我国28种鹅膏菌主要肽类毒素的检测分析

利用高效液相色谱(HPLC)技术对产于我国的28种鹅膏菌的主要肽类毒素(鹅膏毒肽和鬼笔毒肽)进行了检测分析,并和采于欧洲(德国)的毒鹅膏。Amanita phalloides作对照,结果表明,3种东亚所特有的鹅膏菌(灰花纹鹅膏、致命鹅膏和黄盖鹅膏白色变种)和欧洲毒鹅膏所含毒素种类多、含量高,其子实体菌盖部位主要毒素总量分别达到12583．7μg／g、8152．6μg／g、1058．2μg／g、7456．2μg／g干重子实体,这4种鹅膏菌可称之为剧毒鹅膏菌。其它25种鹅膏菌中有10种检测出含有微量鹅膏毒肽,含量在19．5μg／g—151．2μg/g之间。在4种剧毒鹅膏菌中,子实体组织部位不同,毒素含量以及鹅膏毒肽和鬼笔毒肽在其中的分布也不一样,菌盖中的毒素含量最高,菌柄的毒素含量次之,菌托中的毒素含量最低;对于灰花纹鹅膏、致命鹅膏和黄盖鹅膏白色变种,无论在菌盖、菌柄和菌托中,鹅膏毒肽类毒素的含量都高于鬼笔毒肽类毒素,尤其以α-amanitin的相对含量最高;而在欧洲毒鹅膏中,菌盖、菌柄和菌托中都以鬼笔毒肽为主,尤其以phallacidin的相对含量最高,并且从菌盖至菌柄到菌托,鬼笔毒肽的相对含量依次增加。     

我国28种鹅膏菌主要肽类毒素的检测分析*

利用高效液相色谱(HPLC)技术对产于我国的28种鹅膏菌的主要肽类毒素(鹅膏毒肽和鬼笔毒肽)进行了检测分析,并和采于欧洲(德国)的毒鹅膏Amanita phalloides作对照,结果表明,3种东亚所特有的鹅膏菌(灰花纹鹅膏、致命鹅膏和黄盖鹅膏白色变种)和欧洲毒鹅膏所含毒素种类多、含量高,其子实体菌盖部位主要毒素总量分别达到12583.7μg/g、8152.6μg/g、1058.2μg/g、7456.2μg/g干重子实体,这4种鹅膏菌可称之为剧毒鹅膏菌。其它25种鹅膏菌中有10种检测出含有微量鹅膏毒肽,含量在19.5μg/g-151.2μg/g之间。在4种剧毒鹅膏菌中,子实体组织部位不同,毒素含量以及鹅膏毒肽和鬼笔毒肽在其中的分布也不一样,菌盖中的毒素含量最高,菌柄的毒素含量次之,菌托中的毒素含量最低;对于灰花纹鹅膏、致命鹅膏和黄盖鹅膏白色变种,无论在菌盖、菌柄和菌托中,鹅膏毒肽类毒素的含量都高于鬼笔毒肽类毒素,尤其以α-amanitin的相对含量最高;而在欧洲毒鹅膏中,菌盖、菌柄和菌托中都以鬼笔毒肽为主,尤其以phallacidin的相对含量最高,并且从菌盖至菌柄到菌托,鬼笔毒肽的相对含量依次增加。     

云南楚雄致命鹅膏中环肽毒素的检测与分析

采用反相高效液相色谱法对采自云南楚雄双柏县的致命鹅膏在3个不同生长期中不同部位的6种环肽毒素含量进行了检测和分析。结果表明,致命鹅膏含有α-, β-鹅膏毒肽、羧基三羟鬼笔毒肽和羧基二羟鬼笔毒肽,未检出γ-鹅膏毒肽和二羟鬼笔毒肽。生长期毒素总量最高（9.3mg/g）、从成熟期（7.5mg/g）到衰老期（6.5mg/g）逐渐降低,但鬼笔毒肽的相对含量随着年龄增长而逐渐增加,鹅膏毒肽与鬼笔毒肽比值从生长期、成熟期到衰老期分别为2.6、1.4和0.9。在3个不同发育阶段中,4种毒素含量从菌盖、菌柄到菌托逐渐降低,而鬼笔毒肽的相对含量逐渐增加。α-鹅膏毒肽和β-鹅膏毒肽在生长期菌盖中含量最高,分别为7.4mg/g和3.1mg/g,而羧基三羟鬼笔毒肽和羧基二羟鬼笔毒肽在衰老期的菌盖中含量最高,分别为2.8mg/g和2.1mg/g。     

黑鹅膏菌（Amanita fuliginea）毒素的HPLC初步分离鉴定

本文了用反相高效液相色谱法（ＨＰＬＣ）分离黑鹅膏实体内几种鹅膏毒素的结果,采用Ｃ１８液相柱,以不同浓度的０．０２ｍｏｌ／Ｌ乙酸铵－乙腈混合液为流动相,从黑鹅膏子产体中分离并鉴定出了６种毒素,每公斤干重含量分别为（ｍｍｏｌ）：α－毒伞肽：５．１９ｍｍｏｌ;β－毒伞肽;１．１７ｍｍｏｌ;ｐｈａｌｌｏｉｄｉｎ;１．５ｍｍｏｌ;ｐｈａｌｌａｃｉｄｉｎ;０．４０ｍｍｏｌ;ｐｈａｌｌｉｓｉｎ;０．２６ｍｍｏｌ     

枝顶孢霉对毒光盖伞子实体形成的影响

报道枝顶孢霉Acremonium strictum对毒光盖伞Psilocybe venenata子实体形成的影响。拮抗试验结果表明它们之间存在着较弱的干扰竞争作用;人工培养时,毒光盖伞混合菌株产生大型、小型和畸形3种类型的子实体,推测毒光盖伞畸形子实体的形成可能是枝顶孢霉寄生的结果,为毒光盖伞的人工栽培和进一步合理利用、野生蕈菌的驯化提供了理论依据。     

我国鹅膏菌新发现种--致命鹅膏(Amanita exitialis)的肽类毒素分析

采用高效液相色谱(HPLC)技术对在广州发现的鹅膏菌新种——致命鹅膏(Amanita exitialis)不同组织部位的肽类毒素(鹅膏毒肽和鬼笔毒肽)的含量进行了分析,结果表明,致命鹅膏是一种剧毒蘑菇,其毒素含量相当高,子实体中组织部位不同,毒素含量以及鹅膏毒肽和鬼笔毒肽在其中的分布也不一样,菌盖中的毒素含量最高,达8152．6μg／g干重,菌柄的毒素含量次之,为3742．3μg／g干重,菌托中的毒素含量最低,只有1142．5μg／g干重;在菌盖、菌柄和菌托中都以鹅膏毒肽为主,尤其以α-amanitin的相对含量最高,但从菌盖至菌柄到菌托,鬼笔毒肽尤其是Phallacidin的相对含量依次增加。     

枝顶孢霉对毒光盖伞子实体形成的影响

报道枝顶孢霉Acremonium strictum对毒光盖伞Psilocybe venenata子实体形成的影响。拮抗试验结果表明它们之间存在着较弱的干扰竞争作用;人工培养时,毒光盖伞混合菌株产生大型、小型和畸形3种类型的子实体,推测毒光盖伞畸形子实体的形成可能是枝顶孢霉寄生的结果,为毒光盖伞的人工栽培和进一步合理利用、野生蕈菌的驯化提供了理论依据。     

我国鹅膏菌新发现种——致命鹅膏(Amanita exitialis)的肽类毒素分析

采用高效液相色谱（HPLC）技术对在广州发现的鹅膏菌新种——致命鹅膏(Amanita exitialis)不同组织部位的肽类毒素(鹅膏毒肽和鬼笔毒肽)的含量进行了分析,结果表明,致命鹅膏是一种剧毒蘑菇,其毒素含量相当高,子实体中组织部位不同,毒素含量以及鹅膏毒肽和鬼笔毒肽在其中的分布也不一样,菌盖中的毒素含量最高,达8152.6μg/g干重,菌柄的毒素含量次之,为3742.3μg/g干重,菌托中的毒素含量最低,只有1142.5μg/g干重;在菌盖、菌柄和菌托中都以鹅膏毒肽为主,尤其以αamanitin的相对含量最高,但从菌盖至菌柄到菌托,鬼笔毒肽尤其是Phallacidin的相对含量依次增加。     

鹅膏环肽类毒素检测技术的研究进展

鹅膏环肽类毒素主要存在于鹅膏属Amanita、盔孢伞属Galerina和环柄菇属Lepiota蘑菇中。如果不慎摄入,可能会给人类和动物带来严重的健康风险。快速准确地鉴定蘑菇和生物样品中的这些毒素对于确保食品安全以及诊断和治疗蘑菇中毒至关重要。本文综述了文献报道的各类检测方法,重点介绍高效液相色谱与质谱联用法,这是测定复杂基质中鹅膏肽类毒素的主要分析方法。此外,本文还提出了鹅膏环肽类毒素检测的当前趋势,并对未来现场快速检测及仪器定量检测进行了展望。     

Detection and Identification of Amanitins in the Wood-Rotting Fungi Galerina fasciculata and Galerina helvoliceps

More than 600 strains of wood-rotting fungi were screened for the detection of amanitins. Three strains of Galerina fasciculata and 18 strains of Galerina helvoliceps contained amanitins. These strains contained mainly α- and β-amanitins in the native fruit bodies, while α- and γ-amanitins were found in liquid-cultured mycelia. Purified amanitins were confirmed by their chromatographic profiles, spectra (UV, Fourier transform infrared, and atmospheric ionization mass), cytotoxicity for mammalian cell lines (3T3 and SiHa), and inhibitory effects on RNA polymerase II. The results revealed that the purified amanitin fractions from these species are identical to authentic amanitins and suggest that these two species must be handled as poisonous mushrooms.     

The Influence of Light and Temperature on Fruiting of Coprinus lagopus Fr. in Pure Culture

Some effects of light and temperature on fruiting of Coprinuslagopus in pure culture are described. Fruiting, which in darknessdid not commence until about the 15th day, was accelerated bycontinuous light or by brief exposures to light between the7th and 13th days of incubation. Very small exposures sufficed,provided they were of a wavelength no longer than that of greenlight, the response being restricted to the area of myceliumactually exposed. In both light and dark a temperature near25° C. was optimal for growth and fruiting.     

Fruiting Body Formation from Regenerated Mycelium of Pleurotus ostreatus Protoplasts

Fruiting bodies were induced from mycelium regenerated from Pleurotus ostreatus protoplasts. Mycelia originated from protoplasts conformed to parental strain mycelia in morphology. Six strains selected at random from the dikaryotic regenerants were able to form normal fruiting bodies, yielding 18% more than the parent.     

Structures and Antitumor Activities of the Polysaccharides Isolated from Fruiting Body and the Growing Culture of Mycelium of Ganoderma lucidum

Several β-D-glucans, appertaining to the same molecular species but having different degrees of branching, were isolated from water and alkali extracts of the fruiting body of Ganoderma lucidum (Reishi). The purified glucans that were mostly water-insoluble had a backbone of (1 →3)-linked D-glucose residues, attached mainly with single D-glucosyl units at 0-6 and also with a few short (l→4)-linked glucosyl units at 0-2 positions. However, their degrees of branching appeared to differ in the range of d.b. 1/3 ~ 1/23, depending on the extracted glucan fractions. In addition to the ^-glucans, the fruiting body contained water-soluble heteropolysaccharides, comprising D-glucose, D-galactose, D-mannose, L-(or D)-arabinose, D-xylose, and L-fucose.

A branched (1 →3)-β-D-glucan was also isolated from the culture filtrate of G. lucidum grown in a glucose-yeast extract medium. The extracellular β-D-glucan was less soluble in water after purification, but soluble in dilute alkali. This glucan has essentially the same structure as that of hot-water extracted polysaccharide from the fruiting body. The repeating unit of the glucan contains a backbone chain of (1 →3)-linked D-glucose residues, five out of sixteen D-glucose residues being substituted at 0-6 positions with single D-glucosyl units and one D-glucose residue at 0-2 positions probably with a cellobiose unit.

The hot-water extractable fruiting body glucan and the extracellular glucan of the culture of growing mycelium showed relatively high growth-inhibition activities against Sarcoma 180 solid tumor in mice, when administered by. successive intraperitoneal injections. When the moderately branched glucans were modified to D-glucan-polyols by periodate oxidation and borohydride reduction, they exhibited higher antitumor activities, confirming the previous conclusion that the attachment of polyol groups to the (1 →3)-lmked backbone significantly enhances its host-mediated antitumor effect.     

蛹虫草子实体多糖的分离纯化

目的:研究人工培养蛹虫草子实体多糖的分离纯化方法.方法:多糖经脱色、醇析、除蛋白及乙醇分级沉淀,采用Seph-adex G100柱层析纯化.结果:60℃脱色9h脱色率达70.72％.醇析最优条件为:无水乙醇,24h,4倍乙醇.Sevag法抽提30min重复6次除蛋白率达84.09％;抽提lh重复3次、6次除蛋白率分别为81.14％、84.47％,多糖损失率分别为27.03％、43.16％.木瓜蛋白酶除蛋白最优条件为70℃,1:10,2h,除蛋白率为25.67％.粗多糖经乙醇分级沉淀得2种粗多糖成分,分别经Sephadex G100柱层析可进一步纯化为3种较纯多糖成分.结论:采用乙醇分级沉淀及Sephadex G100柱层析纯化粗多糖可得到3种较纯多糖成分,纯化效果较好.     

橘黄裸伞子实体个体发育研究

采用石蜡切片法对不同发育时期橘黄裸伞的原基或幼子实体进行个体发育研究。结果表明:橘黄裸伞原基的第一个形态分化是下部边缘菌丝平行排列进行垂直生长,形成菌柄;然后边缘菌丝迅速向外生长,外菌幕形成,菌盖原基生长,在菌盖原基下部观察到菌褶腔,菌褶腔上部连续排列着栅栏细胞;在菌褶形成过程中,囊状体在尖端上聚集,说明菌褶的生长点在与菌盖组织相连的基部而不是尖端;内菌幕由内菌幕原基、菌盖边缘平行向下生长的菌丝和菌柄上部边缘平行向外生长的菌丝共同发育形成,由于内菌幕与菌柄组织的同源性,菌环不易脱落。橘黄裸伞属于半被果型中的双菌幕发育型,发育顺序表明其为菌柄发育型。     

黄鳞伞子实体发育

为了丰富大型真菌个体发育学研究数据,并依据个体发育学数据提出分类学建议,通过石蜡切片法对黄鳞伞子实体进行了发育学观察。结果显示:黄鳞伞子实体发育初期原基圆形至卵圆形,具外菌幕原基,内部菌丝弯曲致密,螺旋交织在一起呈束状,随着原基的发育,端向膨大生长,菌盖原基出现,与此同时原基基部在保持伸长生长外,直径也明显增大,菌柄原基由此形成。随后菌褶腔出现,栅栏状细胞的出现表明子实层发育的开始,发育过程中Y型菌褶清晰可见。黄鳞伞的发育属于菌盖菌柄型发育,发育类型是半被果双菌幕发育型。     

Method for Radiorespirometric Detection of Bacteria in Pure Culture and in Blood

Methods are described for the detection of low numbers of bacteria by monitoring (14)CO(2) evolved from (14)C-labeled substrates. Cell suspensions are filtered with membrane filters, and the filter is then moistened with 0.1 ml of labeled medium in a small, closed apparatus. Evolved (14)CO(2) is collected with Ba(OH)(2)-moistened filter pads and assayed with conventional radioactivity counting equipment. The kinetics of (14)CO(2) evolution are shown for several species of bacteria. Fewer than 100 colony-forming units of most species tested were detected in 2 h or less. Bacteria were inoculated into blood and the mixture was treated to lyse the blood cells. The suspension ws filtered and the filter was placed in a small volume of labeled medium. The evolved (14)CO(2) was trapped and counted. A key development in the methodology was finding that an aqueous solution of Rhyozyme and Triton X-100 produced lysis of blood but was not detrimental to bacteria.     

Purification and Properties of Tyrosinase Isozymes from the Gill of Lentinus edodes Fruiting Body

Six tyrosinase isozymes were purified from the browned gill of the fruiting body of Lentinus edodes by ammonium sulfate fractionation, DEAE-Sephacel and Q-Sepharose column chromatography, and partially denaturing SDS–PAGE. At the step of Q-Sepharose column chromatography, two active fractions (A and B) were obtained. Each fraction was separated to three further fractions, A1, A2, and A3, and B1, B2, and B3, respectively, by partially denaturing SDS–PAGE. All these isozymes consisted of two types of polypeptides: a polypeptide (Aα or Bα) and either β (Aβ or Bβ) or γ polypeptide (Aγ or Bγ). The α polypeptide contained the consensus amino acid sequence of the active site of known tyrosinases, which is considered to act as a catalytic subunit. From the results of peptide mapping and the amino acid composition, Aα and Bα polypeptides were considered to be different proteins. The kinetic properties of the purified tyrosinase isozymes differed greatly according to whether they contained β or γ polypeptide, indicating these polypeptides to be a possible regulatory subunit.     

蛹虫草子实体中甘露醇含量的测定

建立了HPLC法测定蛹虫草子实体中甘露醇含量的方法。通过比较提取溶剂、提取方式及提取时间等条件对甘露醇提取效果的影响,确定甘露醇分析的前处理方法为:1g子实体粉中加入150 mL 90%乙醇热回流提取1h。采用SUGAR SP0810柱(300 mm×8 mm)为分析柱,超纯水为流动相,流速1.0 mL/min,柱温70℃,示差折光检测器检测,进样量10μL。甘露醇在0.04-9.9 mg/mL范围内线性关系良好,回归方程为y=103860x+2183.9(r=0.9999),平均回收率为104.27%,RSD=2.19%(n=9)。本方法准确度高,稳定性、精密度、重现性好,适用于蛹虫草子实体中甘露醇含量的分析。