The Effect of Ageing on Bud Differentiation in the Moss, Physcomitrium sphaericum

In the moss Physcomitrium sphaericum, we examined the numberof buds per filament, the position of buds, and the ratio ofbud-differentiated filaments when treated with cytokinin, inrelation to the increase in the number of cells per filament. When filaments of a young protonema were treated with cytokinin,many filaments did not differentiate buds. As the number ofcells in a filament increased, both the mean number of budsper filament and the ratio of bud-differentiated filaments increased.However, the position of bud differentiation was unaffectedby application of cytokinin. A higher concentration of cytokininincreased the mean number of buds per filament and the ratioof bud-differentiated filaments. The relationship between cytokinin, ageing of filaments andthe ability to differentiate buds is discussed. (Received June 17, 1985; Accepted September 9, 1985)     

Relationship between the Growth Rate of a Filament and the Ability to Differentiate a Bud in the Moss, Physcomitrium sphaericum

Protonemata filaments of the moss Physcomitrium sphaericum displaygrowth rates that change remarkably before they differentiatebuds under normal conditions, that is, without cytokinin treatment.Before bud differentiation occurred, the growth rate of thefilament first decreased to a minimum and then increased toa maximum and decreased again. Study of whether the change inthe growth rate is related to bud differentiation showed thatbud differentiation was closely related to the maximum growthrate and the fluctuation range, that is, the difference betweenthe minimum and the succeeding maximum growth rate. The frequencyof bud-differentiated filaments increased as both the maximumgrowth rate and the fluctuation range of growth rate increased.Examination of the relationship between the time of cytokininapplication and the frequency of bud-differentiated filamentsshowed that the cytokinin treatment given at the time when thegrowth rate increased was most effective to induce buds. Therelationships between cytokinin, growth rate of filaments andthe ability to differentiate buds are discussed. (Received September 17, 1985; Accepted March 13, 1986)     

Aspects of the Differentiation of the Egg of the Moss Physcomitrium coorgense Broth

Oogenesis in Physcomitrium coorgense follows the course seenin lower archegoniates generally. However no evidence was foundof cytoplasmic autophagy, or, during maturation of the egg,of nucleo-cytoplasmic interaction of the kind reported in liverwortsand ferns. The internal lamellar system of the plastids dedifferentiatesalmost entirely, and there is a corresponding increase in thefrequency of osmiophilic droplets. Starch also disappears, andsimultaneously large quantities of mucilage appear in the cytoplasm.The mucilage is secreted into the venter of the archegoniumand envelopes the egg. The egg lacks a special osmiophilic membrane.     

The Morphology of Protonema and Bud Formation in the Bryales

The development of protonema from spore in aseptic culture wasfollowed in species representing 14 genera and 7 orders of theBryales. In no case could a distinction be made between sharplydefined ‘chloronema’ and ‘caulonema’stages. In all species, with the exception of the anomalous Cinclidotusfontinaloides, the protonema developed a markedly heterotrichoushabit, with prostrate filaments of relatively unlimited growthand erect filaments of more restricted development. The twotypes of filament were usually distinct in cellular characteristicsas well as in the direction of growth. In some cultures a thirdtype of filament grew downwards into the medium. Shoot buds were found to occupy diverse positions in differentspecies, but the commonest position was near the base of a primaryfilament of the erect branch system. Shoot buds were formedas readily in artificial light of sufficient intensity as innatural daylight.     

Endogenous Diterpenes Derived from ent-Kaurene,a Common Gibberellin Precursor,Regulate Protonema Differentiation of the Moss Physcomitrella patens

Gibberellins (GAs) are a group of diterpene-type plant hormones biosynthesized from ent-kaurene via ent-kaurenoic acid. GAs are ubiquitously present in seed plants. The GA signal is perceived and transduced by the GID1 GA receptor/DELLA repressor pathway. The lycopod Selaginella moellendorffii biosynthesizes GA and has functional GID1-DELLA signaling components. In contrast, no GAs or functionally orthologous GID1-DELLA components have been found in the moss Physcomitrella patens. However, P. patens produces ent-kaurene, a common precursor for GAs, and possesses a functional ent-kaurene synthase, PpCPS/KS. To assess the biological role of ent-kaurene in P. patens, we generated a PpCPS/KS disruption mutant that does not accumulate ent-kaurene. Phenotypic analysis demonstrates that the mutant has a defect in the protonemal differentiation of the chloronemata to caulonemata. Gas chromatography-mass spectrometry analysis shows that P. patens produces ent-kaurenoic acid, an ent-kaurene metabolite in the GA biosynthesis pathway. The phenotypic defect of the disruptant was recovered by the application of ent-kaurene or ent-kaurenoic acid, suggesting that ent-kaurenoic acid, or a downstream metabolite, is involved in protonemal differentiation. Treatment with uniconazole, an inhibitor of ent-kaurene oxidase in GA biosynthesis, mimics the protonemal phenotypes of the PpCPS/KS mutant, which were also restored by ent-kaurenoic acid treatment. Interestingly, the GA₉ methyl ester, a fern antheridiogen, rescued the protonemal defect of the disruption mutant, while GA₃ and GA₄, both of which are active GAs in angiosperms, did not. Our results suggest that the moss P. patens utilizes a diterpene metabolite from ent-kaurene as an endogenous developmental regulator and provide insights into the evolution of GA functions in land plants.GAs are a large family of tetracyclic diterpenoids, and bioactive GAs play crucial roles in aspects of plant growth and development, including seed germination, stem elongation, leaf expansion, trichome development, and flower and fruit development (Olszewski et al., 2002). GAs are biosynthesized from ent-kaurene, the key intermediate of the GA biosynthetic pathway (Olszewski et al., 2002; Yamaguchi, 2008; Fig. 1). ent-Kaurene is synthesized via sequential cyclization steps of geranylgeranyl diphosphate (GGDP) by ent-copalyl diphosphate synthase (CPS; Sun and Kamiya, 1994) and ent-kaurene synthase (KS; Yamaguchi et al., 1996, 1998). The bioactive GAs (GA₁ and GA₄) are synthesized through a series of oxidation reactions of ent-kaurene by two types of oxidases. Both ent-kaurene oxidase and ent-kaurenoic acid oxidase are cytochrome P450 monooxygenases that successively convert ent-kaurene to GA₁₂. GA₁₂ is further converted to bioactive GAs by two 2-oxoglutarate-dependent dioxygenases, GA 20-oxidase and GA 3-oxidase (Phillips et al., 1995; Olszewski et al., 2002; Yamaguchi, 2008; Fig. 1). GA 2-oxidase is another member of the 2-oxoglutarate-dependent dioxygenase family and is responsible for GA inactivation (Fig. 1). The active GAs can bind to the soluble GA receptor, GID1, and promote the interaction of GID1 with DELLA repressors, which are negative regulators of GA signaling (Ueguchi-Tanaka et al., 2005; Nakajima et al., 2006). This GA-promoted GID1-DELLA interaction triggers the degradation of DELLA repressors via the SCF^GID2/SLY1 proteasome pathway and consequently activates GA signaling (Ueguchi-Tanaka et al., 2007).Open in a separate windowFigure 1.The biosynthetic pathway of GA. The enzyme names are shown in boldface below or to the right of each arrow. AMO-1618 is an angiosperm inhibitor of CPS. Uniconazole, a GA biosynthesis inhibitor, blocks ent-kaurene oxidase activity. GA₁ and GA₄ are the bioactive GAs, and GA₈ and GA₃₄ are their inactive catabolites, respectively. KAO, ent-Kaurenoic acid oxidase.In nonseed land vascular plants, auxin, cytokinin, and abscisic acid function as regulators of plant growth and development (Chopra and Kumra, 1988; Raghavan, 1989). Various physiological responses to these phytohormones are investigated in nonseed land plants, especially in the model moss Physcomitrella patens (Cove et al., 2006). Auxin and cytokinin function in developmental phase changes of chloronemata, caulonemata, and gametophores as well as in cellular growth regulation in P. patens (Imaizumi et al., 2002; Sakakibara et al., 2003; Decker et al., 2006). Abscisic acid mediates the establishment of tolerance to dehydration, cold temperature, and osmotic stresses in P. patens as in angiosperms (Decker et al., 2006; Cho et al., 2009; Khandelwal et al., 2010). In contrast to these hormones, there are only a few studies on the physiological activity of GA in mosses (Von Maltzahn and Macquarrie, 1958; Chopra and Mehta, 1987; Vandenbussche et al., 2007), and the GA function and signaling pathways are still unclear.Recent progress in plant molecular biology and chemical analysis of GA revealed the biosynthesis, perception, and signaling of GA in P. patens and the lycopod Selaginella moellendorffii (Hirano et al., 2007; Vandenbussche et al., 2007; Yasumura et al., 2007). Genome sequence for these organisms has enabled the identification of genes orthologous to flowering plant genes encoding GA biosynthetic enzymes and GA signaling components involved in the GID1-DELLA pathway (Hirano et al., 2007; Vandenbussche et al., 2007). Recently, two reports demonstrated that GID1-DELLA-mediated signaling is functionally conserved in the fern Selaginella and in angiosperms (Hirano et al., 2007; Yasumura et al., 2007). GA-dependent protein-protein interactions were observed between SmGID1 and SmDELLA proteins, the S. moellendorffii proteins orthologous to the rice (Oryza sativa) GID1 and DELLA proteins, respectively. The introduction of either the SmGID1a or SmGID1b gene rescued the rice Osgid1-3 mutant, and the overproduction of SmDELLA1 suppressed GA action in the wild-type background. These reports indicate that the GID1 and DELLA proteins function similarly in S. moellendorffii and in angiosperms. Additionally, S. moellendorffii has functional GA biosynthetic enzymes similar to the angiosperm GA 20- and GA 3-oxidases and endogenous active GA₄ detected by liquid chromatography-tandem mass spectrometry (LC-MS/MS) analysis. However, endogenous GAs were not detected in P. patens by LC-MS/MS analysis, and the putative P. patens GA oxidases did not show any enzymatic activity on the known substrate for the orthologous angiosperm GA oxidases (Hirano et al., 2007). Furthermore, the PpGID1-like and PpDELLA-like proteins did not interact in the presence of active GA in yeast cells, and the PpDELLA-like protein did not complement the rice DELLA function. These findings suggest that GID1-DELLA-mediated GA signaling evolved in the vascular plant lineage after bryophyte divergence (Hirano et al., 2008).GA₁ and GA₄ are recognized as major biologically active GAs in angiosperms. S. moellendorffii biosynthesizes GA₄ as an active GA. Additionally, the Schizaeaceae family of ferns utilize GA methyl esters (methyl esters of GA₉, GA₂₀, and GA₇₃) as regulators of antheridium development, whereas these GA methyl esters are inactive in angiosperms (Yamauchi et al., 1996, 1997; Kurumatani et al., 2001). The biologically active GAs present in angiosperms were not detected in P. patens (Hirano et al., 2007). Although diverse GA metabolites have been found in plants and fungi, all the GA metabolites are thought to be derived from ent-kaurene, a common intermediate in early GA biosynthetic steps in both land plants and fungi (Kawaide, 2006). In angiosperms, two separate enzymes (CPS and KS) are involved in ent-kaurene synthesis from GGDP via ent-copalyl diphosphate as a reaction intermediate (Fig. 1). We have reported that PpCPS/KS, catalyzing the direct cyclization of GGDP to ent-kaurene, was a bifunctional diterpene cyclase with both CPS and KS activities in a single polypeptide (Hayashi et al., 2006). This type of bifunctional ent-kaurene synthase was also found in GA-producing fungi but was not identified in angiosperms (Kawaide et al., 1997; Toyomasu et al., 2000). The P. patens genome contains a single CPS/KS homolog, and no diterpene cyclase gene was found on the basis of sequence similarity in this organism. Anterola et al. (2009) reported that AMO-1618, an inhibitor of CPS, suppressed spore germination in P. patens; the suppression was recovered by exogenous ent-kaurene application. These results led the authors to hypothesize a role for ent-kaurene in regulating spore germination (Anterola et al., 2009). However, the hypothesis should be examined because the AMO-1618 inhibitory effect was not fully recovered by ent-kaurene application, probably because of the unspecific inhibitory effect of AMO-1618 on spore germination (Anterola et al., 2009).To assess the biological role of ent-kaurene and its metabolites in P. patens, we performed an insertional knockout of the ent-kaurene synthase gene, CPS/KS, in P. patens; the loss of ent-kaurene production was confirmed by gas chromatography-mass spectrometry (GC-MS) analysis. We also determined the abundance of all possible GAs and their precursors in P. patens by LC-MS/MS analysis. The PpCPS/KS disruption mutant (Ppcps/ks KO) lines have a defect in protonemal development. The differentiation of chloronemata to caulonemata was suppressed in the Ppcps/ks KO mutants, and the defect was recovered by the exogenous application of ent-kaurene or ent-kaurenoic acid. Furthermore, the GA₉ methyl ester, an antheridiogen of schizaeaceous ferns, rescued the protonemal defect of the mutants, but GA₃ and GA₄, the representative active GAs for angiosperm, did not. Our results demonstrate that P. patens utilizes GA-type diterpenes synthesized from ent-kaurene as an endogenous growth regulator in protonemal development.     

An explanation of the intermittent occurrence of Physcomitrium sphaericum (Hedw.) Brid.

Abstract

The spasmodic temporal distribution of the rare ephemeral moss Physcomitrium sphaericum is described and an explanation of this unusual periodicity is proposed. Field observations over 44 years have established that the presence of P. sphaericum is closely correlated with periods of summer drought. Evidence from germination experiments and the discovery of a viable buried spore bank suggest that during drying out of mud exposed by drought, spores are unearthed and dormancy is broken by the action of light. It is suggested that these regenerative features, together with a compressed life cycle, enable success in a habitat where conditions for growth occur infrequently and are of a short duration.     

三种植物生长调节剂对密叶绢藓(Entodon challengeri)孢子萌发、原丝体发育及芽体发生的影响

研究了3种植物生长调节剂苯基噻二唑基脲(TDZ)、6-苄基腺嘌呤(6-BA)、萘乙酸(NAA)对密叶绢藓[Entodon challengeri(Paris)Cardot]孢子萌发、原丝体发育及芽体发生的影响,并对整个发育过程进行了显微观察和照相,结果表明:(1)3种植物生长调节剂对密叶绢藓孢子萌发影响不显著;(2)在原丝体发育阶段,1.0 mg/LNAA对原丝体初期的发育促进效果显著,0.4 mg/L TDZ对原丝体发育中期分枝的形成促进效果显著,6-BA处理效果不显著;(3)3种植物生长调节剂单独处理均促进芽体的发生,但0.4 mg/L TDZ效果最佳。而1.5 mg/L 6-BA+TDZ组合处理效果更加显著;(4)芽体的发生数量与芽体的长势无正相关性。     

N-(2-氯-4-吡啶基)-N'-苯基脲(CPPU)对无疣墙藓原丝体发育与芽体发生的影响

0.2、0.4、1.0及1.5mg·L-1 4个浓度的N-(2-氯-4-吡啶基)-N'-苯基脲(CPPU)对无疣墙藓的孢子萌发没有显著影响,但抑制绿丝体伸长和侧枝生成,对芽体的分化有明显的促进,且芽体发生数随浓度升高而增加.     

The Effect of Bud Position on Branch Growth and Bud Abscission in Quercus petraea (Matt.) Liebl.

The time at which a bud began to expand was related to its positionnot only on an individual shoot but also within the crown. Thedistribution of buds and branches on the shoot was uneven; theshoot tip, where they were densely clustered, was termed the'whorl; and the remainder of the shoot, where they were widelyspaced, the ‘interwhorl’ stem. In spring, the terminalbud started expanding before the ’whorl’ buds whichpreceded the ‘interwhorl’ stem buds; completionof the flush of growth, determined by the end of leaf expansion,occurred in the reverse order, ‘interwhorl’     

The Effect of Bud Position on Branch Growth and Bud Abscission in Quercus petraea (Matt.) Liebl.

The time at which a bud began to expand was related to its positionnot only on an individual shoot but also within the crown. Thedistribution of buds and branches on the shoot was uneven; theshoot tip, where they were densely clustered, was termed the‘whorl; and the remainder of the shoot, where they werewidely spaced, the ‘interwhorl’ stem. In spring,the terminal bud started expanding before the ‘whorl’buds which preceded the ‘interwhorl’ stem buds;completion of the flush of growth, determined by the end ofleaf expansion, occurred in the reverse order, ‘interwhorl’> ‘whorl’ > terminal. Similarly bud expansionstarted at the top of the crown and progressed downwards, andthe first shoots to complete their flush were at the bottomof the crown. Approximately 60% of the buds on each shoot beganexpanding in spring but only about half of these formed branches.Bud abscission began in May and by Sep. 45% of buds originallypresent had abscised. Most of-the buds that did not abscisewere the small buds at the base of the shoot that were not originallyassociated with a leaf. Approximately 42% of ‘whorl’buds and 28% of MnterwhorP stem buds formed branches. ‘Whorl’branches were approx. 60% longer that ‘interwhorl’stem branches; buds on the lower surface of the shoot producedlonger branches than those on the upper surface. The implicationsof the results for the development of crown form and selectionof superior oak are discussed. Quercus petraea, oak, buds, branches, crown form     

黄芩花芽形态分化研究

采用石蜡切片法和扫描电镜技术对黄芩花芽分化的过程进行了观察.结果表明,黄芩花芽分化进程可分为花芽未分化期、花序分化期、苞片和小花原基分化期、花器官分化期、花序形成期5个时期.同时发现主茎叶节数在20个之前为营养生长期,叶节数达29个左右时主茎花芽分化结束,不同位置的花序在分化进程上比上一级花序落后至少1个时期.     

黄花杓兰的花芽发育

对黄花杓兰（Cypripedium flavum P.F.Hunt et Summerh.）成年植株做了一个生长季的研究,提出了一年芽、二年芽和多年休眠芽的概念。指出由芽形成到植株开花需两年时间,其具体发育路线是：第一年6－7月份,根状茎顶端二年芽基部外侧有两个新的小芽产生,即“一年芽”,至9－10月份发育出7－9片幼叶,然后随气温下降停止生长;第2年4月份复苏,即为“二年芽”,二年芽在本生长季内发育成混合芽,但一般情况下只有一个充分发育,另一个未能充分发育并且一般将来也不再有发育的机会,被称为“多年休眠芽”;第3年5月份充分发育的二年芽长出地面,形成植株,迅速开花、结果,至9月底植株枯萎。本文还讨论了黄花杓兰发育过程与环境的关系。     

光皮树花芽分化过程中内源激素含量变化的研究

以4年生光皮树嫁接苗为材料,采用酶联免疫吸附法（ELISA）测定同龄开花光皮树与不开花光皮树叶内4种内源激素生长素（IAA）、赤霉素（GA3）、玉米核苷素（ZR）、脱落酸（ABA）含量的动态变化,研究成花过程中叶片内源激素含量的变化与成花的关系。研究结果表明：在芽分化时期开花光皮树和未开花光皮树叶内4种内源激素含量动态变化存在显著差异。有花芽分化的光皮树保持相对较低和稳定IAA、GA3含量,ABA含量高且变化幅度较大,ZR含量相对较低,但随着花的形成含量逐渐升高;而在相同的生长季内,无花光皮树IAA、GA3含量先升高后降低,ABA含量先逐渐升高,然后下降,而ZR含量呈现出先逐渐升高然后降低,再升高再下降的变化趋势。因此,4种内源激素含量的动态变化影响光皮树的成花过程。     

观赏植物花芽分化研究进展

花芽分化是有花植物发育中最为关键的阶段,同时也是一个复杂的形态建成过程。简要综述了植物花芽分化过程中形态结构、外部因子与内部因子的影响,以及花芽分化中花转变的顺序和基因对成花的作用,并对观赏植物花芽分化的展望与问题做了概述和探讨。     

舞钢玉兰芽种类与成枝成花规律的研究

报道了舞钢玉兰芽的种类、分枝习性与成枝生长规律,拟花蕾、着生位置、解剖结构及其分化发育成花规律。从中发现：（1）当年生枝上有休眠芽、叶芽（侧叶芽和顶叶芽）、拟花蕾3种;（2）拟花蕾有缩台枝、芽鳞状托叶、雏枝、雏芽及雏蕾组成,因其外形似“花蕾“,称为“拟花蕾“;（3）缩台枝是枝与花着生的中间过滤枝变阶段,是由母枝顶端节间缩短、增粗的枝段和当年由雏枝生长的1次极短新枝所组成;（4）4-5月及7-8月前后两批形成的拟花蕾,均经过未分化发育期、花被分化发育期、雄蕊群分化发育期及离心皮雌蕊群分化发育期,各期均依次递后交错进行,但不逆转,也不能截然分开,直到翌春花分化发育全部结束,开花后才能结实;（5）芽鳞状托叶是托叶的变态,最外层薄革质,外面密被短柔毛,始落期6月中下旬,其余纸质--膜质,外面密被或疏被毛柔毛,翌春开花时脱落完毕;（6）雏蕾有雏梗、雏花及包被雏花的佛焰苞状托叶组成;（7）分枝习性与成枝生长规律与预生分枝及预生一同生分枝呈单阶无歧、单阶1歧生长规律,稀有单阶2歧生长规律。     

The Moss, Physcomitrella patens

   apd: 9 March 2001     

Regulation of a Sub-sexual Life Cycle in a Moss: Evidence for the Occurrence of a Factor for Apogamy in Physcomitrium

As demonstrated in our earlier studies, the differentiationof apogamous sporophytes on the secondary protonema of the mossPhyscomitrium pyriforme Brid. requires an exogenous supply ofsucrose in the medium. In the present work, similar differentiationwas observed in the leaf cells of aged gametophytes. The experimentsindicate an accumulation in the leaves of a sporophytic factorwhich initiates a de novo differentiation of sporophytes fromleaf cells without the intervention of sexual reproduction.In the absence of sucrose, the factor for apogamy was not present.Highlight intensity (5000–6000 lx) also inhibited itsproduction. There was no evidence that its presence interferedwith or inhibited production of gameto-phores. Growth regulatorssuch as IAA and kinetin altered only the effectiveness of thissporophytic factor, demonstrating that it was endogenous. Sporogenesisin the apogamous sporophytes took place without orthodox meiosis. Results obtained by using different exogenous environments forthe in vitro differentiation of callus into gametophytes orsporophytes are also reported. These support our contentionthat there is an accumulation of a sporophytic factor in thegametophytic callus cells, which is diluted during the processof differentiation. The morpho-regulatory influence of lightin the differentiation of apical cells with three cutting facesfrom unorganized callus is also considered.     

植物激素对大岩桐愈伤组织诱导和芽分化增殖的影响

以大岩桐(Sinningia specioca)的幼嫩茎、叶片为外植体,通过正交实验的方法探讨不同浓度和比例的植物激素对愈伤组织诱导和芽分化增殖的影响。实验结果表明:大岩桐愈伤组织的形成最佳激素组合为2,4二-氯苯氧乙酸2.0 mg/L 6苄-基嘌呤0.1 mg/L 萘乙酸0.3 mg/L;芽分化的最佳激素组合为6苄-基嘌呤0.5mg/L 萘乙酸0.1 mg/L。     

Ca2+对黄瓜子叶离体培养物花芽分化的影响

黄瓜子叶离体培养物分化培养 0～ 8d期间 ,添加Ca2 有利于花芽分化 ,花芽分化率可从Ca2 0mmol/L的 (7.9± 5 .6 ) %上升到Ca2 6mmol/L的(31.7± 4.0 ) % ;0～ 2d和 2～ 4d无钙脉冲处理不利于花芽分化 ,高钙脉冲处理的花芽分化率比对照略高 ;4～ 6d和 6～ 8d高钙脉冲不利花芽分化 ,而无钙脉冲处理使花芽分化率上升很多。尤其是在 4～ 6d ,高钙处理使花芽分化率从 (2 2± 1.5 ) %下降到 (15 .7±3 .5 ) %。而无钙处理使花芽分化率从 (2 2 .4± 1.4) %上升到 (4 3± 3 .5 ) %。表明 0～ 8d期间不同时间段对Ca2 的需求是有差别的。相关性分析表明 :0～ 8d期间外源Ca2 影响花芽分化率与总芽中花芽比例极显著相关 ,提示Ca2 可能影响子叶向花芽或营养芽分化的趋势。本文结合已报道的黄瓜子叶培养物花原基形成的时程 ,分析了Ca2 对花原基形成和分化的影响     

喷施烯效唑对苹果顶芽激素水平和花芽分化的影响

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