硬粒小麦单倍体原生质体培养及植株再生

由硬粒小麦（Ｔｒｉｔｉｃｕｍ ｄｕｒｕｍ Ｄｅｓｆ．）×玉米（Ｚｅａ ｍａｙｓＬ．）建立的单倍性胚性愈伤组织,在继代培养４ 个月后置于含２．０ ｍ ｇ／Ｌ２,４－Ｄ、３％ 蔗糖、２００ ｍ ｇ／Ｌ水解酪蛋白、１４６ ｍ ｇ／Ｌ谷氨酰胺和３００ ｍ ｇ／Ｌ天冬氨酸的ＭＳ液体培养基中进行悬浮培养,４ 个月后形成了生长迅速、由大小不同（０．５ ～５ ｍ ｍ ）的愈伤组织块组成的愈伤组织悬浮系。酶解试验表明,２．０％ 纤维素酶ＲＳ和０．５％ 的离析酶效果最好,而液体悬浮培养物和固体培养的愈伤组织（在酶解时用锋利的解剖刀片切成１ ｍ ｍ 左右的小块）都能释放出大量原生质体,但悬浮培养物释放出的原生质体状态较好,胞质更浓厚,用ＫＭ８ｐ 培养基以琼脂糖包埋培养方式培养时分裂频率可达５％ 左右。由原生质体再生的小愈伤组织经增殖、筛选后可获得胚性愈伤组织,将其转移至分化培养基Ⅰ（０．２ ｍ ｇ／Ｌ ２,４－Ｄ、１．０ ｍ ｇ／Ｌ ＢＡＰ、０．１ ｍ ｇ／ＬＮＡＡ、３％ 蔗糖、２００ ｍ ｇ／Ｌ 水解酪蛋白、１４６ ｍ ｇ／Ｌ谷氨酰胺和３００ ｍ ｇ／Ｌ天冬氨酸的ＭＳ固体培养基）和Ⅱ（不含２,４－Ｄ,其它成分同Ⅰ）上进行分步分化培养可再生出完整植株,分化频率约为２０％     

蜜环菌菌索分化的差异蛋白质组学研究

菌索是蜜环菌与宿主互作的组织结构,蜜环菌菌丝形成菌索的分子机制尚不清楚。本研究采用SWATH-MS^ALL非标记定量蛋白质组学技术,首次对Armillaria mellea菌丝形成菌索过程的蛋白质组学进行了系统研究。在蜜环菌菌丝和菌索中共鉴定蛋白1 724个（global FDR 1%）,定量蛋白1 179个。与菌丝相比,蜜环菌菌索差异表达蛋白640个（上调表达256个,下调表达384个）。差异表达蛋白GO注释结果表明,蜜环菌菌索分化的生物学过程较复杂,差异蛋白参与的主要生物学过程包括有机含氮化合物代谢、有机物生物合成、小分子代谢、氧化还原反应等。分子功能富集结果提示,电子转运活性的富集因子最高,而氧化还原反应的富集P值最显著,这与KEGG注释的氧化磷酸化代谢活跃的结果一致。进一步的推测分析表明,蜜环菌菌丝形成菌索可能是受到氧化应激所致,菌索的形成可能促使诸如硫氧还蛋白样等毒力蛋白和富马酸的合成和释放增多,抑制宿主免疫而有利于蜜环菌侵染和定植于宿主。因此,对差异蛋白质组的进一步研究和深入解析不仅有利于揭示蜜环菌菌索形成的蛋白分子机制,同时也具有较强的理论和现实意义。     

毛花猕猴桃原生质体再生植株

从毛花猕猴桃（Ａｃｔｉｎｉｄｉａ ｅｒｉａｎｔｈａ Ｂｅｎｔｈ．）试管培养的实生苗新展开叶片分离的原生质体,培养在液体ＭＳ（除去ＮＨ４ＮＯ３）附加２,４－Ｄ １．０ ｍ ｇ／Ｌ和葡萄糖０．４ ｍ ｏｌ／Ｌ的培养基上。培养３周后植板率达到１９．４％ 。在未添加新鲜培养基的情况下,原生质体再生的细胞可持续分裂,并于３个月时长成２ ｍ ｍ 大小的愈伤组织。将该愈伤组织转移到附加玉米素０．５ ｍ ｇ／Ｌ和ＩＡＡ ０．１ ｍ ｇ／Ｌ的固体ＭＳ培养基上,分化出苗。试管苗经诱导生根,长成完整小植株     

土人参原生质体培养再生植株

分别由土人参（Ｔａｌｉｎｕｍ ｐａｎｉｃｕｌａｔｕｍ （Ｊａｅｑ．） Ｇａｅｒｔｎ．）组织培养再生苗的叶片和幼茎诱导的愈伤组织游离出原生质体．叶肉原生质体在培养中未能进行正常分裂,存活不过１ 周．愈伤组织原生质体在Ｐ４ 培养基中（Ｋ８ｐ＋ ２,４－Ｄ ０．２ ｍ ｇ／Ｌ＋ ＮＡＡ １．０ ｍ ｇ／Ｌ＋ ＺＴ ０．５ ｍ ｇ／Ｌ＋椰乳５０ ｍ Ｌ／Ｌ＋ 葡萄糖０．５ ｍ ｏｌ／Ｌ）培养３ ｄ 开始第一次分裂,培养７ ｄ 时分裂频率为３６．７％ ． 愈伤组织再生率在液体培养中为０．３１％ ,在双层培养中为０．３４％ ． 愈伤组织在含有较低浓度的６－ＢＡ 的分化培养基上分化出不定芽． 幼苗生根后移栽到花盆中继续生长,２～３个月后开花结实,长出粗壮的肉质根． 再生小植株在试管中继代培养２～３ 个月开花结实． 研究结果还表明∶（１）愈伤组织在液体培养基或增殖培养基中培养时间过长,或继代次数过多均不利于分化．（２）较低浓度的６－ＢＡ （０．５～０．７ ｍ ｇ／Ｌ）对愈伤组织的分化是合适的．（３）ＧＡ３ 对幼苗的发育有促进作用． （４）多效唑（ＭＥＴ）对土人参试管苗有明显的壮苗和壮根作用     

蜜环菌对锌的耐性和富集特性

研究了锌对蜜环菌Armillaria mellea生长的影响,蜜环菌对于锌的耐性和富集特性,以及锌胁迫下蜜环菌的抗氧化酶的变化情况。结果表明,锌浓度45mg/L下对于蜜环菌菌体的生长有显著促进作用（p＜0.05）,锌浓度90mg/L以上时,蜜环菌菌体的生长受到抑制（p＜0.05）。蜜环菌的子实体萌发和子实体生物量在锌的浓度为45mg/L以下时与对照组无显著性差异（p＞0.05）,锌的浓度超过90mg/L后子实体不能萌发。培养基锌含量在270mg/L以下时,皮壳状菌丝中锌的含量随培养基中锌浓度的增大而增大。培养基锌含量在135mg /L以下时,菌索中锌的含量随培养基中锌浓度的增大而增大。随着培养基中锌浓度的提高,菌丝和菌索POD、CAT、SOD活性都有增加,PPO的活性则是先升高后降低,而且菌丝与菌索之间抗氧化酶活力有显著差异（p＜0.05）。     

蜜环菌对镁的耐性和富集特性

研究了镁对蜜环菌生长的影响, 蜜环菌对于镁的耐性和富集规律, 以及高浓度镁胁迫下蜜环菌的抗氧化酶的变化情况。3?15 g/L的Mg浓度对于蜜环菌菌体的生长有促进作用。Mg浓度19 g/L以上时, 蜜环菌菌体的生长受到抑制。蜜环菌的子实体形成和子实体生物量在Mg的浓度为11 g/L以下时不受影响, 超过11 g/L则子实体不能萌发。皮壳状菌丝和菌索中Mg的含量随培养基中Mg浓度的增大而增大, 培养基Mg浓度达到16 g/L后, 菌丝、菌索中Mg的含量都不再上升。子实体对Mg的富集量比菌丝体小的多, 在培养基Mg浓度在9、10 g/L时, 子实体中Mg的含量与对照组有显著差异。随着培养基中Mg浓度的提高, 菌丝和菌索POD、CAT、SOD活性都有增加, 而且菌丝与菌索之间抗氧化酶活力的差异随着培养基中Mg浓度的提高而增大。     

石斛离体培养中ABA对诱导花芽形成的影响

由兰科植物铁皮石斛（Ｄｅｎｄｒｏｂｉｕｍ ｃａｎｄｉｄｕｍ Ｗａｌｌ．ｅｘ Ｌｉｎｄｌ．）种子诱导形成的愈伤组织,在光照下置于ＭＳ附加０．３ ｍ ｇ／ＬＮＡＡ 的培养基上繁殖,可以形成原球茎。将原球茎转入ＭＳ含２ ｍ ｇ／Ｌ ６－ＢＡ 和０．５ ｍ ｇ／ＬＮＡＡ 的培养基上,花芽形成频率为２７．０％ 。原球茎先在０．５ ｍ ｇ／ＬＡＢＡ的培养基上预培养１５ ｄ,再转入含２ ｍ ｇ／Ｌ６－ＢＡ 的ＭＳ培养基上培养,花芽形成频率明显提高,可达８４．４％ ,而且每株植株花的数目增加;但是在仅有ＡＢＡ 的ＭＳ培养基上培养的原球茎再生的植株未见花芽形成     

灵芝菌诱变育种与深层培养的研究

采用紫外线对灵芝菌进行了诱变处理,选育到一株高产菌株ＵＶ－６０Ｓ,其菌体干重达１３．１ｇ／Ｌ,粗多糖含量为６４０ｍｇ／Ｌ,分别比原菌株提高了２１．３％和３０．６％;并研究了培养基组成和培养条件对菌体生长的影响,优化了深层培养的工艺条件,使菌体产量与胞外多糖含量比优化前分别提高了１５．３％和１８．８％。     

大叶紫花苜蓿愈伤组织原生质体再生植株

大叶紫花苜蓿下胚轴诱导的愈伤组织在继代培养基上生长快速,易于分散。继代第１２ｄ的愈伤组织原生质体的得率为６．５×１０７／ｇ鲜重。原生质体培养基为ＳＨ基本培养基,含有１．０ｍｇ／Ｌ２,４－０、０．５ｍｇ／ＬＢＡ、２．０ｇ／ＬＣＨ、２％蔗糖、６％葡萄糖、５ｍｍｏｌ／ＬＭＥＳ,培养密度为１．０×１０５／ｍＬ。培养至第１２ｄ时的原生质体再生细胞植板率为３．７％。由原生质体形成的小愈伤组织在含２．０ｍｇ／Ｌ２,４－Ｄ的ＭＳ固体培养基上大量增殖。增殖的愈伤组织转移至２．０ｍｇ／Ｌ２－ｉｐ＋０．１ｍｇ／ＬＮＡＡ的Ｂ５培养基上,形成体细胞胚并发育成完整植株。     

菜心下胚轴原生质体培养和植株再生

以萌发３—４ 天（长约４ ｃｍ ）的菜心（Ｂｒａｓｓｉｃａ ｃａｍｐｅｓｔｒｉｓ ｖａｒ．ｐａｒａｃｈｉｎｅｓｉｓ）无菌苗苍白下胚轴为材料,酶解分离原生质体。经纯化的原生质体,在含０．５ ｍ ｇ／ＬＺＴ、０．５ ｍ ｇ／Ｌ２,４－Ｄ、１．０ ｍ ｇ／ＬＮＡＡ 和０．４ ｍ ｏｌ／Ｌ葡萄糖的Ｋ８ｐ 培养基中,进行微滴培养。在起始培养１４—１８小时,原生质体再生新的细胞壁。３６ 小时再生细胞开始第一次分裂。第三天分裂细胞频率可达３５％ 。培养第８—９ 天,可见含８—１６个细胞的小细胞团,植板率为１５％ —１８％ 。３ 周后将发育成直径为２ ｍ ｍ 的白色小愈伤组织,转到含０．３ ｍ ｇ／Ｌ ２,４－Ｄ并用ｇｅｌｒｉｔｅ半固化的培养基上,增殖成４—５ ｍ ｍ 直径的愈伤组织。在ＭＳ＋ ３．２（或１．６） ｍ ｇ／Ｌ ＢＡ＋ １．６（或０．８） ｍ ｇ／ＬＺＴ＋ ０．０１ ｍ ｇ／Ｌ ＮＡＡ＋ ０．１ ｍ ｇ／ＬＧＡ３ 和０．２％ 蔗糖的分化培养基上,获得芽的分化。切下约２ ｃｍ 长的芽苗,转移到含０．２ ｍ ｇ／ＬＩＡＡ 和２％ 蔗糖的培养基上,生根形成完整植株     

用改良苯酚品红染色液替代醋酸洋红染色液的研究

以往在动物遗传学实验“果蝇唾液腺染色体标本的制作和观察”中,采用醋酸洋红染色液对染色体染色。本文对用改良苯酚品红染色液替代醋酸洋红染色液对果蝇唾液腺染色体染色的问题进行了研究。结果表明,改良苯酚品红染色液对果蝇唾液腺染色体的染色效果与醋酸染洋红染色液的染色效果是相同的。而且用改良苯酚品红染色液还人提高工效,简易节约的优点。因此认为,在对果蝇唾液腺染色体染色中,用改良苯酚品红染色液替代酸酸洋红染色液     

Further Experiments with the Masson Trichrome Modification of Mallory's Connective Tissue Stain

Several dyes, notably ponceau 2R, azofuchsin 3B, nitrazine yellow, and Biebrich scarlet may replace imported “ponceau de xylidin” in the Masson ponceau acid fuchsin mixture. Of these Biebrich scarlet appears to be the best and may be used without acid fuchsin.

A mixture of equal parts of 5% solutions of phosphomolybdic and phosphotungstic acids is much superior to either acid alone and gives adequate mordanting in 1 minute at 22°C.

With the fast green modification, times in plasma and fiber stains can be reduced to 2 minutes each. With anilin blue a 4-minute plasma stain is required. One-minute final differentiation in 1% acetic acid is adequate.

Primary mordanting of formalin material may be accomplished by 5 minutes in saturated aqueous mercuric chloride or 2 minutes in saturated alcoholic picric acid. Three minutes washing in running water is required after these mordants.     

Red Food Coloring Stain: New,Safer Procedures for Staining Nematodes in Roots and Egg Masses on Root Surfaces

Acid fuchsin and phloxine B are commonly used to stain plant-parasitic nematodes in roots and egg masses on root surfaces, respectively. Both stains can be harmful to both the user and the environment and require costly waste disposal procedures. We developed safer methods to replace both stains using McCormick Schilling red food color. Eggs, juveniles, and adults of Meloidogyne incognita stained in roots with red food color were equally as visible as those stained with acid fuchsin. Egg masses stained with red food color appeared as bright-red spheres on the root surfaces and were highly visible even without magnification. Replacement of acid fuchsin and phloxine B with red food color for staining nematodes is safer for the user and the environment, and eliminates costly waste disposal of used stain solutions.     

A minor sialoglycoprotein of the human erythrocyte membrane

The sialoglycoprotein periodate fuchsin sulfite 2 has about 8% of the sialic acid contained in the sialoglycoproteins of the human erythrocyte membrane. This polypeptide appears to have an apparent monomeric molecular weight of 35,000, somewhat smaller than the monomer of the major sialoglycoprotein (periodate fuchsin sulfite 1) as judged by sodium dodecyl sulfate-polyacry lamide gel electrophoresis, and has frequently been confused with the monomer of the major sialoglycoprotein. Periodate fuchsin sulfite 2 is not labeled by the lactoperoxidase procedure in the intact cell, although it is accessible to neuraminidase and other hydrolases. On the other hand, this component can be labeled by lactoperoxidase on the cytoplasmic surface of open membranes or resealed ghosts. Thus, it is a trans membrane protein. Although most of the other transmembrane proteins of the human erythrocyte membrane are extracted from the membrane by 0.1% Triton X-100 in 7 mm phosphate buffer, pH 7.4, this component is not removed and may be a cytoskeletal component. Trypsin, chymotrypsin, and thermolysin peptides, as well as cyanogen bromide fragments, clearly indicate that the primary sequence of this polypeptide can be distinguished from dimeric or monomeric forms of the major sialoglycoprotein (periodate fuchsin sulfite 1).     

The role of paraldehyde in the rapid preparation of aldehyde fuchsin

Preparation of aldehyde fuchsin normally requires ripening for 3 to 5 days. By using a 5-fold excess of paraldehyde a fully potent aldehyde fuchsin can be prepared in 24 hr at room temperature. Aldehyde fuchsin prepared by both normal and accelerated ripening afforded comparable results, including selective staining of unoxidized pancreatic B cells. Dried aldehyde fuchsin prepared form pararosaniline and reconstituted in acid alcohol has spectrophotometric properties different form the ripened strain. Reconstituted aldehyde fuchsin stains unoxidized B cells adequately only if staining time is extended. Excess paraldehyde added to reconstituted aldehyde fuchsin retards decomposition but does not produce a normal stain by spectrophotometric standards. Warming of aldehyde fuchsin solutions to accelerate ripening has been shown to produce deleterious effects and should be avoided.     

A new fluorescent staining method for callose of microspore mother cells during meiosis

To observe the dynamic behavior of callose of microspore mother cells during meiosis, we developed a convenient, rapid and efficient staining method using an improved carbol fuchsin/aniline blue solution. The stained microspore mother cells during meiosis showed yellowish green callose, red cytoplasm and dark red chromosomes when excited with blue light, which produced a contrasting image with a three-dimensional effect. When stained with only improved carbol fuchsin solution, the cells had red cytoplasm and chromosomes when excited with green light. The improved carbol fuchsin solution can be used to replace other more expensive DNA-specific dyes, such as DAPI and H33258, to reduce experimental costs.     

A new fluorescent staining method for callose of microspore mother cells during meiosis

To observe the dynamic behavior of callose of microspore mother cells during meiosis, we developed a convenient, rapid and efficient staining method using an improved carbol fuchsin/aniline blue solution. The stained microspore mother cells during meiosis showed yellowish green callose, red cytoplasm and dark red chromosomes when excited with blue light, which produced a contrasting image with a three-dimensional effect. When stained with only improved carbol fuchsin solution, the cells had red cytoplasm and chromosomes when excited with green light. The improved carbol fuchsin solution can be used to replace other more expensive DNA-specific dyes, such as DAPI and H33258, to reduce experimental costs.     

Acid Fuchsin as a Stain—A Refinement in Manufacture

From the study of 38 samples of acid fuchsin prepared from several types of basic fuchsin and under varying conditions it is found that rosanilin sulfonated between 80° and 85°C. gives the best results in the Van Gieson staining technic. Staining tests also show that a satisfactory acid fuchsin will give the best results when employed with picric acid in the ratio of 1 part of the 1 per cent aqueous acid fuchsin to 20 parts of the aqueous picric acid. Details for the preparation and use of acid fuchsin are given.     

Acid Fuchsin as a Stain—A Refinement in Manufacture

From the study of 38 samples of acid fuchsin prepared from several types of basic fuchsin and under varying conditions it is found that rosanilin sulfonated between 80° and 85°C. gives the best results in the Van Gieson staining technic. Staining tests also show that a satisfactory acid fuchsin will give the best results when employed with picric acid in the ratio of 1 part of the 1 per cent aqueous acid fuchsin to 20 parts of the aqueous picric acid. Details for the preparation and use of acid fuchsin are given.     

A Consideration of French's Test of Basic Fuchsin for Endo's Medium

In describing a method of testing for the return of color in decolorized fuchsin for use in Endo Medium, French states that variations in hydrogen ion concentration fail to influence the appearance of color in this medium.

Duplications of this test were made using alcoholic and aqueous solutions of fuchsin and both sodium sulfite and sodium bisulfite as decolorizing agents.

In the decolorized alcoholic solutions of fuchsin the color failed to reappear when formalin was added, but a small amount of a weak solution of lactic acid caused the color to return.

Alcoholic solutions of fuchsin failed to decolorize in sodium bisulfite solutions until a few drops of NaOH were added. The color, then, reappeared immediately.

Solutions of peptones to which fuchsin had been added were substituted for the original fuchsin solution. Alcoholic and aqueous solutions of fuchsin were added to equal amounts of a 1% peptone solution. The peptone solutions varied in their hydrogen ion concentration and the results showed that those which were neutral decolorized readily while the more acid solutions were but partially decolorized.

Fuchsin decolorized according to results found in this test, was not satisfactory in the Endo medium, especially in the case of the aqueous solutions of fuchsin.

Experiments which were carried on by other workers and checked with this method all indicated that some acid is necessary to secure the restoration of color.