Sugar for my honey: carbohydrate partitioning in ectomycorrhizal symbiosis

Simple, readily utilizable carbohydrates, necessary for growth and maintenance of large numbers of microbes are rare in forest soils. Among other types of mutualistic interactions, the formation of ectomycorrhizas, a symbiosis between tree roots and certain soil fungi, is a way to overcome nutrient and carbohydrate limitations typical for many forest ecosystems. Ectomycorrhiza formation is typical for trees in boreal and temperate forests of the northern hemisphere and alpine regions world-wide. The main function of this symbiosis is the exchange of fungus-derived nutrients for plant-derived carbohydrates, enabling the colonization of mineral nutrient-poor environments. In ectomycorrhizal symbiosis up to 1/3 of plant photoassimilates could be transferred toward the fungal partner. The creation of such a strong sink is directly related to the efficiency of fungal hexose uptake at the plant/fungus interface, a modulated fungal carbohydrate metabolism in the ectomycorrhiza, and the export of carbohydrates towards soil growing hyphae. However, not only the fungus but also the plant partner increase its expression of hexose importer genes at the plant/fungus interface. This increase in hexose uptake capacity of plant roots in combination with an increase in photosynthesis may explain how the plant deals with the growing fungal carbohydrate demand in symbiosis and how it can restrict this loss of carbohydrates under certain conditions to avoid fungal parasitism.     

红冬孢酵母苯丙氨酸解氨酶基因pal在大肠杆菌中的克隆与表达

以红冬孢酵母总RNA为模板反转录获得其苯丙氨酸解氨酶基因pal,测序与已公布蛋白序列进行比对,相似度为99％.并以含有T7强启动子的pET - 28a(+)为载体构建重组质粒pET - 28a(+)- pal,通过异丙基硫代-β-D-半乳糖苷(IPTG)诱导实现苯丙氨酸解氨酶(PAL)在大肠杆菌中的表达.对诱导条件进行初步优化后,重组茵PAL比酶活可达到42.99 U/g.转化实验中肉桂酸的转化率为48.52％,L-苯丙氨酸生成量为1.73 g/L.结果表明,红冬孢酵母pal基因通过表达载体pET - 28a(+)在E.coli中获得了高效表达.     

Interplay between metal binding and cis/trans isomerization in legume lectins: structural and thermodynamic study of P. angolensis lectin

The interplay between metal binding, carbohydrate binding activity, stability and structure of the lectin from Pterocarpus angolensis was investigated. Removal of the metals leads to a more flexible form of the protein with significantly less conformational stability. Crystal structures of this metal-free form show significant structural rearrangements, although some structural features that allow the binding of sugars are retained. We propose that substitution of an asparagine residue at the start of the C-terminal beta-strand of the legume lectin monomer hinders the trans-isomerization of the cis-peptide bond upon demetallization and constitutes an intramolecular switch governing the isomer state of the non-proline bond and ultimately the lectin phenotype.     

NO对金丝桃悬浮细胞生长及金丝桃素生物合成的促进作用研究

一氧化氮 (NO)是近年来发现的一种新型植物信号分子。以硝普钠 (Sodiumnitroprusside ,SNP)为一氧化氮 (NO)的供体 ,研究外源NO对金丝桃悬浮细胞生长及金丝桃素生物合成的影响。试验结果表明 ,金丝桃悬浮细胞在含 0 5和 15 0mmol LSNP的培养基中培养 2 0d后 ,细胞的干重分别为对照组的 140%和50% ;细胞中金丝桃素的含量分别为对照组的 98%和210%。试验结果表明 ,低浓度SNP处理有利于金丝桃悬浮细胞生长 ,而高浓度SNP可以促进金丝桃素的合成。在细胞培养初期 (0d)加入 0.5mmol LSNP并在指数生长后期 (14d)加入15.0mmol LSNP的金丝桃悬浮细胞在培养 2.5d后 ,细胞的干重和金丝桃素的含量分别为对照组的1.4和1.8倍 ,金丝桃素的产量达15.2mg/L ,比对照高3.2倍。SNP对金丝桃悬浮细胞生长及金丝桃素含量的影响可以被NO专一性淬灭剂CPITO(2-4-carboxyphenyl-4 ,4 ,5 ,5-tetramethylimidazoline-1-oxyl-3-oxide)所抑制,说明SNP是通过其分解产物NO影响细胞生长和金丝桃素的合成。试验结果同时表明,在15.0mmol/L的SNP处理下,金丝桃悬浮细胞中的苯丙氨酸解氨酶(PAL)的活性显著升高,推测NO可能通过触发金丝桃悬浮细胞的防卫反应,激活了细胞中金丝桃素的生物合成途径。     

The effect of size and acetylation degree of chitosan derivatives on tobacco plant protection against Phytophthora parasitica nicotianae

Enzymatic degradation of chitosan polymer with Pectinex Ultra SPL was used to obtain derivatives with biological potential as protective agents against Phytophthora parasitica nicotianae (Ppn) in tobacco plants. The 24 h hydrolysate showed the highest Ppn antipathogenic activity and the chitosan native polymer the lowest. The in vitro growth inhibition of several Phytophthora parasitica strains by two chitosans of different DA was compared. While less acetylated chitosan (DA 1%) fully inhibited three P. parasitica strains at the doses 500 and 1000 mg/l the second polymer (DA 36.5%) never completely inhibited such strains. When comparing two polymers of similar molecular weight and different DA, again the highest antipathogenic activity was for the less acetylated polymer. However, degraded chitosan always showed the highest pathogen growth inhibition. Additionally, a bioassay in tobacco seedlings to test plant protection against Ppn by foliar application demonstrated that partially acetylated chitosan and its hydrolysate induced systemic resistance and higher levels of glucanase activity than less acetylated chitosan. Similarly, when treatments were applied as seeds coating before planting, about 46% of plant protection was obtained using chitosan hydrolysate. It was concluded that, while less acetylated and degraded chitosan are better for direct inhibition of pathogen growth, partially acetylated and degraded chitosan are suitable to protect tobacco against P. parasitica by systemic induction of plant resistance.     

1‐Aminobenzocyclobutene‐1‐phosphonic Acid and Related Compounds as Inhibitors of Phenylalanine Ammonia‐Lyase

Five new geminal aminocycloalkanephosphonic acids ( 4 – 8 ) containing both an aromatic ring and a cycloalkane ring were synthesized and evaluated as potential inhibitors of buckwheat phenylalanine ammonia‐lyase (PAL). Within the set of compounds which are related to 2‐aminoindane‐2‐phosphonic acid (AIP, 3 ), a known powerful inhibitor of PAL, racemic 1‐aminobenzocyclobutene‐1‐phosphonic acid ( 4 ), was six times weaker than AIP as an in vitro inhibitor of buckwheat PAL, but six times stronger than AIP as an in vivo inhibitor of phenylalanine‐derived anthocyanin synthesis in buckwheat.     

p-香豆酸对西洋参的化感作用及生理机制

西洋参(Panax quinquefolium L.)栽培中存在严重的连作障碍现象,前期发现p-香豆酸在以滤纸片为基质的条件下,能够显著抑制西洋参胚根的生长。为了明确p-香豆酸在土壤基质中对种胚的化感活性以及对成株西洋参生长的作用及生理机制,以自然土壤为基质,观察p-香豆酸作用后种胚的生长情况;采用室内水培试验,观察p-香豆酸作用下2年生西洋参种根从出苗至结果期的生长及部分生理指标的变化。种胚生长实验在土壤中分别添加0.0024、0.012、0.06、0.3、1.5、7.5 mg/g的p-香豆酸,处理7 d后测定西洋参种胚的胚根长和胚芽长。水培试验中全营养液中分别添加0.012 mg/mL、0.06 mg/mL、0.3 mg/mL p-香豆酸,处理后每隔5 d测定植株叶片展开情况、株高、冠幅等生长指标;于展叶期(10 d)、现蕾期(20 d)、结果期(30 d)测定地上部分及新生须根的生物量,同时测定新生须根苯丙氨酸解氨酶(PAL)活力;叶片完全展开后测定植株净光合速率(Pn)、表观电子传递速率(ETR)和最大光化学效率(Fv/Fm)等光合特性参数。结果表明,土壤中添加0.0024-7.5 mg/g p-香豆酸西洋参胚根长度降低28.52%-100%,胚芽长度降低1.09%-100%,并呈现一定的剂量抑制效应。实验浓度内的p-香豆酸可显著抑制西洋参植株地上部分生长,推迟展叶期;结果期地上部生物量比对照降低17.17%-54.55%(P < 0.05,Dunnett-t test);同时,叶片的Pn、ETR受到抑制(P < 0.05),但Fv/Fm不变;对须根的影响主要表现为0.06 mg/mL p-香豆酸处理组在展叶期PAL酶活力提高69.05%,之后PAL活力和生物量均比对照下降,浓度增加至0.3 mg/mL时整个培养期内PAL酶活力和生物量均低于对照。由此推论,根系环境中的p-香豆酸在自然土壤中对西洋参种胚具有显著抑制其生长的化感作用;对成株西洋参的作用主要为抑制地上部分生长,并通过降低成株西洋参叶片光合能力,从而表现出明显的化感作用,0.06 mg/mL p-香豆酸诱导须根PAL酶活力先升高再降低并最终降低生物量的结果也表明p-香豆酸是西洋参根系生长的胁迫因素。结果证实p-香豆酸对西洋参种胚和成株的生长均具有自毒作用,其抑制生长的生理机制在于抑制叶片的光合作用。