烟草叶片、花萼等在组织培养中形态发生的细胞组织学研究

烟草叶片、花萼、叶柄在附加2mg/L BA和0.1mg/L NAA的MS培养基上,具高诱导率和分化率。本文着重观察了这三类外植体启动时的细胞形态及器官发生过程。发现表皮细胞、叶肉细胞和各处薄壁细胞均可启动,含有叶绿体的同化组织一般在2—3天普遍启动,被启动细胞脱分化形成分生型胚性细胞,并进入细胞分裂周期,分裂面一般不规则,以后形成分生细胞团。叶片、叶柄中有些分生细胞团可直接分化为不定芽;不定芽数量多,密集成芽丛;分化速度快,一般10—15天,花萼经愈伤组织阶段,分化速度较慢,约25天,芽亦少。观察了三者形态发生的过程,一般芽为外起源,少数为内起源;根一般为内起源。从细胞启动到芽原基形成均有淀粉积累,以叶片最明显,芽形成后淀粉逐渐消失。     

八角莲组织培养的器官发生途径研究

为探究小檗科植物八角莲组织培养的器官发生方式,该研究以八角莲离体叶片、叶柄在MS培养基上诱导产生的愈伤组织、不定芽、不定根为对象,用连续石蜡切片技术分析八角莲组织培养的器官发生途径。结果表明:八角莲愈伤组织形成的解剖学特征是靠近表皮的薄壁细胞经激素刺激恢复分裂能力,继续培养形成拟分生组织。拟分生组织可形成许多分化中心。通过对八角莲组织培养产生的不定芽细胞组织学观察发现芽原基起源于愈伤组织外侧的几层薄壁细胞,芽原基背离愈伤组织中央生长形成不定芽,故八角莲脱分化形成的芽起源方式为外起源。而八角莲的根原基起源于组织深处髓部薄壁细胞和部分维管形成层细胞,进而形成类似球形或楔形并朝韧皮部突起的根原基轮廓,根原基继续发育会突破表皮生成不定根,起源方式为内起源。八角莲离体再生途径为器官发生型,在组培苗生长过程中先诱导形成不定芽,再诱导形成不定根,在愈伤组织上形成维管组织将不定芽和不定根连接成完整植株。     

屋顶长生草叶的解剖结构及其离体培养形态发生的研究

对屋顶长生草叶的解剖结构及其在离体培养条件下形态发生过程进行了研究。结果表明,屋顶长生草的叶具有肉质旱生植物叶的特点,表皮细胞外有角质层,叶有较密的腺毛分布,气孔器由两个肾形的保卫细胞和两个镰刀形的护卫细胞组成;叶肉细胞没有栅栏组织与海绵组织之分,细胞比较大,有贮水作用;维管束平行排列,导管和筛管分子都很小,为一圈维管束鞘所包围。屋顶长生草叶片离体培养形态发生途径主要有两种:一种是由外植体直接产生不定芽(器官型)途径;另一种是叶肉细胞脱分化成胚性细胞,经胚性细胞团形成愈伤组织,再分化产生芽、根等器官(器官发生型),芽分化为内起源。     

黄槐叶片培养过程中器官发生的研究

以黄槐（ＣａｓｓｉａｓｕｒａｔｔｅｎｓｉｓＢｕｒｍ．ｆ．）幼嫩叶片为材料,接种于ＭＳ＋ＮＡＡ１ｐｐｍ＋２,４－Ｄ１ｐｐｍ＋６－ＢＡ２ｐｐｍ的培养基上,诱导形成两种形态的愈伤组织,即致密愈伤组织与雪花状愈伤组织．将愈伤组织转移到ＭＳ＋ＮＡＡ：１ｐｐｍ＋６－ＢＡ２ｐｐｍ的分化培养基上．仅致密型愈伤组织经过球状体至不定芽途径形成大量再生植株。扫描电镜及组织细胞学观察表明,致密愈伤组织表层细胞排列紧密,有许多分生细胞团,而雪花状愈伤组织表层细胞薄壁化,分裂能力很低。球状体起源于致密愈伤组织表层的分生细胞团,其细胞有极强的分生能力,顶端可以分化发育成不定芽原基,最后形成不定芽并发育成小植株。球状体可以看成是具有形成不定芽能力的繁殖单位．     

油橄榄(Olea europaea L.)组织培养的细胞组织学研究 Ⅱ.组织分化和器官发生

油橄榄愈伤组织转入分化培养基进行继代培养后,在它外围部分的局部表面可以由愈伤形成层发生周皮。同时在它内部有星散的管胞和维管束分化,这些维管组织并不构成维管系统,与器官发生无任何联系。此外,愈伤组织内有由薄壁细胞不规则地发生胚性细胞,它具有分生细胞的性质,以它不同的细胞分裂形式,产生两种分生组织的结构,即分生细胞团和分生组织结节。分生组织结节形成生长中心而无任何分化,但可分化为维管组织结节,它有以形成层状细胞围绕着许多管胞的结构,在它具有单向极性时,从它发育成根原基,而芽原基则由愈伤组织近表面的分生细胞团分化形成。并初步观察到在愈伤组织中有再次胱分化的过程。对维管组织结节在构造上的差异和根与芽的起源问题,根据观察结果作了简要的讨论。     

金鱼草愈伤组织过氧化物酶活性及其同工酶变化

在不同激素比例的MS培养基上 ,金鱼草 (Antirrhinummajus)茎愈伤组织主要有三种分化状态 :a愈伤组织不分化 ;b以器官发生途径分化出不定芽和不定根 ;c通过胚胎发生途径形成胚状体。过氧化物酶活性与愈伤组织分化程度呈正相关。未分化愈伤组织与分化芽、分胚状体及分化芽和根的愈伤组织酶活性呈线性递增关系 ,相对酶活力为 1:3:5 :6。在其同工酶谱中 ,三种状态的愈伤组织都具有酶带I和II,表明这两种同工酶与细胞的增殖生长有联系。分化的愈伤组织比未分化愈伤组织多出现酶带Ⅲ、Ⅳ和Ⅴ ,说明这三条酶带是影响分化的特异蛋白质。在分化芽的愈伤组织中 ,还存在酶带Ⅳ ,说明它是催化器官发生途径的特有同工酶。     

金鱼草愈伤组织过氧化的酶活性及其同工酶变化

在不同激素比例的MS培养基上,金鱼草（Antirrhinum majus）茎愈伤组织主要有三种分化状态：a愈伤组织不分化;b以器官发生途径分化出不定芽和不定根;c通过胚胎发生途径形成胚状体。过氧化物酶活性与愈伤组织分化程度呈正相关。未分化愈合组织与分化芽,分胚状体及分化芽和根的愈伤组织酶活性呈线性递增关系,相对酶活力为1：3：5：6。在其同工酶谱中,三种状态的愈伤组织都具有酶带和Ⅰ和Ⅱ,表明这两种同工酶与细胞的增殖生长有联系。分化的愈伤组织经未分化愈伤组织多出现酶带Ⅲ,Ⅳ和Ⅴ,说明这三条酶带是影响分化的特异蛋白质。在分化芽的愈伤组织中,还存在酶带Ⅳ,说明它是催化器官发生途径的特有同工酶。     

籼稻体细胞胚胎发生及器官发生的比较研究

在以幼穗为外植体的诱导培养及其以后的继代培养与悬浮培养中,从以下几个方面对３个籼稻品种的体细胞胚胎发生（Ｅ）与器官发生（Ｏ）的特点作了比较研究．在形态上,（Ｅ）型愈伤由胚状体组成,具有层次分明的结构．胚状体由胚芽、胚根及盾片组成．而（Ｏ）型的愈伤没有上述组织的分化．没有层次结构。植株再生能力方面．与器官发生途径相比较,体细胞胚胎发生途径之分化频率高．保持再生能力持续的时间长．从每个愈伤上发生的再生植株数多．（Ｏ）型愈伤结构较疏松．建立结构良好的、细胞团较小的悬浮细胞系容易．但这种细胞系在液体条件下几乎丧失再生能力．而（Ｅ）型愈伤则相反．建立好的悬浮细胞系．需要时间较长．但在悬浮条件下仍然具有再生植株的能力。在诱导条件方面．２,４－Ｄ及激动素分别作用时可诱导器官发生,共同作用时则诱导体细胞胚胎发生．再生植株途径方面,由于水稻同时具有器官发生及体细胞胚胎发生的特点．无论在诱导条件上还是在（Ｅ）与（Ｏ）本身的特点上均不似萝卜或烟草那样专一．并且有（Ｅ）与（Ｏ）相互转化和混合发生的复杂情况．     

天仙子(Hyoscyamus niger)花粉的胚胎发生与器官发生

天仙子花粉在附加不同浓度NOA的BN培养基中,形态发生能力不同,低浓度易由花粉直接形成胚状体,高浓度一般先形成愈伤组织,再由愈伤组织分化胚状体或根芽。实验表明,直接起源于花粉的胚状体与经花粉愈伤组织形成的胚状体,其胚胎发生的模式和顺序相同,均由原胚、球形胚、心形胚、鱼雷期胚到子叶期胚,但二者原胚的起源不同。花粉愈伤组织亦可经器官发生途径产生根芽。     

扫描电镜下的器官发生——植物胚状体和不定芽的分化(封二说明)

在离体培养条件下,植物组织的器官分化基本可分为不定芽发生及胚状体(体细胞胚)发生这两大主要类型。它们既可以从外值体(即接种材料)的表面直接发生,也可以由外植体经脱分化后形成愈伤组织,由愈伤组织再分化而产生。 封二,图1、2,为刺五加(Acanthopanaxsenticosus)的胚接种在MS 2,4-D0.5ppm培养基上1—2个月后,由子叶及胚轴直接分化出大量胚状体的情况。胚状体的分化是不同步的,     

Histological study of callus formation and root regeneration from mung bean (Vigna radiata W.)

We have established a reproducible culture system for callus formation and root development from juvenile stem segments of mung bean(Vigna radiata). In particular, we have studied the influence of plant growth regulators. Induction of calli from young stem explants was very effective on MS inorganic salts supplemented with 0.5 mg/L 2,4-D and 1.0 mg/L kinetin. In regenerating adventitious roots from callus tissues, we found that a combination of 0.75 mg/L NAA, 1.5 mg/L kinetin, and MS salts resulted in 20% efficiency. Histological examination showed that callus tissues originated from out-growths of the cambium rings through de-novo meristematic activity. Those rings were localized outside the vascular cambium. Adventitious roots that developed from root primordia originated from the center of the Callus masses. These primordia produced tracheid-like cells, which then became meristemoid cells for the cambium. Newly formed adventitious roots had the typical tetrarche actinostele type.     

Histological comparison of single somatic embryos of maize from suspension culture with somatic embryos attached to callus cells

An embryogenic suspension culture of Zea mays, genotype 4C1, was obtained from friable callus that was cultured on solid medium and had been obtained from zygotic embryos. The suspension contained non-dividing elongated cells, clusters of dividing isodiametric cells, and globular, ovoid, and polar stages of somatic embryos. The single somatic embryos were blocked in shoot meristem formation: when transferred to regeneration medium they developed a root and, at the shoot side, a green cap with meristematic cells, but a scutellum and leaf primordia were not formed. In medium containing 2,4-dichlorophenoxy acetic acid, somatic embryos formed embryogenic callus aggregates, consisting of globular stage somatic embryos attached to each other via undifferentiated callus cells. These somatic embryos developed into mature embryos with the zygotic histological characteristics, such as scutellum and leaf primordia, in maturation medium, and then regenerated into plants in regeneration medium. By omitting the maturation phase, regeneration occurred via organogenesis. Polyembryos, i. e. embryos attached to each other without callus tissue in between, behaved as single somatic embryos. It is concluded that the attached callus tissue provides a factor that stimulates scutellum and leaf primordia formation.Abbreviations CMM callus maintenance medium - 2,4D 2,4-dichlorophenoxy acetic acid - PCV packed cell volume - MS Murashige and Skoog medium     

ADVENTIVE ORGANOGENESIS FROM SOMATIC TISSUE CULTURES OF SOLANUM CAROLINENSE: ORIGIN AND DEVELOPMENT OF REGENERATED PLANTS

The development of adventitious shoot formation from cultured somatic tissues of Solanum carolinense was studied using light microscopy. For purposes of comparison, callus initiation and proliferation were also followed. When stem segments of this plant were cultured on medium supplemented with 6 mg/l benzyladenine (BA), cell division was first observed after 48 hr in the external phloem and inner cortex of the segments. This division activity gave rise to meristematic zones which subsequently formed shoot primordia within 6 days of culture. While organogenic potential appears to be limited to specific regions, all tissues of the explant were capable of callus formation when cultured on medium containing 3 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D). In conjunction with a previous study, it appears that unlike somatic embryogenesis in this species, organogenesis does not require an intermediate callus phase for differentiation to occur.     

Histological Aspects of Root Formation in Petioles of Detached Leaves of Pereskia grandifolia (Cactaceae): Natural Conditions and Effects of GA3 and Dark

Adventitious roots arise naturally on petioles of Pereskia grandifoliaHaw. held in light. At about the 12th day after the beginningof the experiment, the root primordia arise in a callus tissuedeveloped from the basal portion of the petiole. Associatedwith the development of the callus, noticeable structural changesoccur in the originating organ. Petioles maintained in darkalso form callus; however, they die in a few days. On the otherhand, petioles treated with GA,, maintained in light, developcallus and survive; but they do not give rise to roots. Someaspects are discussed, such as: the kind of origin observedfor the roots, and the possible physiological basis for theirformation, as wdl as for the inhibition of their appearance Pereskia grandifolia, adventitious root formation, gibberelljc acid, petiole structure, rooting     

Studies on Root Regeneration from Anther derived Spear of Asparagus officinalis

There were two different stages during the root regeneration from the anther derived spear of Asparagus officinalis L. c v. Marry Washington 500, the root primordia differentiation, and the development stage of root primordia into young root. Differentiation of root primordia was enhanced by amplified nutrient supplement and lowered NAA concentration, both of which were favorable to callus formation and sustained decrease of endogenous ABA at the transection of the base of the spear. Moreover, further development of the root primordia was promoted by appropriate limitation of water supply and by effective aeration.     

Tissue Culture of Maize I. Callus Induction and Growth

Callus induction and subculture was successful with mature embryos and stem sections of seedlings of Zea mays L. on Linsmaier and Skoog's medium modified to contain 4 mg/I of 2,4-D and 1 g/I of casamino acids. — 2,4-D was superior to NAA and IAA for both callus induction and growth. Callus subcultured on NAA formed abundant roots on agar-solidified media and numerous root-like primordia in liquid cultures. — Kinetin had no effect on callus induction in the presence of 2,4-D and neither kinetin nor gibberellic acid stimulated callus growth during subculture. — Callus grew equally well on the medium of Linsmaier and Skoog, that of Schenk and Hildebrandt, and the B-5 medium of Gamborg and Eveleigh containing 2% sucrose, 4 mg/I of 2,4-D and 1 g/I of casamino acids. — The callus grew more rapidly at 25°C than at 30°C or 35°C. Little difference was noted at any temperature in callus growth in alternating light (16 h) and dark (8 h) or continuous dark. — Sucrose was superior to glucose and maltose in both liquid and agar-solidified cultures. Lactose and galactose failed to support callus growth.     

Effect of Chlorsulfuron on Morphogenetic and Disordered Cell Division in Cultures of Passiflora edulis

We examined the effects of a sulfonylurea herbicide, chlorsulfuron, which is known as a potent inhibitor of plant cell division, on morphogenetic cell division and disorganized cell division using the culture system of multiple shoot primordia and callus of Passiflora edulis. The multiple shoot primordia tissue treated with chlorsulfuron failed to achieve shoot morphogenesis, and a large part of the tissue was necrotized during the posttreatment culture, even when it was washed and transferred to chlorsulfuron-free medium. The inhibition of Passiflora shoot morphogenesis by chlorsulfuron was not reversed by the simultaneous addition of branched amino acids, which are known to reverse the inhibitory effect of chlorsulfuron. In contrast, the same treatment of chlorsulfuron on the callus did not kill the cells, although the growth resumption was retarded by a prolonged lag period. The addition of branched amino acids enhanced the recovery growth of the chlorsulfuron-treated callus. These results suggest that the inhibition of disorganized cell division (callus growth) by chlorsulfuron is reversible, whereas morphogenetic cell division (shoot morphogenesis), which is under complex regulation, is inhibited irreversibly by chlorsulfuron. Qualitative differences between morphogenetic cell division and disordered simple proliferative cell division are discussed. Received November 17, 1997; accepted June 4, 1998     

Structure and development of adventitious roots in Salix caprea and S. caprea × S. viminalis

Formation and structure of adventitious roots in cuttings of two clones of S. caprea and a hybrid betwen S. caprea and 5. viminalis was studied with light microscopy (LM) and transmission electron microscopy (TEM). The hybrid contained large preformed root primordia, which in cuttings placed in water developed into roots in only three days. One of the S. caprea clones contained minute preformed root primordia, which developed into roots in about eight days. Treatment with indolebutyric acid (IBA) increased the percentage of rooted cuttings and the number of roots formed. Roots emerging from IBA-treated cuttings contained both mature protophloem and protoxylem, while in roots of untreated cuttings only some sieve elements of the protophloem were mature. In the other 5. caprea clone no preformed root primordia were detected, but after treatment with IBA roots appeared in about two weeks. The cambium in treated stems produced a large number of cells, most of which differentiated into xylem. Root primordia were initiated in the newly produced tissue external to the cambium. The roots contained both mature protophloem and protoxylem at emergence. A few roots emerged also from extensive callus tissues formed external to the basal end of the cuttings. Cell enlargement and cell divisions in various parts of the base of the cuttings caused disruption of the peripheral tissues, which made the cuttings susceptible to infection by microorganisms.     

Shoot regeneration of hybrid seed geranium (Pelargonium x hortorum) and regal geranium (Pelargonium x domesticum) from primary callus cultures

Procedures have been developed that increase the rate of shoot regeneration of hybrid seed geranium from month-old primary callus cultures. Hybrid geranium callus tissue covered with green nodular structures was initiated by placing shoot tip explants on solidified Murashige & Skoog medium (MS) supplemented with 2.0 mgl^-1 zeatin and 1.9 mgl^-1 indoleacetic acid. Hybrids Red Orbit, White Orbit and Scarlet Orbit were shown to produce 5–50 shoot primordia per explant when callus was initiated on this medium. Regal geranium callus was initiated by placing leaf explants on MS medium supplemented with 2.0 mgl^-1 6-benzylaminopurine and 2.0 mgl^-1 naphthaleneacetic acid. Regal geranium cultivars Tiny Tot and Lavender Grand Slam were shown to produce between 2–50 shoot primordia per explant when initiated on the same medium.     

Cytohistological Studies on the Tissue Culture of Olea europaea L. II. Histogenesis and Organogenesis

After the calli derived from Olea europaea stem tissue have been introduced to the subculture on the solid medium for differentiation, a periderm was partially formed from the wound cambium in the outer region of the callus. At the same time, some scattered tracheids and vascular bundles were differentiated in the inside of the callus. These vascular bundles did not form a vascular system and also had no rela- tion to the organogenesis. In addition, there were some embryonic cells induced at random from parenchymatous cells in the callus, and these embryonic cells were characterized as the meristematic cells. Two types of meristematic tissues, namely, meristematic cellular mass and meristematic nodule, were produced by different types of mitotic division respectively. The meristematic nodules formed a growth center without any differentiation, but later, they were differentiated tracheids in the inner surrounded by the cambium-like cells. With monopolarity the root primordia were produced from this type of nodules. But the adventitious buds were derived from the meristematic cellular masses. Therefore, realize that the process of differentiation and dedifferentiation all occurs in the callus tissue. The structural differences among the nodules with tracheids, and the origin of buds and root primordia are also briefly discussed.