光周期对青饲玉米耐高氮的调控效应

以光周期敏感型‘华农1号’青饲玉米为材料,在大田条件下,设置N1(75kg/hm2)、N2(225kg/hm2)、N3(375kg/hm2)3个氮素水平和3个光周期处理(16h、13h和10h),分析了其在不同光照长度条件下耐高氮胁迫的能力,探讨光周期对玉米氮高效相关的农艺性状和光合特性指标的影响。结果表明,(1)16h光照处理下,玉米植株的根长、根表面积、根体积分别比10h处理增加了113.19%、45.73%和97.71%,叶片叶绿素含量与净光合速率比10h处理分别提高97.90%和60.24%,且根长、根体积、叶绿素含量和净光合速率在16h和10h处理下差异极显著;16h处理与10h处理叶片数的平均相差值(12)显著,根系直径随光周期延长逐渐减小,但光周期对植株分蘖数无显著影响。(2)‘华农1号’青饲玉米地下部和地上部部分农艺性状指标,在16h长光照处理下随氮素水平的提高而增加,表现出耐高氮胁迫的生物学特征;在10h短光照处理下氮素水平过高相关性状指标反而下降。(3)随着光照时间逐渐延长,地上部生物量逐渐显著增加。研究发现,光周期敏感型‘华农1号’青饲玉米具有较强的耐高氮能力,长光周期促进了其植株营养生长阶段的生长发育,增强了其对高氮的适应能力。     

光周期对穗花狐尾藻生长、开花与种子形成的影响

通过人工补光和遮光处理,初步研究了光周期对狐尾藻生长和开花的影响。研究发现:8h短日照条件不利于狐尾藻的生长和花序形成,导致狐尾藻不能正常开花和结实;与自然日照长度(平均日照14h)条件下相比,16h长光照条件可以增加植株的高度和分枝数,形成更大的生物量;但24h全光照条件对生长有抑制作用。长光照条件下,狐尾藻花序形成时间和开花时间均比自然条件下延迟,形成花序的数目也显著较自然条件下的少,但长光照条件下形成的种子比自然条件下形成的种子具有更高的萌发率。     

不同光周期对西红花开花和花丝品质的效应比较

为筛选促进西红花开花和提高花丝品质的最佳光周期,以3种不同规格(20~25 g、25~30 g、30~35 g)西红花种球为材料,设置4种光周期处理(8 h/16 h、10 h/14 h、12 h/12 h、14 h/10 h),考察光周期对西红花种球鲜重变化、主芽生长、展叶数量、开花后营养物质含量以及花朵性状和花丝品质的效应。结果表明:(1)光周期8/16 h最有利于促进西红花主芽生长、增加展叶的种球数量。(2)光周期8 h/16 h和12 h/12 h下的西红花花朵直径大且前5 d开花数量多。(3)不同光周期对西红花苷含量、花丝干重、鲜重、折干率、含水量等花丝品质无显著影响。(4)西红花开花后种球中可溶性糖、淀粉、可溶性蛋白等营养物质含量在光周期8 h/16 h处理下较高,而在光周期12 h/12 h和14 h/10 h处理下较低。研究认为该试验条件下适合西红花生长的最佳光周期是8 h/16 h(昼/夜),此光周期有利于西红花生长、促进初期提前开花,然而对花丝品质无明显影响。     

光周期对毕氏海蓬子(Salicornia bigelovii Torr.)开花的影响

对毕氏海蓬子分别进行了不同日照长度处理及不同光周期数的短日照处理,发现:(1)毕氏海蓬子开花的临界日长为15 h;(2)在光照8 h/d处理条件下,毕氏海蓬子开花所需最少光周期数为13;(3)经过13～18个短日照(8 h光照/d)光周期数处理,再移至长日照(17 h光照/d)条件下,有成花逆转现象.     

高羊茅FaCONSTANS基因的表达及功能分析

植物由营养生长向生殖生长转变过程中光周期调控起着重要的作用。CONSTANS (CO) 是光周期途径中的特有基因,为探讨高羊茅FaCONSTANS (FaCO) 基因响应日照长短从而启动植物开花的机理,利用实时荧光定量qRT-PCR技术分析在长日照、短日照、持续光照、持续黑暗条件下FaCO基因的表达水平。构建过表达载体p1300-FaCO,利用农杆菌介导法遗传转化拟南芥,构建沉默载体p1300-FaCO-RNAi遗传转化高羊茅。结果表明,FaCO基因的表达受光周期调控,与生物钟控制的昼夜节律相关。在长日照条件下FaCO基因促进拟南芥开花,且恢复拟南芥突变体开花表型。RNAi沉默FaCO基因的高羊茅转基因植株晚花或者一直处于营养生长阶段。本研究初步探究高羊茅FaCO基因对开花过程的调控,这将有助于更进一步了解该基因的生物学功能。     

光周期对春石斛开花及多胺含量的影响

以春石斛为试材,研究光周期对其开花及多胺（腐胺、亚精胺和精胺）含量的影响,以期了解春石斛开花的光周期特性以及期间能源物质多胺的变化规律。结果显示,春石斛短日照处理植株开花较长日照处理的提前约18d,为称量性短日照植物;同时,短日照处理植株的花芽多,开花量犬,花径较长日照大。不同光周期诱导开花过程中,春石斛叶片内腐胺含量最高,波动较大,短日照处理下基本维持比长日照高的水平。亚精胺含量其次,且随生长发育逐渐升高,短日照处理下一直保持比长日照高的水平。精胺含量最低,变化不大,短日照下保持与长日照相同或略高的水平。由此推测,春石斛为称量性短日照植物,高水平的腐胺和亚精胺可能与春石斛花芽的形成有关。     

根系浸泡生长素对橄榄幼苗生长及其叶绿素荧光特性的影响

以1～2片真叶的橄榄健康幼苗为试材,研究2种外源生长素吲哚丁酸(IBA)和萘乙酸(NAA)在不同浓度(100、300和500μmol/L)及不同处理时间(1、3和5 h)下对橄榄幼苗根系和地上部生长量的影响,并运用隶属函数法进行综合评价,对测定排名前5个处理的橄榄幼苗的叶绿素荧光特性进行分析,以探寻促进橄榄幼苗生长的最佳处理,为橄榄实生砧木苗繁育提供理论及技术依据。结果显示:(1)外源生长素能促进橄榄幼苗生长,改善根系构型,以低浓度处理和高浓度短时长的处理表现较好,能提高橄榄幼苗生长势。(2)隶属函数分析橄榄幼苗生长的综合效果排名前五的处理为:N3001N5001N1005N1001I3003,前4个均为NAA处理,平均隶属函数值均大于0.65,且对株高、茎粗、地上部生物量、总根长、总根表面积、主根长及侧根数的促进作用比IBA大。(3)叶绿素荧光特性显示,N1001处理的橄榄幼苗实际光化学量子效率Y_((Ⅱ))最高且比对照显著增加了8.16%,光合电子传递速率ETR最大,非光化学淬灭系数NPQ最低且比CK显著降低了23.78%(P0.05)。研究表明,N1001为促进橄榄幼苗生长的最佳处理,即选择100μmol/L外源生长素NAA处理橄榄实生砧木苗根系1 h,能显著促进植株生长,提高幼苗的光能利用率和光合能力。     

环境因素对长颚斗蟋翅型分化的影响

长颚斗蟋具有明显的翅二型现象。比较长颚斗蟋不同翅型成虫的形态差异,结果表明其短翅型成虫除翅已明显退化外,与长翅型成虫并无其他形态差异。为探究环境因素与长颚斗蟋翅型分化的关系,就光周期、温度及密度对其翅型分化的影响进行了研究。结果表明,短光周期会抑制其长翅型的形成,而LD16∶8h的长光周期则促进长翅个体的分化,但非自然条件的长光周期及全明或全暗条件与上述结论并不一致。变化光周期亦会影响其翅型分化,而随着改变光周期的时间及方向的不同,影响作用亦不相同。在孵化后第20天及40天经历光周期的趋长变化会促进其长翅化;而在孵化后第20天经历光周期的趋短变化则会抑制其长翅化,第30天转移却有促进作用。此外,低温(20℃)条件诱导长颚斗蟋短翅化,高温(25℃,30℃)则促进长翅型的分化。单独饲养时,LD12∶12h与LD16∶8h条件下的若虫均羽化为短翅型成虫,当密度增加至2或5头/容器时,成虫的长翅率均明显增加,说明高密度亦是长翅型个体出现的重要诱因。     

激光共聚焦显微镜观察玉米茎尖形态学变化

以玉米光敏感自交系CML288和不敏感自交系黄早4为实验材料,采用长日照15 h、短日照9 h的不同光周期处理,利用激光扫描共聚焦显微镜(laser scanning confocal microscope, LCSM)观察了不同叶龄期玉米茎尖分生组织的形态学变化.结果表明,短日照能促进玉米开花,促进茎端分生组织向生殖生长转化,黄早4和CML288分别在6叶期和7叶期完成茎尖分生组织的生殖转化;而长日照则明显延迟开花,延迟茎尖分生组织向生殖生长转化,黄早4和CML288分别在8叶期和11叶期完成茎尖分生组织的生殖转化;因此光周期诱导玉米开花因光照条件和品种有一定差异,短日照条件下,光敏感和不敏感的玉米自交系开花提前,花期更接近,而长日照条件下光敏感玉米自交系开花延迟要比不敏感自交系明显得多.     

光照对蔺草生长和草茎开花率的影响

蔺草草茎长度和是否开过花是决定其品质的两个重要方面。试验表明,不同光周期及光照强度对蔺草的生长和草茎开花率会产生显著影响。生育前期,延长日照显著促进开花,遮光处理降低蔺草的分蘖、草茎长度、减少草茎开花率和每花序小花数。中后期对蔺草进行一定遮光处理后,草茎长度增加,开花率下降。试验表明,光照是造成蔺草开花逆转和影响草茎品质的重要生态因子之一。     

Influence of light quality and photoperiod on flowering of Cyclamen persicum Mill. cv. ‘Dixie White’

The effect of light quality (spectral quality) and photoperiod (day length) were studied on flowering of Cyclamen persicum cv. Dixie White. Light generated from light emitting diodes (LED) i.e. monochromatic blue (10 or 12 h per day), monochromatic red (10 or 12 h per day), blue plus red (10 or 12 h per day) and fluorescent lights were used in these studies. It was found that blue plus red LEDs improved flower induction in cyclamen, the number flower buds and open flowers being highest in the plants grown under blue plus red LED (10 h per day). Blue and red LEDs alone reduced the flowering response. Peduncle length (flower stalk length) and blooming period of flowers were also influenced by light qualities and photoperiod treatments. Peduncle length was 23.8 cm on plants grown under red LED (12 h per day) treatment but 14 cm on plants grown under fluorescent light. Blooming period of flowers grown under fluorescent light was 20 d, whereas it was 40 d with the plants grown under red LEDs (10 h per day). The results indicate that flowering and subsequent growth of cyclamen can be controlled by manipulating light quality and lighting period.     

Esters hydroxycinnamiques et induction photopériodique florale in vitro chez Cichorium intybus

Hydroxycinnamic acid esters and photoperiodic flowering induction in vitro of Cichorium intybus.
In root tissues of Cichorium intybus L. cv. Witloof cultured in vitro, the photoinductive period occurs between the 8th and the 16th day after the start of the culture. The promotive light conditions are either long days (16 h photoperiod) or daily cycles of 9 h white + 15 h red light applied during the photoinductive period in an otherwise short day treatment. During the photoinductive period and under suitable irradiation conditions, the endogenous hydroxycinnamic acid esters (especially chlorogenic acid) show a regular development as from the 8th day, reaching a maximal level by the 16th day. The amount of these molecules then decreases rapidly, preceding the external expression of floral induction. When we apply non-inductive conditions [short days (9 h) or daily cycles of 9 h white + 15 h (far-red + red) light supplied from the 8th to the 16th day in otherwise short day conditions], the metabolic changes indicate the same pattern during the inductive period as mentioned above. However, a fundamental difference exists between the inductive and non-inductive conditions, so that the production of hydroxycinnamic acid esters is particularly high towards the end of the second week of in vitro development in the induced state. This increase is not primarily due to increased photosynthetic activity in long day conditions, since it occurs both in the long day treatments and in the treatments with daily cycles of 9 h white + 15 h red light, thus revealing the morphogenetic action of light via phytochrome. This accumulation of hydroxycinnamic acid esters is correlated with floral induction, which appears to be ineffective unless there is a certain minimum amount of these molecules in the tissues.     

Effects of Number of Photoperiodic Cycles on Induction and Development of Flowers and Fruits in Corchorus olitorius L. (var. oniyaya Epen.)

Plants of Corchorus olitorius, a short-day plant, were subjectedto varying numbers of short-day cycles before transfer to longdays. Treatments started after germination of the seeds at thetime of cotyledon release. Four short-day cycles (10 h naturaldaylight followed by 14 h darkness) were sufficient to induceflowering in all plants. The number of flowers and fruits producedon a plant increased as the number of short-day cycles was increasedfrom three to 30. Plants given three to seven short-day cyclesproduced flowers on the main stem only but when plants weremaintained in short days for longer periods, flowers were alsoproduced on the branches. The growth in d. wt of fruits wasgreatest when plants were maintained in short days throughout. Corchorus olitorius L., flowering, fruit development, photoperiodism     

Transition from absolute to quantitative short-day control in Nicotiana tabacum cv. Maryland Mammoth

The response in vitro of thin cell layers, excised from different stem regions of Nicotiana tabacum cv. Maryland Mammoth plants at various developmental stages, was studied under different photoperiodic treatments. The aim was to determine at which stage of plant development, and in which region of the stem, the absolute short-day requirement, indispensable for the induction of the flowering process in this genotype, becomes quantitative and whether it remains short-day. The explants were cultured on a medium suitable for flower neoformation, and were exposed for 30 days to the following treatments: continuous darkness, 8 h light/16 h dark per day, 16 h light/8 h dark per day, and continuous light. The first flowers on explants were observed from plants that were still in the vegetative state, but whose apex showed an accelerated production of axillary vegetative buds, as observed histologically. These explants were excised from the first 10 internodes below the first node with a leaf ≥ 5 cm in length (apical site), and produced flowers only under short-day treatment. When the apical dome initiated the organization of the terminal flower, the apical site explants developed flowers under both short-day and long-day treatments. At the same stage, explants from the 15th to the 20th internode below the first leaf ≥ 5 cm in length also formed flowers, but only under short-day. When the plant showed a complete inflorescence, flowers were also present on explants from the most basal stem internodes and from the inflorescence branches. At this stage, flower neoformation occurred under all treatments; however, under short-day the number of explants showing flowers not associated with vegetative buds on the same sample greatly exceeded that observed under other treatments, as did the mean number of flowers per explant (except the basal regions). In conclusion, in the post-inductive phases of the flowering process, the photoperiodic requirement of this genotype is always short-day. The superficial tissues of the stem require either absolute or quantitative short-day treatment, depending on their position on the stem and the stage of evolution of the flowering process in the terminal apex.     

Effect of Intercalated Long Days and Light Interruption of Dark Period on Flowering, Extension Growth and Senescence of impatiens balsamina

Plants of Impatiens balsamina L. grown under long days were divided into 5 lots to receive 1, 2, 4, 8 and 16 consecutive short day (SD) cycles respectively. Each lot was divided into 5 groups to receive 1, 2, 4, 8 and 16 long day (LD) cycles subsequent to SD regime and the cycles were repeated till the end. Observations on the number, position and time of emergence of floral buds, flowers and extension growth were recorded. The floral buds are initiated and these develop into flowers even when Individual SDs are intercalated with 16 LD cycles, showing that the sub-threshold stimulus is not wiped off but becomes effectively summated through a long non-inductive period. The floral bud initiation in lots receiving less than 4 and flowering in those receiving less than 8 consecutive SD cycles are delayed with decreasing number of consecutive SDs and increasing number of intercalating LDs. This progressive delay is probably due to the delay that is caused by these treatments in the completion of requisite number of SD cycles. The first node to show floral bud initiation is shifted up with increasing intercalated LDs only in plants receiving less than 4 SD cycles and not in those receiving more. Some of the lower floral buds in plants receiving less than 8 consecutive SD cycles either abort or revert to vegetative growth. The first node to flower is, therefore, shifted up. The number of such buds increases either with a decrease in the number of consecutive SDs or an increase in the number of intercalated LDs. The number of floral buds produced in plants receiving 2 or more and flowers in those receiving 4 or more consecutive SD cycles does not differ much with the number of intercalated LDs, but decreases in those receiving less number of SDs. Some nodes bear more than one floral bud and flower. Such nodes are observed in plants receiving individual SD cycles only when intercalated with individual LDs but in all groups in plants receiving 16 consecutive SD cycles. The rate of extension growth increases with an increase in the number of consecutive SDs. The rate in plants receiving individual SDs closely resembles that of plants grown under continuous LDs and that of consecutive 16 SDs with that of control SD plants. The attainment of maximum and the consequent steep fall preceding senescence is successively delayed with an increase in the number of intercalated LDs in plants receiving 16 consecutive SD cycles. Light interruption of the dark period inhibits both the initiation of floral buds and their development Into flowers. showing that in this plant. short days are necessary both for the initiation of floral buds and their development into flowers.     

The role of light quality of photoperiodic lighting on photosynthesis,flowering and metabolic profiling in Ranunculus asiaticus L.

Photoperiodic light quality affects flowering of long day plants, by influencing the phytochrome photoequilibria (PPE) at plant level; however, the most effective light spectrum to promote flowering is still unknown for most of the flower crops. We evaluated the influence of light spectrum of three light sources, with different induced PPE, on photosynthesis, metabolic profiling, plant growth and flowering in two hybrids of Ranunculus asiaticus L., MBO (early flowering) and MDR (medium earliness). Three photoperiodic treatments were compared to natural day length (NL): white fluorescent light (PPE 0.84), light emitting diodes (LEDs) with red:far red (R:FR) light at 3:1 ratio (PPE, 0.84) and LEDs with R:FR light at 1:3 ratio (PPE 0.63). Under natural light, net photosynthesis was higher in MDR than in MBO, while photochemistry was similar in the hybrids. Compared to NL, photoperiodic treatments did not affect net photosynthesis, while they promoted the quantum yield of PSII and reduced the non-photochemical quenching. Under NL, plant growth was greater in MBO, while flowering started earlier in MDR and flowers characteristics were similar in the hybrids. Despite the greater sensitivity of MDR plants in terms of metabolism, photoperiodic lighting improved plant growth and reduced the flowering time only in MBO, with a stronger effect under R:FR 3:1 light. MDR plants were characterized by higher soluble sugars, polyphenols, photosynthetic pigments and proteins, while MBO plants by higher starch and amino acid content. The morphological effects of photoperiodic light quality and the hybrid-specific response should be taken into account to optimize lighting protocols in commercial farms.     

Observations on the Growth of Carnation (Dianthus caryophyllus L.) in Natural and Long Days

Observations were made on the growth and development of carnationsgrown in containers under natural or 24 h days. The number ofleaf pairs produced before flower initiation and the final lengthof each flowering stem were affected by the date at which theshoot appeared and its position on the plant. Dusk-to-dawn lighting reduced the number of axillary shootsin each generation but increased their rate of development.This resulted in similar numbers of flowers being produced inboth treatments. Dianthus caryophyllus L., Carnation, growth, flowering, day length     

Effect of Gibberellic Acid and Monophenols on Flowering of lmpatiens balsamina in Relation to the Number of Inductive and Non-inductive Photoperiodic Cycles

A single treatment of plants with GA₃ (gibberellic acid) is not adequate to cause induction under LD (long day: 24-h photo-period) condition, but its effect is added to the sub-threshold induction caused by one SD (short day: 8-h photoperiod) cycle. Floral bud initiation is hastened, and the number of floral buds and flowers per flowering plant increases in plants receiving a single treatment with the combination GA₃+ SA (salicylic acid) accompanying a single SD cycle. However, the increase on 10 replicate basis is more marked in plants receiving three treatments with the combination GA₃+β-N (β-naphthol) and five treatments with the combination GA₃+ SA accompanying six and 10 SD cycles, respectively. The number of floral buds and flowers decreases with an increase hi the number of SD cycles, but it is higher in plants treated with GA₃, SA or GA₃+β-N than in the water-treated controls. — Under long days, treatment of plants with the combinations GA₃+ SA or GA₃+β-N accelerates the initiation as well as increases the number of floral buds. While a minimum of five treatments with GA₃ or of 25 with SA or β-N alone is needed for floral bud initiation under a 24-h photoperiod, three treatments are adequate to induce floral buds with the combination GA₃+ SA or GA₃+β-N under continuous illumination. Ten or more treatments with these combinations under a 24-h photoperiod produce more flowers than the same treatments under an 8-h photoperiod.     

In vitro photoinduction of leaf tissue ofStreptocarpus nobilis

Leaf expiants from vegetative plants of the short-day plantStreptocarpus nobilis (C. B. Clarke) developed flower budsin vitro when cultured in 8 h photoperiods. Tn non-inductive photoperiods only vegetative buds were formed.In vitro photoinduction was demonstrated by giving the expiants short-day (SD) cycles and then transferring them to non-inductive photoperiods for expression of flowering. On medium containing 6-benzylaminopurine (BAP) organogenesis was initiated during the photoinductive treatments. Photoinduction of leaf tissue without adventitious bud development was obtained on medium without BAP. The photoinductive state of the leaf tissue was fairly stable, being expressed after 2–3 weeks in non-inductive photoperiods when adventitious buds were formed. The quantitativein vitro flowering response to the endogenous floral stimuli, resulting from photoinduction, could provide the basis of a bioassay for presumptive flower inducing chemicals.