刺芹侧耳生长条件和栽培特性的研究

对刺芹侧耳[Pleurotus eryngii(DC.ex Fr.)Quel]生长条件与栽培特性进行了分析.结果表明:刺芹侧耳菌丝生长的适宜pH值为pH 5～pH 7,最适pH值为pH 6;黑暗环境有利于菌丝生长,光照对菌丝生长具有抑制作用;菌丝生长适宜的碳源为可溶性淀粉、葡萄糖和蔗糖,适宜的氮源为蛋白胨和钼酸铵,葡萄糖和蛋白胨的适宜浓度分别为50和1 g·L-1;在马铃薯黄豆粉培养基、黄豆粉玉米粉培养基和马铃薯蛋白胨培养基中可较好地形成菌丝球.采用液体菌种栽培,菌丝的生长速度比使用玉米固体菌种快,其中用马铃薯黄豆粉液体菌种栽培,菌丝生长最快;使用马铃薯蛋白胨液体菌种在木屑棉籽壳混合培养料中栽培,可获得菌柄长菌盖大的子实体,而且产量高.     

肉质黑孢孔菌生物学特性、驯化栽培及急性毒性

以采自河北省燕山地区的一株野生食用菌肉质黑孢孔菌Amylosporussucculentus经组织分离得到的菌丝体为实验材料,对其菌丝体营养特性和环境特性进行了研究,对其适宜的原种、母种和栽培种培养基进行了筛选,经驯化栽培成功出菇。通过单因素试验和正交试验筛选,得出适合肉质黑孢孔菌菌丝生长的最优配方为：可溶性淀粉1.80%,酵母浸粉0.25%,硫酸镁0.15%,磷酸二氢钾0.30%,琼脂2.00%。适宜肉质黑孢孔菌菌丝生长的温度为31–34℃,pH为4.5–5.5,光照条件为黑暗。适合肉质黑孢孔菌培养的母种培养基为玉米粉培养基,原种培养基为小米培养基。栽培袋接种后30–60 d满袋,5–10 d后现原基,6–11 d原基分化成子实体。高产栽培料配方为玉米芯+棉籽壳培养基,配方为：玉米芯39%,棉籽壳39%,石膏1%,葡萄糖1%;其第一潮菇产量为106.9 g/袋,生物学效率为66.81%。急性经口毒性试验表明：在给予小鼠最大给药量为4612.4mg/kg情况下,肉质黑孢孔菌无明显急性中毒的危险性。     

用正交试验法筛选樟芝菌适宜发酵培养基

用正交试验法对樟芝菌 (AntrodiacamphorataZang&Su)的发酵培养基进行了研究。选取马铃薯淀粉、葡萄糖、麦芽糖、酵母膏、蛋白胨、麸皮、KH2 PO4 、MgSO4 ·7H2 O等作为试验因素 ,采用L2 7(31. 3)正交表设计五因素、三水平的正交试验 ,对所选各因素的添加量分别作了试验 ,对菌丝干重和发酵液多糖含量结果作了方差分析 ,确定了合适的发酵培养基。试验结果表明 :樟芝菌的深层发酵适宜培养基是 :马铃薯淀粉 1 .0 0 % ,葡萄糖2. 0 0 % ,酵母膏 0 . 10 % ,蛋白胨 0 . 10 % ,麸皮 1 .0 0 % (或 0. 5 0 % ) ,KH2 PO4 0 . 10 % ,MgSO4 ·7H2 O 0 . 0 5 %。     

竹荪生长和基质的关系

竹荪(Dictyophora rubrovalvata)在PDA琼脂培养基上培养,菌丝体生长很慢,若在PDA培养基上分别添加酵母膏、生啤酒、天冬酰胺、核糖核酸,可促进菌丝体的生长,菌落直径生长和菌丝线性生长都加快;添加蛋白胨、椰子汁、硫胺素和肌醇效果不明显。菌丝体生长的pH值在4.4—5.4之间,最适pH值为4.7;pH值在6.7以上,菌丝体不生长。在木屑培养基中分别添加麦芽汁、玉米、高粱和黄豆粉可以增加子实体的鲜重,其中黄豆和玉米粉、黄豆和高梁粉混合使用的效果比单用一种的更好,菇产量比对照增加1—2倍。播种后基质中含水量控制在50—60％,当原基形成时,含水量提高到55—70％,空气相对湿度在95％以上,菌蕾才能发育成子实体。在自然温度条件下栽培竹荪,出菇高峰期出现在八月份,基质内平均温度为22.4℃,子实体生长的最适温度在20—22.5℃之间,在此温度下产菇率占总产值的85％。     

不同营养基质与条件对灰树花生长的影响

探讨了不同营养基质与条件对灰树花[Grifola frondosa(Fr.)S.F.Gray]生长的影响。试验结果表明：菌丝生长的最适pH为5-6;最适氮源为蛋白胨、牛肉膏和谷氨酰胺,葡萄糖和蛋白胨最适浓度分别为100和1g/L;菌丝在黑暗环境下生长良好;使用马铃薯蛋白胨培养基进行振荡培养,菌丝球生长较好;母种采用马铃薯麦麸培养基,栽培种选用棉子壳麦麸石培养料,可缩短制种周期,获得质量较高的菌种;菌丝含有较多的钙、铁和锌等元素。     

在哈尔滨地区使用液体菌种栽培红平菇技术初探

从福建三明真菌研究所(福建省三明市375000)购入红平菇优良菌株,在哈尔滨地区对其进行了用液体菌种代替固体原料的栽培技术研究。包括一级种培养基的筛选、液体菌种培养基的筛选、栽培种制作与培养以及出菇管理技术。结果表明:对于一级种,红平菇在PDA和马铃薯半组合培养基上都生长良好,菌丝洁白、粗壮、浓密,7～8d长满斜面;红平菇在玉米粉葡萄糖蛋白胨和麦麸葡萄糖蛋白胨液体培养基上生长较好,7d时菌丝长满培养液,菌丝量较多;用与平菇相似的常规方法制作栽培种、养菌处理与出菇管理,红平菇的产量达100%～150%。由于采用了液体菌种的栽培模式,从制种到采收的整个过程共需要50～60d,比二级种为固体菌种的常规方法缩短26～31d,大大地缩短了生产周期,提高了经济效益。     

中国东北地区三种蜜环菌的生物学特性及奥氏蜜环菌人工培养

蜜环菌属Armillaria真菌具有较高的食药用价值。由于蜜环菌的生长发育过程较复杂,还未完全实现商业化栽培,野生资源的供应受到季节性和地域性的影响。本研究以采自东北地区蜜环菌属的3个菌株为研究对象,通过培养物的形态特征及分子标记确定菌株JG19016为奥氏蜜环菌A. ostoyae,菌株JG19017为高卢蜜环菌A. gallica,菌株JG19018为中国蜜环菌生物种C。奥氏蜜环菌JG19016最适生长温度为25 ℃,高卢蜜环菌JG19017的最适生长温度为22 ℃,中国蜜环菌生物种C JG19018则在22-25 ℃时菌丝生长速度最快;3个菌株最适pH为5-6。奥氏蜜环菌JG19016对葡萄糖和蔗糖利用率较好,高卢蜜环菌JG19017对葡萄糖利用率较好,中国蜜环菌生物种C JG19018对葡萄糖和淀粉利用率较好;蛋白胨对3个菌株促进作用最强,为最适氮源。培养基中加入VB₁,对3个菌株的菌丝生长均有明显的促进作用。奥氏蜜环菌JG19016菌丝生长的最优培养基配方为：葡萄糖20 g,蛋白胨3 g,磷酸二氢钾2 g,硫酸镁1.5 g,VB₁ 10 mg,琼脂20 g,水1 L。在木屑基质中培养,其配方的最优碳氮比为38:1,最佳木屑粗细比为3:1以上。出菇条件探索结果显示,菌丝及菌索长满菌袋(17 mm×33 mm×5 mm丝聚乙烯袋)需要50-60 d,之后在18 ℃、60%湿度和12 h散射光的环境中,10 d左右可观察到原基产生。增加菇房湿度到90%-95%,2-3 d可观察到1-3 cm的幼子实体,7 d左右菌柄和菌盖完全分化,10 d左右观察到菌盖展开。     

碳源和氮源对黑盖木层孔菌菌丝生长的影响

研究了四种碳源(蔗糖、乳糖、葡萄糖、可溶性淀粉)和九种氮源(玉米面、麸皮、马铃薯、大豆粉、酵母粉、蛋白胨、硝酸钾、硝酸铵、尿素)对黑盖木层孔菌菌丝生长的影响。从不同代数的菌丝体中提取多糖,并测定多糖含量、分子量分布范围及单糖组成。结果表明:黑盖木层孔菌菌丝生长的最佳碳源为可溶性淀粉,最佳氮源为玉米面,最优碳氮组合为蔗糖和玉米面的组合。不同代数的菌丝体多糖性状基本稳定。     

芳香杯伞生物学特性及驯化栽培

以采自于河北省平泉市的一株野生食用菌Clitocybe fragrans的菌丝体为材料,对其营养及环境特性进行研究。检测了不同碳源、氮源、C/N、无机盐在固体培养条件下对芳香杯伞菌丝生长的影响,单因素及正交试验结果表明,实验范围内,芳香杯伞最适碳源为蔗糖、最适氮源为酵母浸粉、最适C/N为40:1、最适无机盐为硫酸镁。正交试验筛选适宜培养基配方为：蔗糖17.3 g,酵母浸粉1.8 g,磷酸二氢钾3 g,无水硫酸镁1.5 g,琼脂20 g,水1 L。对菌丝生长所需的温度、pH及光照条件进行研究,结果显示,适宜菌丝生长的温度范围为19–25℃,pH值范围为5–5.5,光照条件为黑暗。对获得的菌种进行了驯化栽培研究,结果表明,适宜的母种扩繁培养基为：粪草培养料100 g (煮汁),马铃薯200 g (煮汁),葡萄糖20 g,磷酸二氢钾3 g,蛋白胨3 g,无水硫酸镁1.5 g,琼脂20 g,水1 L;原种培养基为：高粱粒98%,葡萄糖1%,石膏1%;栽培培养基质为：粪草培养料98%,石膏1%,葡萄糖1%,含水量55%。栽培袋接菌后35–40 d满袋,8–10 d后现原基,7–8 d原基分化成子...     

基质碳氮比对广叶绣球菌生长发育的影响

培养基质碳氮比显著影响食用菌菌丝生长及子实体生长发育。广叶绣球菌是一种珍贵的食药用真菌,前期研究发现其生长发育过程中对碳源的需求较多。本研究采用松木屑、复合氮源作为栽培原料,研究基质碳氮比对绣球菌菌丝生长及子实体生长发育的影响。结果表明：6种不同碳氮比（C/N）的栽培基质对菌丝生长速度无显著影响,但是随着C/N比值的增加,子实体形成期逐渐延长,子实体形成率呈先增大后减小的趋势。当基质C/N在48.8-55.9之间时,采收率较高,在80-90d内,达到采收标准的菌袋比例分别为83.7%和81.4%。当基质C/N为43.4时,鲜菇产量最高,但外观品质受影响。综合考虑生产成本及效率,采用松木屑和复合氮源作为栽培原料、适宜的基质C/N为48.8时,绣球菌子实体形成期为64d,子实体形成率为95%且较为集中,鲜菇平均产量为231g/袋（76%集中于200-260g/袋）,整个生产周期为84d。本研究结果表明绣球菌具有“高碳低氮”的营养生理特性。     

马铃薯干腐病菌硫色镰孢的生物学特性

从碳源、氮源、酸碱度及生长温度等方面对引起马铃薯干腐病的硫色镰孢Fusarium sulphureum的生物学特性进行了研究。结果表明,该病原菌在不同发育阶段对营养和环境条件的要求存在差异。在固体培养基上,菌落生长最佳碳源为葡萄糖、麦芽糖,最佳氮源为蛋白胨,pH8?为最佳;在液体培养基中,菌丝体生长以麦芽糖为最佳碳源,以硝酸钠为最佳氮源,pH6?为最佳;在分生孢子萌发阶段,在以羧甲基纤维素钠、蛋白胨和谷氨酸为碳、氮源的营养液中,分生孢子萌发率最高,最适pH 6–8。该病菌最适生长温度为25℃,分生孢子致死     

Protease production by the ontjom fungus,Neurospora sitophila

Summary The production of protease and mycelium byNeurospora sitophila cultured on solid and liquid potato dextrose media was studied. Maximal activity of protease extracted from 4-day-old cultures occurred at pH 6.5 when an unfractionated peanut (groundnut) protein substrate was used. The greatest protease activity and mycelium production occurred during the first day of the 4-day test period. Potato dextrose media containing more than 0.2 M NaCl resulted in decreased protease and mycelium production, while tapioca starch was without affect at concentrations up to 1.4%. Addition of up to 0.3 M sucrose to growth media greatly stimulated protease production and mycelial growth. Maximal proteolytic activity was observed in extracts from mycelium cultured in potato dextrose media adjusted from pH 6.0 to 7.5. Activity was greater when soluble peanut protein was used as a substrate, compared to unfractionated or globulin protein substrates.     

樟芝对氮素营养源利用的研究

采用 5种不同的氮素营养源 ,配制合成液体培养基 ,测定各种氮源对樟芝菌丝液体深层培养的影响。结果表明 ,樟芝对 5种氮源的利用表现明显的差异性 ,对有机氮利用较好 ,尤其是酵母膏 ,无论是菌球数量还是菌体收率均高于蛋白胨。酵母膏的菌球数量达 1 2 5 8个 /dL,比蛋白胨多出 63 8个 ;菌体干重为 7 2 1 6g/dL比蛋白胨高出 1 45 0g/dL。樟芝对无机氮的利用不如有机氮 ,其中对硫酸铵能够利用 ,而对硝酸铵的利用较差 ,对碳酸铵基本不能利用。樟芝菌丝在液体深层培养过程中 ,pH值变化幅度不大 ,基本处于平缓状态。有机氮处理的发酵液起始pH值与终止pH值呈上升趋势 ,而无机氮处理的发酵液pH值呈下降趋势 ,但下降的幅度不大 ,尤其是碳酸铵 ,pH值一直处于偏碱性状态 ,不适合樟芝菌丝的生长。樟芝在马铃薯基础培养基中 ,不同氮源的各个处理 ,菌球生长都比较均匀 ,表面光滑 ,没有分枝 ,圆形或肾形 ,且发酵液有浓郁的果香味。     

凝固剂对水稻花药培养愈伤组织诱导的影响

本文初步研究了不同类型的凝固剂对水稻花药培养愈伤组织形成的影响。结果发现,用Gelrite、马铃薯淀粉、甘薯淀粉、可溶性淀粉代替琼脂可明显促进水稻花药培养愈伤组织的产生而尤以5.0%马铃薯淀粉为最佳。出愈率比琼脂增加5.2倍,达液体培养水平。以8个不同基因型,为材料研究发现,5.0%马铃薯淀粉作凝固剂,有7个材料出愈率高于对照,最高的BC 163比对照增加7.75倍,平均增加1.15倍。另外,以5.0%马铃薯淀粉作凝固剂代替0.8%琼脂可降低成本30%。因此,用马铃薯淀粉作凝固剂在水稻花药培养中可能具有潜在的应用价值。     

凝固剂对水稻花药培养愈伤组织诱导的影响

本文初步研究了不同类型的凝固剂对水稻花药培养愈伤组织形成的影响。结果发现,用Gelrite、马铃薯淀粉、甘薯淀粉,可溶性淀粉代替琼脂可明显促进水稻花药培养愈伤组织的产生而尤以5.0％马铃薯淀粉为最佳。出愈率比琼脂增加5.2倍,达液体培养水平。以8个不同基因型,为材料研究发现,5．0％马铃薯淀粉作凝固剂,有7个材料出愈率高于对照,最高的BCl63比对照增加7.75倍,平均增加1.15倍。另外,以5.0％马铃薯淀粉作凝固剂代替0.8％琼脂可降低成本30％。因此,用马铃薯淀粉作凝固剂在水稻花药培养中可能具有潜在的应用价值。     

花生壳培养基对杏鲍菇菌丝生长的影响

以农业废料花生壳为主要原料设计不同配方,筛选适宜杏鲍菇菌丝生长的培养基及培养料.结果表明,母种培养基以m(花生壳):m(马铃薯)=3:1的配方生长最快,平均生长速度为4.53 mm/d,长势最旺盛;原种及栽培种培养料按m(棉籽壳):m(花生壳)=1:1的配方菌丝生长最快而健壮,生长速度可达5.43 mm/d.因此,在花...     

Peptone,a low-cost growth-promoting nutrient for intensive animal cell culture

The effect of addition of peptone to serum-free and serum supplemented media for the growth of hybridoma cells in various systems was studied. Supplementation of defined medium with either proteose peptone or meat peptone resulted in significant increases in cell number and specific monoclonal antibody production in batch culture system. Other peptones were either inactive or less effective. In continuous culture, using medium supplemented with new born calf serum, the addition of peptone resulted in 125% and 150% increases in cell and antibody concentrations respectively. Similar increase in cell number (128%) was also obtained in spin-filter perfusion culture when medium was supplemented with peptone. By comparison, the substitution of a defined 1xMEM amino acids mixture resulted in only a 50% increase. At higher perfusion rates the cell number maintained in steady state using peptone supplement could be increased to 1.3×10⁷ cells ml^–1 while the serum concentration was reduced from 5% to 1% at a perfusion rate of 2.5 volumes per day.     

Growth and fat formation of Aspergillus oryzae and Aspergillus terreus on enzyme-hydrolyzed sweet potatoes

Two fungi, namely,Aspergillus oryzae andAspergillus terreus, have been grown on enzyme-hydrolyzed sweet potato medium either as such or supplemented with an external source of nitrogen in the form of ammonium carbonate, sodium nitrate, or asparagine. Hydrolysis alone promoted carbohydrate uptake, growth as well as fat formation to a remarkable extent in both fungi.Addition of an external supply of nitrogen to the hydrolyzed media increased further carbohydrate absorption which continued until the potato media were almost completely depleted; on unhydrolysed potato media, appreciable amounts of carbohydrates always remained unutilized. It also accelerated the rate of building up so that the dry mycelium increased by more than 4 times in some cases. Fat formation was consequently remarkably enhanced specially in the presence of ammonium carbonate or asparagine.     

A preliminary study of the applicability of sweet potatoes for mycological fat production

Summary For mycological fat production,Aspergillus nidulans andPenicillium lilacinum were grown on media made up of crushed and boiled sweet potatoes. Mycelial mats containing a fair amount of fat were obtained, namely, 15 % in case ofAspergillus and 24 % in case ofPenicillium. Media containing an external supply of glucose gave rise to increase in percentage fat in mycelium, but the amount of mycelium and consequently the total fat content decreased.Addition of sodium nitrate gave heavier mycelial mats but the total fat content could not be raised.Addition of potassium phosphate or magnesium sulphate or both to the sweet potato medium gave rise to heavier mycelial mats but with lower fat content.     

The production of ectomycorrhizal mycelium in forests: Relation between forest nutrient status and local mineral sources

Due to acid rain and nitrogen deposition, there is growing concern that other mineral nutrients, primarily potassium and phosphorus, might limit forest production in boreal forests. Ectomycorrhizal (EcM) fungi are important for the acquisition of potassium and phosphorus by trees. In a field investigation, the effects of poor potassium and phosphorus status of forest trees on the production of EcM mycelium were examined. The production of EcM mycelium was estimated in mesh bags containing sand, which were buried in the soil of forests of different potassium and phosphorus status. Mesh bags with 2% biotite or 1% apatite in sand were also buried to estimate the effect of local sources of nutrients on the production of EcM mycelium. No clear relation could be found between the production of EcM mycelium and nutrient status of the trees. Apatite stimulated the mycelial production, while biotite had no significant effect. EcM root production at the mesh bag surfaces was stimulated by apatite amendment in a forest with poor phosphorus status. The contribution of EcM fungi to apatite weathering was estimated by using rare earth elements (REE) as marker elements. The concentration of REE was 10 times higher in EcM roots, which had grown in contact with the outer surface of apatite-amended mesh bags than in EcM roots grown in contact with the biotite amended or sand-filled mesh bags. In a laboratory study, it was confirmed that REE accumulated in the roots with very low amounts <1 translocated to the shoots. The short-term effect of EcM mycelium on the elemental composition of biotite and apatite was investigated and compared with biotite- and apatite-amended mesh bags buried in trenched soil plots, which were free from EcM fungi. The mesh bags subjected to EcM fungi showed no difference in chemical composition after 17 months in the field. This study suggests that trees respond to phosphorus limitation by increased exploitation of phosphorus-containing minerals by ectomycorrhiza. However, the potential to ameliorate potassium limitation in a similar way appears to be low.