甘蔗试管苗光合自养生根技术研究

为了简化甘蔗组织培养流程,降低生产成本,该文以甘蔗品种GT44和B9无根试管苗为材料,先经叶片喷施植物生长调节剂处理,然后炼苗24 h,接着把处理后的试验苗移植于沙土混合栽培基质中,研究其在日光温室条件下完成不定根的形成和生长过程; 同时比较了无根试管苗和有根试管苗的移栽存活率和生长情况。试管苗生根率调查时间为试管苗移植后第3天开始至第10天结束,成活率的调查时间为试管苗移植后的第30天。结果表明:经吲哚丁酸(IBA)和ABT2号生根粉处理的无根试管苗的移栽成活率分别为96.3%和97.7%,接近传统生根试管苗的移栽成活率,且其单株试管苗生根成本为传统生根方法的1/28。甘蔗品种GT44和B9试管苗首次出现可见根的时间均发生在试管苗移栽后的第4天。试管苗根的再生可以在有菌的沙土基质栽培和日光温室条件下完成,而不需要在无菌的MS生根培养基和培养室中进行生根; 基因型和试管苗素质是影响甘蔗试管苗光合自养生根的关键因素; 甘蔗试管苗光合自养生根技术比传统试管苗培养基生根技术拥有更多优势,且操作简单、程序简化、生根率和成活率高、省工、节省能源和生产成本、效率高,替代传统的试管苗生根技术,应用于商业化生产。     

铁皮石斛组培苗移栽驯化过程中叶片光合特性、 超微结构及根系活力的变化

研究了铁皮石斛(Dendrobium candicum Wall.ex Lindl.)组培苗在移栽驯化(即试管苗移栽大田)过程中,移栽0、1、2、4d和20d(已移栽成活)时叶片光合特征参数、叶绿素荧光特性及叶绿体超微结构,光合色素含量、可溶性糖含量、根系活力和硝酸还原酶活性等生理特征的变化,以阐明铁皮石斛组培苗在移栽驯化过程中发生的适应性变化。结果表明:铁皮石斛幼苗在移栽驯化过程中叶片表观量子效率、最大净光合速率、羧化速率以及PSⅡ的最大光化学效率和表观光合电子传递速率均在移栽驯化过程中不断升高并于20d时达到最大;而暗呼吸速率和叶绿素b的含量在移栽20d时显著降低。驯化过程中叶片光合机构遭到破坏,但移栽20d时叶绿体内淀粉粒和嗜饿小体体积变大,片层结构清晰、完整且有序。根系活力和硝酸还原酶活性均在移栽20d时显著增大。铁皮石斛组培苗在移栽驯化过程中叶片光合特性、超微结构及根系活力都发生了一定的适应性变化,随着移栽时间的延长,石斛叶片的光合效率明显提高,并有大量的光合产物积累;同时根系吸收水分、养分的能力及抗逆能力都明显增强,到移栽20d时组培苗已完全适应大田环境。     

拟单性木兰不同季节断根和剪枝后蒸腾和光合特性的变化

在2005年春季、夏季和秋季,对10a生拟单性木兰(Parakmeriaomeiensis)进行断根和剪枝处理,模拟移栽,用LICOR-6400测定了植株叶片的蒸腾速率、光合速率等生理指标,探讨这些生理指标对不同季节移栽成活率的影响。结果表明,春季处理后叶片能迅速关闭部分气孔,蒸腾速率和光合速率都减小,两者最低时约为对照的60%,生理机能的减弱有利于维持地上、地下部分的平衡,因而最有利于植株成活。夏季处理后叶片气孔导度显著增加,光合速率和蒸腾速率也随之增大,最高时约为对照的2倍左右,此时,若主要依靠剪枝来降低水分消耗,很难保证水分代谢平衡,移栽成活率低。秋季处理后植株叶片气孔导度高于对照,光合速率和蒸腾速率也增加,但增加幅度相对夏季较小,前期最高约增加40%,此时移栽可以通过适当的剪枝和增加土壤水分含量等措施提高成活率。可见,与水分相关的生理机能的调节机制,决定了移栽后的成活水平,即处理后能迅速调节自身生理机能、减少水分消耗的植株,成活率就高,反之就低。     

试管苗木薯的光合作用及水分关系特性

引进种试管苗木薯188比本地栽培种面包木薯具有相对高的光合速率、光合产物输出率、光合色素含量、叶片气孔传导性、良好的水分关系参数和较低的乙醇酸氢化酶活性。表明引进种试管苗比本地栽培种对干旱逆境的适应性强,生产性能高。     

江西地方特色山药盆栽试管苗叶绿素含量以及其光合荧光参数的变化

为了解江西地方特色山药品种(瑞昌山药,南城淮山,广丰千金薯,永丰淮山和泰和竹篙薯)光合生理的变化规律,本研究对其盆栽试管苗营养生长期叶绿素含量以及其光合特性和叶绿素荧光参数进行测量,并对获得的试验数据进行统计分析。分析表明,江西地方特色山药盆栽试管苗营养生长期的叶绿素含量在5月~9月的日变化和季节变化均呈"先升后降"趋势,且均在7月或8月的15点达到最高值。江西地方特色山药盆栽试管苗营养生长期的净光合速率(Pn)、蒸腾速率(Tr)、气孔导度(Gs)、气孔限制值(Ls)、水分利用效率(WUE)、瞬时羧化速率(CUE)、初始荧光(Fo)、暗适应下最大荧光(Fm)、暗适应下PSⅡ最大光化学效率(Fv/Fm)、PSⅡ潜在光化学效率(Fv/Fo)、光适应下PSⅡ实际光化学效率(ФPSⅡ)、光适应下PSⅡ最大光化学效率(Fv'/Fm')和光化学荧光猝灭系数(q P)在5月~9月这5个月中也均呈"先升后降"趋势,且均在7月或8月达到最高值,但其胞间CO2浓度(Ci)和非光化学猝灭系数(q N)在5月~9月这5个月中却"先降后升",且均在8月达到最低值,其中瑞昌山药在7月和8月的Ci无显著性差异,南城淮山和广丰千金薯在7月和8月的q N也无显著性差异。因此,江西地方特色山药盆栽试管苗在7月和8月具有较高的光合能力,这为江西地方特色山药试管苗的移栽及其以后的水肥管理提供了理论基础。     

南城淮山脱毒苗移栽驯化期的光合生理

为了解南城淮山脱毒苗移栽驯化期的光合生理,本研究对其移栽驯化期的叶绿素含量以及其光合特性和叶绿素荧光参数进行测定和统计分析。结果表明,南城淮山脱毒苗在移栽驯化初期具有较高的叶绿素含量;随着移栽驯化时间延长,脱毒苗的叶绿素含量也显著提高;当移栽驯化时间达到10 d时,脱毒苗的叶绿素含量达到最高值;但当移栽驯化时间超过10 d时,脱毒苗的叶绿素含量则显著下降。脱毒苗在移栽驯化期间的叶绿素含量显著高于其带毒苗。脱毒苗移栽驯化期内的净光合速率(Pn)、气孔限制值(Ls)、水分利用效率(WUE)、瞬时羧化速率(CUE)、初始荧光(Fo)、暗适应下最大荧光(Fm)、暗适应下PSⅡ最大光化学效率(Fv/Fm)、PSⅡ潜在光化学效率(Fv/Fo)、光适应下PSⅡ实际光化学效率(ФPSⅡ)、光适应下PSⅡ最大光化学效率(Fv'/Fm')、光化学荧光猝灭系数(q P)先增后降;蒸腾速率(Tr)和气孔导度(Gs)显著下降;胞间CO2浓度(Ci)和非光化学猝灭系数(q N)先降后升。脱毒苗的Pn、Tr、Gs、Ls、WUE、CUE、Fo、Fm、Fv/Fm、Fv/Fo、ФPSⅡ、Fv'/Fm'、q P均显著高于带毒苗,而其Ci和q N显著低于带毒苗。因此,南城淮山脱毒苗老叶在移栽驯化期第10天具有较强的光合效率,随后其光合效率随着移栽驯化时间的延长而显著下降,并逐渐由新生叶的光合作用所代替。南城淮山脱毒苗的光合效率显著高于带毒苗,有利于积累更多的光合产物,从而实现增产。本实验结果为南城淮山脱毒苗的移栽驯化及其大田种植提供了理论基础。     

草莓离体无性繁殖的研究——Ⅱ.试管苗移栽和田间表现

本文报道了在普通塑判温室内进行试管苗移栽的试验结果,提出了用离体培养法结合常规栽培技术,及季节特点大规模无性繁殖草莓苗的生产程序。试管苗出现复叶(成年叶)是适合移栽的形态指标;硅石是试管苗良好的移栽基质。简要报道了试管苗的田间表现。     

葡萄试管苗光自养培养快速繁殖

葡萄是世界上栽培面积和总产量都占第一位的果树。有关葡萄茎尖培养、侧芽培养和无 病毒苗的试管繁殖都有报道。但是试管苗移栽成活率一般较低而且很不稳定,这就使葡萄试管苗(特别是脱病毒试管苗)快速繁殖在生产上的应用受到很大限制。本试验利用光自养培养获得的葡萄试管苗生长发育正常,移栽前练苗时培养基不易污染,可适当延长练苗时间,并且,此试管苗对移栽后的环境条件具有很强的适应能力,成活率高,生长速度快。我们     

苹果试管苗移栽前后光合特性的初步研究（简报）

植物组织培养近十几年来得到迅猛发展,已广泛应用于植物的快速繁殖及育种等各个领域。但关于苹果等木本植物试管苗光合特性方面的研究尚未见系统报道。现将我们对苹果试管苗移栽前后的光合特性所进行的研究,介绍如下。试材选用苹果品种长富-2的组培无性系。生根培养基为1/2MS 0.3mg/1 IBA 2%蔗糖 0.5%琼脂,培养容器为100ml三角瓶,温度25—28℃,光强3000lx,光周期16/8(日/夜)。生根处理45天后转到温室,开口锻炼3天,移栽在遮荫温室中,基质为蛭石并用塑料     

不同地理种源长白落叶松生理生态特性的研究

在人工气候室中测定了１０个种源长白落叶松二年生硬枝扦插苗的光合、水分生理生态参数。结果表明,不同种源的长白落叶松生理生态参数变异较大,但有一定规律可循。各种源的总光合速率＞最大净光合速率＞净光合速率＞半饱和光强时的净光合速率＞光呼吸速率＞呼吸速率,只偶有例外。各参数中呼吸速率在各种源间变异最小,光呼吸速率变异较大,总光合速率变异最大。各参数在种源间的变化趋势均与净光合速率一致,即净光合速率大的种源其它参数也大,净光合速率小的种源其它参数也小。相对光呼吸在各种源间变异较大,其释放的ＣＯ２相当于光合固定ＣＯ２的总量的１／３。光补偿点、饱和点和半饱和点在各种源间的变异较大。水分利用率在各种源间的较大变异主要是由净光合速率引起,与蒸腾速率关系不大。净光合速率占总光合速率的百分比、呼吸功效、ＣＯ２补偿点、蒸腾速率和水势在各种源间变异不大     

Influence of in vitro growth conditions on photosynthetic competence and survival rate of Rehmannia glutinosa plantlets during acclimatization period

The photosynthetic responses of Rehmannia glutinosa grown under photoautotrophic or heterotrophic conditions in vitro were investigated after transfer to greenhouse conditions. In addition, the changes in carbohydrate content and survival rates of the plantlets were evaluated. During six days after transplantation, the photosynthetic rate declined and photoinhibitory impairments represented by decrease of Fv/Fm and chlorophyll content were observed regardless of environmental conditions in vitro. Excessive transpiration was observed in plantlets grown under heterotrophic conditions during that period. Fructose and glucose content of the plantlets grown under photoautotrophic conditions increased with time and reached almost the same level of field grown plants after day 15. Under heterotrophic conditions, in contrast, the content of these sugars decreased continuously during that period. It is suggested that high survival rate of plantlets grown under photoautotrophic conditions has to be attributed to improvement of photosynthetic competence by imposed high light intensity and CO₂ concentration in vitro. The results strongly suggest that the control of transpiration during early stage after transplantation plays a key role in the acclimatization process, and photoautotrophic conditions could be a solution to solve the problems associated with transplantation stress. This revised version was published online in June 2006 with corrections to the Cover Date.     

Canopy Light Gradient Perception by Cytokinin

We have recently identified cytokinin as an important xylem-carried signal involved in the photosynthetic acclimation of plants to light gradients in dense canopies. Lower leaves become shaded in a dense canopy and consequently have reduced transpiration rates. our measurements have shown that this results in a reduced delivery of cytokinins carried in the transpiration stream to shaded leaves, as compared to light-exposed leaves. Cytokinins are involved in the regulation of photosynthetic acclimation to the light gradient by stimulating the expression of photosynthetic enzymes in light-exposed leaves. In shaded leaves, the low delivery rate of cytokinin leads to reduced photosynthetic capacity and ultimately senescence. We show evidence for this role of cytokinin, as part of a complex of signaling pathways where other regulatory mechanisms are also involved. A model is presented depicting the regulation of photosynthetic acclimation by cytokinin delivery to leaves dependent on the irradiance they receive.Key Words: canopy light gradient, transpiration, photosynthetic acclimation, cytokinin, nitrate, systemic signaling     

Changes in photosynthetic capacity and antioxidant enzymatic systems in micropropagated <Emphasis Type="Italic">Zingiber officinale</Emphasis> plantlets during their acclimation

Ginger (Zingiber officinale Rosc.) plantlets were propagated in vitro and acclimated under different photosynthetic photon flux densities (60 and 250 μmol m⁻² s⁻¹ = LI and HI, respectively). Increases in chlorophyll (Chl) content and Chl a/b ratio were found under both irradiances. In vitro plantlets (day 0) exhibited a low photosynthesis, but chloroplasts from in vitro leaves contained well developed grana and osmiophillic globules. Photoinhibition in leaves formed in vitro was characterized by decrease of photochemical efficiency and quantum efficiency of photosystem 2 photochemistry in HI treatment during acclimation. The new leaves formed during acclimation in both treatments showed a higher photosynthetic capacity than the leaves formed in vitro. Also activities of antioxidant enzymes of micropropagated ginger plantlets changed during acclimation.     

Acclimation of tobacco plantlets to ex vitro conditions as affected by application of abscisic acid

Plantlets of Nicotiana tabacum L. cv. Petit Havana SR1 were grown in vitro on Murashige and Skoog medium containing 2% saccharose, and then transplanted ex vitro into pots with coarse sand and Hewitt nutrient solution. In the first day after transplantation, the anti-transpirant abscisic acid (ABA; 0.01, 0.05 or 0.10 mM) was added to the substrate. Leaf stomatal conductance (gs), which was high in plants during the first days after transplantation similarly as in plantlets grown in vitro, was considerably decreased by ABA-treatment. However, in the further days gs decreased more quickly in control than in ABA-treated plants, and after 2 or 3 weeks gs was significantly lower than that of plantlets grown in vitro but similar in control and ABA-treated plants. Two weeks after transplantation, net photosynthetic rate, chlorophyll a + b content, maximal photochemical efficiency, and actual quantum yield of photosystem II in plant leaves were higher in comparison with those in plantlets grown in vitro. ABA-treatment had slight positive or insignificant effect on photosynthetic parameters and enhanced plant growth. Thus ABA application can alleviate 'transplant shock' and speed up acclimation of plantlets to ex vitro conditions.     

Spatial distribution of leaf nitrogen and photosynthetic capacity within the foliage of individual trees: disentangling the effects of local light quality,leaf irradiance,and transpiration

There is presently no consensus about the factor(s) driving photosynthetic acclimation and the intra-canopy distribution of leaf characteristics under natural conditions. The impact was tested of local (i) light quality (red/far red ratio), (ii) leaf irradiance (PPFD(i)), and (iii) transpiration rate (E) on total non-structural carbohydrates per leaf area (TNC(a)), TNC-free leaf mass-to-area ratio (LMA), total leaf nitrogen per leaf area (N(a)), photosynthetic capacity (maximum carboxylation rate and light-saturated electron transport rate), and leaf N partitioning between carboxylation and bioenergetics within the foliage of young walnut trees grown outdoors. Light environment (quantity and quality) was controlled by placing individual branches under neutral or green screens during spring growth, and air vapour pressure deficit (VPD) was prescribed and leaf transpiration and photosynthesis measured at branch level by a branch bag technique. Under similar levels of leaf irradiance, low air vapour pressure deficit decreased transpiration rate but did not influence leaf characteristics. Close linear relationships were detected between leaf irradiance and leaf N(a), LMA or photosynthetic capacity, and low R/FR ratio decreased leaf N(a), LMA and photosynthetic capacity. Irradiance and R/FR also influenced the partitioning of leaf nitrogen into carboxylation and electron light transport. Thus, local light level and quality are the major factors driving photosynthetic acclimation and intra-canopy distribution of leaf characteristics, whereas local transpiration rate is of less importance.     

惠州虎颜花光合特性及环境因子日变化规律

利用便携式光合蒸腾仪测定惠州虎颜花Tigridiopalma exalata的光合特性、蒸腾特性以及环境影响因子的日变化。结果表明，惠州虎颜花净光合速率的日变化为双峰型，净光合速率与光合有效辐射、大气湿度、蒸腾速率显著相关。通过测定惠州虎颜花的生理生态特性，可为其生态适应性研究提供基础数据，并为制定保护措施及扩大育种规模提供理论参考。     

Changes in total leaf nitrogen and partitioning of leaf nitrogen drive photosynthetic acclimation to light in fully developed walnut leaves

Comprehensive studies on the processes involved in photosynthetic acclimation after a sudden change in light regime are scarce, particularly for trees. We tested (i) the ability of photosynthetic acclimation in the foliage of walnut trees growing outdoors after low‐to‐high and high‐to‐low light transfers made early or late in the vegetation cycle, and (ii) the relative importance of changes in total leaf nitrogen versus changes in the partitioning of leaf nitrogen between the different photosynthetic functions during a 2 month period after transfer. Changes in maximum carboxylation rate, light‐saturated electron transport rate, respiration rate, total leaf nitrogen, ribulose 1·5‐bisphosphate carboxylase/oxygenase (Rubisco) and total chlorophylls were surveyed before and after the change in light regime. Respiration rate acclimated fully within 1 week of transfer, and full acclimation was observed 1 month after transfer for the amount of Rubisco. In contrast, total nitrogen and photosynthetic capacity acclimated only partially during the 2 month period. Changes in photosynthetic capacity were driven by changes in both total leaf nitrogen and leaf nitrogen partitioning. The extent of acclimation also depended strongly on leaf age at the time of the change in light regime.     

Photosynthetic acclimation to elevated CO2 is dependent on N partitioning and transpiration in soybean

Physiological processes that modulate photosynthetic acclimation to rising atmospheric CO₂ concentration are subjects of intense discussion recently. Apparently, the down-regulation of photosynthesis under elevated CO₂ is not understood clearly. In the present study, the response of soybean (Glycine max L.) to CO₂ enrichment was examined in terms of nitrogen partitioning and water relation. The plants grown under potted conditions without combined N application were exposed to either ambient air (38 Pa CO₂) or CO₂ enrichment (100 Pa CO₂) for short (6 days) and long (27 days). Plant biomass, apparent photosynthetic rate, transpiration rate and ¹⁵N uptake and partitioning were measured consecutively after elevated CO₂ treatment. Long-term exposure reduced photosynthetic rate, stomatal conductance and transpiration rate. In contrast, short-term exposure increased biomass production of soybean due to increase in dry weight of leaves. Leaf N concentration tended to decrease with CO₂ enrichment, however such difference was not true for stem and roots.A close correlation was observed between transpiration rate and ¹⁵N partitioned into leaves, suggesting that transpiration plays an important role on nitrogen partitioning to leaves. In conclusion existence of a feed back mechanism for photosynthetic acclimation has been proposed. Down-regulation of photosynthetic activity under CO₂ enrichment is caused by decreasing leaf N concentration, and reduced rate of transpiration owing to decreased stomatal conductance is partially responsible for poor N translocation.     

Changes in photosynthetic activity,pigment composition,electrolyte leakage,lipid peroxidation,and antioxidant enzymes during ex vitro establishment of micropropagated <Emphasis Type="Italic">Rauvolfia tetraphylla</Emphasis> plantlets

The effects of photosynthetic photon flux density (PPFD) on antioxidant metabolism and photosynthetic properties in leaves during ex vitro establishment of micropropagated Rauvolfia tetraphylla plantlets were investigated. In vitro-propagated plantlets were acclimatized at either 50 (Low-light = LL) or 300 (High-light = HL) μmol m⁻²s⁻¹ photosynthetic PPFD for 4 weeks under controlled conditions. Increases in chlorophyll (Chl) a, b and carotenoid levels were observed in plantlets acclimatized at both light intensities. At transplantation, micropropagated plantlets were not photosynthetically active, but the net photosynthetic rate increased in newly formed leaves over time during acclimatization. The observed differences in pigment contents and photosynthetic rates suggested adaptation of plantlets from heterotrophic to autotrophic mode of nutrition during acclimatization. Changes in activities of antioxidant enzymes were also observed during acclimatization. Superoxide dismutase activity increased in plantlets acclimatized at HL intensities. Likewise, changes in activity of catalase and ascorbate peroxidase were also detected. These observed changes reflected the ability of plants in developing an antioxidant enzymatic defense system aiding in survival against oxidative stress and in reducing release of free radicals.