真菌诱导子对悬浮培养西洋参细胞的生理效应

报道了不同真菌诱导子对悬浮培养的西洋参（Ｐａｎａｘｑｕｉｎｑｕｅｆｏｌｉｕｍ）细胞生长、皂甙和多糖合成,以及细胞内和培养液中过氧化物酶活性的生理效应。悬浮培养的西洋参细胞经刺盘孢菌（Ｃｏｌｌｅｔｏｔｒｉｃｈｕｍｎｉｃｏｌｔｉａｎａｅ）丝体诱导子处理后,总皂甙产率可由对照的２９６ｍｇ／Ｌ增加到６７９ｍｇ／Ｌ（约占细胞干重的（１６．３％）,比对照提高约１．３倍,而且总皂甙的８５％排放在培养液中;经黑曲霉（Ａｓｐｅｒｇｉｌｌｕｓｎｉｇｒａｎ）诱导子处理后,细胞多糖含量可达到１１．７９％（细胞干重）,比对照增加１倍多。初步纯化的刺盘孢菌丝体诱导子和尖孢镰刀菌（Ｆｕｓｕｒｉｕｍｏｘｙｓｐｏｒｕｍ）滤液诱导子在诱导处理前期能明显促进西洋参细胞生长,同时细胞内及培养液中过氧化物酶活性显著增加;随时间延长,细胞生长和酶活性逐步受到抑制。     

Dammarane saponins of leaves of Panax pseudo-ginseng subsp. himalaicus

From dried leaves of Panax pseudo-ginseng subsp. himalaicus collected in Eastern Himalaya, new dammarane saponins, named pseudo-ginsenosides-F₁₁ and -F₈ were isolated along with the known Ginseng-root saponins, ginsenosides-Rb₃, Rd and -Re. Pseudo-ginsenoside-F₈ was proved to be a mono-acetyl-ginsenoside-Rb₃ and the location of its acetyl group was established mainly by ¹³C NMR spectroscopy. Pseudo-ginsenoside-F₁₁, was identified as the 6-O-α-rhamnopyransyl(1 → 2)-β-glucopyranoside of 3β,6α,12β,25-tetrahydoxy-(20S,24R)-epoxy-dammarane. The C-24 configuration of ocotillone and its related triterpenes was confirmed to be 24R excluding the recent comment by Lavie et al.     

Plant regeneration through somatic embryogenesis in root-derived callus of ginseng (Panax ginseng C. A. Meyer)

Summary Callus culture was initiated from expiants of mature root tissues of ginseng (Panax ginseng C.A. Meyer) on MS medium enriched with 2,4-D. The ageing callus produced numerous embryoids in this medium. Reculture of these embryoids in media (1/2 MS or B5) supplemented with benzyladenine and gibberellic acid resulted in profuse plantlet regeneration.     

Cryopreservation of <Emphasis Type="Italic">Panax ginseng</Emphasis> Adventitious Roots

We tested desiccation and/or vitrification procedures to cryopreserve the adventitious roots of Panax ginseng, the source of commercially produced ginsenosides. When only desiccation was applied, the post-freeze survival of 3- to 4-mm root tips was <14% regardless of the composition of the preculture medium or the explant origin. Callus formation was frequently observed after cryopreservation. In contrast, 90% survival and 32.5% root formation efficiency were achieved after cryopreservation when a vitrification protocol was followed. Adventitious root cultures in flasks and bioreactors were reestablished from root tips cryopreserved by vitrification. A prolonged lag-phase and lower biomass production were recorded in post-freeze-regenerated cultures compared with control roots that were subcultured four times in flasks. However, biomass accumulations did not differ between control and regenerated roots at the end of the sixth subculturing period. After 40 days of culture in bioreactors, a mean value of 12.5 g dw L⁻¹ was recorded for post-freeze-regenerated cultures versus 9.1 g dw L⁻¹ for the control roots. Production of triol and diol ginsenosides in our bioreactor cultures also was enhanced after cryopreservation, by 41.0% and 89.8%, respectively. These results suggest that the vitrification method is successful for cryopreservation of P. ginseng adventitious roots.     

人参原生质体培养再生愈伤组织

人参原生质体培养未见报道成功。Harn(1974)曾用人参幼叶,幼根和上胚轴进行原生质体分离,但得到的数量很少,无法进行培养。本实验以人参培养细胞为材料,通过培养再生了愈伤组织。     

三七总RNA提取方法的对比研究

比较利用改进的异硫氰酸胍一步法、异硫氰酸胍高盐法、CTAB法和Thomas’RNA提取法等4种方法提取三七根茎2个部位总RNA的可行性。结果表明,改进的异硫氰酸胍一步法和异硫氰酸胍高盐法能有效地抑制酚类物质、多糖及皂苷等次级代谢产物对总RNA的影响,可从三七根茎中获得质量高、完整性好的总RNA。RT—PCR分析显示提取的总RNA具有反转录活性。这2种方法具有快速、简单、有效的特点。     

竹节参雌配子体发育的研究

本文报道了竹节参(Panax japonicus C.A.Mey)雌配子体(胚囊)的发育过程。竹节参大孢子母细胞减数分裂产生线形排列的大孢子四分体。胚囊发育属蓼型,由合点端大孢子发育而成。游离核胚囊时期,胚囊珠孔端的细胞器种类和数量都较胚囊合点端多;胚囊合点端相邻的珠被细胞中有含淀粉粒的小质体,与胚囊珠孔端相邻的退化中的非功能大孢子中则有含淀粉粒的大质体和大类脂体。成熟胚囊中,反足细胞较早退化;极核融合成次生核;卵细胞高度液泡化,细胞器数量较少;助细胞则有丰富的细胞器和发达的丝状器。PAS反应表明,受精前的成熟胚囊中积累淀粉粒。次生核受精后,很快分裂产生胚乳游离核,到几十至数百个核时形成胚乳细胞。卵细胞受精后则要经过较长的休眠期。     

人参生理生态的研究

人参是我国极其珍贵的药用植物之一。本文从生理生态的角度对其在生长季的各种环境因子的变化规律及光合生理进程作了较为全面、系统的定位定量研究。根据不同观测点的试验数据,得出了有利于人参生长的最适环境范围,为人参的栽培提供了理论依据及基础资料。     

短期生长环境光强骤增导致典型阴生植物三七光系统受损的机制

阴生植物突然暴露在强光下造成光损伤的情况时有发生, 但其对高光敏感的潜在机制尚不十分清楚。为阐明阴生植物无法在自然全光照环境下生存的相关机制, 该研究以典型阴生植物三七(Panax notoginseng)为材料, 将遮阴环境下(10%透光率)生长的植株转移到全日光环境下3天, 研究其相对叶绿素含量(SPAD值)、光合参数以及叶绿素荧光参数的变化。结果表明, 全光环境下三七光合日变化呈现“双峰”曲线特征, 且净光合速率在处理期间逐日降低。全日光下三七叶片SPAD值、水分利用率和光能利用率显著降低; 叶片光系统I (PSI)反应中心P700最大荧光信号、光系统II (PSII)电子传递速率、暗适应下PSII最大量子效率和光下PSII最大量子效率显著低于遮阴环境下的植株, 且至傍晚不能完全恢复。而参与调节性能量耗散的量子产量、PSI受体侧限制引起的非光化学量子产量、环式电子流则显著高于遮阴环境下的三七。此外, 生长环境光照强度骤增导致荧光诱导动力学曲线发生明显变化, 并显著升高了PSII供体侧和受体侧的荧光产量。当阴生植物三七突然暴露于全光环境下时, 强烈的光照会导致PSII供体侧的放氧复合体活性受损, 抑制受体侧的电子传递, 过度还原PSI的受体侧进而引发PSI光抑制。该研究结果揭示, 全日光导致的PSII不可逆损伤和PSI光抑制可能是典型阴生植物三七为什么不能在全日照光环境下存活的重要原因。     

Highly efficient production of diverse rare ginsenosides using combinatorial biotechnology

The rare ginsenosides are recognized as the functionalized molecules after the oral administration of Panax ginseng and its products. The sources of rare ginsenosides are extremely limited because of low ginsenoside contents in wild plants, hindering their application in functional foods and drugs. We developed an effective combinatorial biotechnology approach including tissue culture, immobilization, and hydrolyzation methods. Rh2 and nine other rare ginsenosides were produced by methyl jasmonate-induced culture of adventitious roots in a 10 L bioreactor associated with enzymatic hydrolysis using six β-glycosidases and their combination with yields ranging from 5.54 to 32.66 mg L⁻¹. The yield of Rh2 was furthermore increased by 7% by using immobilized BglPm and Bgp1 in optimized pH and temperature conditions, with the highest yield reaching 51.17 mg L⁻¹ (17.06% of protopanaxadiol-type ginsenosides mixture). Our combinatorial biotechnology method provides a highly efficient approach to acquiring diverse rare ginsenosides, replacing direct extraction from Panax plants, and can also be used to supplement yeast cell factories.