified the activity of the main active monomer Chikusetsusaponin IVa,and showed that it has strongα-glucosidase inhibitory activity.Theα-glucosidase inhibitory concentration IC50 was(565.2±1.026)μg/m L,and the IC50 of acarbose,which was lower than the positive control,was(706.6±1.058)μg/m L.The docking energies of Chikusetsusaponin IVa were–6.1 and–7.7 kcal/mol with yeast-derivedα-glucosidase and human-derivedα-glucosidase molecules,respectively.Both showed strong binding activity,and the levels of alanine aminotransaminase(ALT),aspartate aminotransaminase(AST),UREA,Creatinine(CREA),and cholesterol(CHO)were significantly decreased by Chikusetsusaponin IVa(P<0.05).In addition,it could repair damaged liver and pancreas cells of diabetic mice to some extent.Conclusion This study provides a basis for screeningα-glucosidase inhibitors and structural modifications of the total saponins of Baibiandou(Lablab Semen Album).