不同光质和钙对小麦幼苗硝酸还原酶和谷氨酰胺合成酶活性的影响(简报)

蓝光、红光、远红光都可诱导小麦幼苗硝酸还原酶的活性。黄化苗经红光照射后立即照射远红光,可逆转红光对硝酸还原酶活性的诱导效应,钙可促进这一效应。绿苗在缺钙时没有光逆转效应,有钙时则表现部分逆转效应。谷氨酰胺合成酶活性和硝酸还原酶活性的变化趋势在总体上是一致的。两种酶活性受钙促进,与ＮＯ~(－)_３－Ｎ积累呈负相关。     

不同光质和钙对小麦幼苗硝酸还原酶和谷氨酰胺合成酶活性的影响

蓝光,红光,远红外都可诱导小麦幼苗硝酸还原酶的活性。黄化苗经红光照射后立即照射远红光,可逆转红光对硝酸还原酶活性的诱导效应,钙可促进这一效应。绿苗在缺钙时滑有光逆转效应,有钙时则表现部分逆转效应。     

红光和远红光对绿豆叶绿体Ca^2＋—ATP酶活性的影响

10分钟虹光照射抑制绿豆叶绿体Ca~(2 )-ATPase活性,远红光照射有逆转红光的作用。酶活性的高低取决于最终照射的光质。红光照射后2小时,叶绿体Ca~(2 )-ATPase活性增加。红光和远红光对离体的叶绿体Ca~(2 )-ATPase活性没有显著影响。     

红光,远红光和植物激素对水稻幼苗生长及CAT,POX活性的影响

红光(R)和远红光(Fr)都抑制水稻胚芽的生长,但对胚芽鞘来说,红光抑制其生长,远红光表现出部分逆转效应。一定浓度单一生长素(IAA)促进水稻胚芽鞘的生长,而赤霉素(GA_3)与生长素作用相反。对于水稻的过氧化氢酶(CAT)、过氧化物酶(POX),红光促进两种酶的活性,远红光则表现出逆转效应。单一10~(-2)ppmIAA、10~(-2)ppmGA_3都促进其活性。照光时,在10~(-2)ppm IAA存在的条件下,红光表现为促进,远红光则表现为抑制;但在10~(-2)ppm GA_3存在的条件下,红光反而对两种酶的活性有抑制作用,远红光则表现为促进作用。     

光与激素对于杜鹃花种子发芽的作用

本文报道24种杜鹃花种子的光照发芽试验,结果表明杜鹃花种子是需光性种子。所有种子的发芽都必须有光照,假如在黑暗条件下进行发芽试验,种子的发芽率几乎等于零。杜鹃花种子的发芽受光敏素的控制,红光促进种子发芽,远红光可以逆转这种促进作用,种子发芽与否取决于最后一次照射的光质。 不同种的杜鹃花种子对光的敏感性存在差异。敏感的种子可以在蓝光,短光照时间下正常发芽,并且它们的需光要求可以被1000 ppm赤霉素所代替。迟钝的种子发芽则要求红光和长光照时间,1000 ppm赤霉素不能代替光,光和赤霉素并用具有增效作用。     

大叶黄杨叶片表皮组织的聚光效应及其对叶片内部光分布的影响

利用自制的光纤微探测器研究了大叶黄杨 (EuonymusjaponicusT .)叶片内部的光分布。叶片表皮组织具有聚光效应 ,用金相砂纸磨去叶片的上表皮组织可以去除这种效应。用 6 6 0nm的红光照射叶片时 (从上表皮方向 ) ,叶片内部光量迅速下降 ,在不到 10 0 μm的路径上光量下降到初始值的 2 0 %。叶片内部光分布微分曲线说明 :叶片表皮组织的存在有利于叶片内部各组织之间光吸收的均匀化。分析叶片内部红光分布曲线 (照射上表皮方向以及照射下表皮方向 ) ,海绵组织对红光 (6 6 0nm)吸收较少 ,这可能是海绵组织的一种生理生态意义上适应性的反映     

蓝光调节高粱突变体har1 幼苗的去黄化反应

以航空诱变高粱突变体har1为材料, 对其幼苗去黄化过程进行研究。萌发的种子在远红光下预培养6小时后, 置于12小时蓝光/12小时黑暗条件下培养。测量幼苗的各器官伸长, 结果表明, 与野生型R111相比, har1的胚芽鞘、中胚轴、第一叶鞘以及第二叶鞘的伸长均受到蓝光的明显抑制, 而蓝光对叶片生长影响不明显。3天龄har1黄化苗在连续蓝光下中胚轴花色素苷的积累明显增高, 红光和远红光无此效应。此外, 蓝光促进har1叶片叶绿体发育, 且在蓝光照射24小时后叶片中叶绿素含量升高。Western blot检测结果显示, 7天龄R111和har1幼苗隐花色素SbCRY1b蛋白水平呈现蓝光下低、黑暗中高的变化趋势, har1的SbCRY1b蛋白水平在黑暗中高于R111。研究结果表明, 高粱har1在去黄化过程中具有蓝光超敏感表型,SbCRY1b的作用值得进一步深入研究。     

蓝光调节高粱突变体har1幼苗的去黄化反应

以航空诱变高粱突变体har1为材料,对其幼苗去黄化过程进行研究。萌发的种子在远红光下预培养6小时后,置于12小时蓝光/2小时黑暗条件下培养。测量幼苗的各器官伸长,结果表明,与野生型R111相比,harl的胚芽鞘、中胚轴、第一叶鞘以及第二叶鞘的伸长均受到蓝光的明显抑制,而蓝光对叶片生长影响不明显。3天龄har1黄化苗在连续蓝光下中胚轴花色素苷的积累明显增高,红光和远红光无此效应。此外,蓝光促进har1叶片叶绿体发育,且在蓝光照射24小时后叶片中叶绿素含量升高。Westernblot检测结果显示,7天龄R111和har1幼苗隐花色素SbCRY1b蛋白水平呈现蓝光下低、黑暗中高的变化趋势,har1的SbCRY1b蛋白水平在黑暗中高于R111。研究结果表明,高粱har1在去黄化过程中具有蓝光超敏感表型,SbCRY1b的作用值得进一步深入研究。     

蓝光调节高梁突变体bar1幼苗的去黄化反应

以航空诱变高粱突变体har1为材料,对其幼苗去黄化过程进行研究。萌发的种子在远红光下预培养6小时后,置于12小时蓝光/2小时黑暗条件下培养。测量幼苗的各器官伸长,结果表明,与野生型R111相比,harl的胚芽鞘、中胚轴、第一叶鞘以及第二叶鞘的伸长均受到蓝光的明显抑制,而蓝光对叶片生长影响不明显。3天龄har1黄化苗在连续蓝光下中胚轴花色素苷的积累明显增高,红光和远红光无此效应。此外,蓝光促进har1叶片叶绿体发育,且在蓝光照射24小时后叶片中叶绿素含量升高。Westernblot检测结果显示,7天龄R111和har1幼苗隐花色素SbCRY1b蛋白水平呈现蓝光下低、黑暗中高的变化趋势,har1的SbCRY1b蛋白水平在黑暗中高于R111。研究结果表明,高粱har1在去黄化过程中具有蓝光超敏感表型,SbCRY1b的作用值得进一步深入研究。     

光质对植物光合作用的调控及其机理

光合作用是植物生长发育的基础.光质对植物光合作用的调控主要包括可见光对植物气孔器运动、叶片生长、叶绿体结构、光合色素、D1蛋白及其编码基因和光合碳同化等的调节,以及紫外光对植物光系统Ⅱ的影响.蓝光和红光能促进气孔的开张,而绿光能够逆转这种作用.蓝光有利于叶绿体的发育,红、蓝、绿复合光有利于叶面积的扩展,而红光更有利于光合产物的积累;不同光质对不同植物、不同组织器官叶绿素积累的影响不同.蓝光和远红光可以促进psbA基因转录物质的积累.大多数高等植物和绿藻在橙、红光下光合速率最高,蓝紫光其次,绿光最低.紫外光可以导致光系统Ⅱ的电子传递活性下降.此外,针对光质与光合作用研究领域中存在的问题,对今后的研究方向进行了讨论.     

Modes of Action of Phytochromes in Establishing DifferentPhototropic Responsiveness of Maize Coleoptiles

Previous studies have examined the effects of red light (R) on phototropism of maize ( Zea mays L. cv. Royaldent Hit 85) coleoptiles. The R effect on time-dependent phototropism (TDP) was further studied by characterizing its fluence-response relationship. The results showed the R effect was a low-fluence-response, unlike those on pulse-induced phototropisms that show a very-low-fluence-response mode. A subsequent pulse of far-red light (FR) could reverse the R effect. TDP responsiveness, however, recovered as the following FR was extended. The FR-dependent increase in TDP responsiveness was obtained even coleoptiles were pretreated only with FR. It suggested that TDP responsiveness could also be established in response to a FR signal. The fluence-response relationship for the effect of FR was then investigated. The effect of FR depended on the time of irradiation and required high photon fluences. Because reciprocity was invalid at the higher fluence range, the effect of FR would be a high-irradiance-response mode. Relation between phytochrome action modes and possible multiple pathways for phototropic signal transduction was analyzed based on the experiment results.     

Phototropism: mechanisms and ecological implications

Abstract. Phototropism in seed plants, either etiolated or de-etiolated, is mediated by unidentified photoreceptor(s) sensitive to blue and near-UV regions of the light spectrum. Green plants may have an additional phototropic system sensitive to red light. Fluence-response studies of the blue light-sensitive phototropism, initially made on oat coleoptiles, have indicated the occurrence of multiple response types. Of those, two are found to be general: the first pulse-induced positive phototropism (fPIPP), or the so-called first positive curvature, and the time-dependent phototropism (TDP) or the second positive curvature. The fPIPP, elicited by a pulse stimulus shorter than a few minutes, is characterized by a bell-shaped fluence-response curve and the validity of reciprocity. The TDP, elicited by prolonged irradiation, is characterized by its dependence on the exposure time and the invalidity of reciprocity. Studies made on these two response types have revealed the following: (1) plants acquire directional light information for phototropism by sensing internal light gradients created by light scattering and absorption; (2) phototropism results from redistribution of growth, i.e. inhibition on the irradiated side and compensating stimulation on the shaded side; (3) lateral movement of growth regulators, the principle of the Cholodny-Went theory, can account for the growth redistribution, and auxin is clearly the mediating regulator in maize coleoptiles. This review further describes some mechanistic implications of fPIPP. Experimental results indicate that (1) fPIPP is mediated by a single step of photoreaction, (2) the responsiveness, reflected in the height of the fluenceresponse curve, is reduced by pre-irradiation with blue light and recovers gradually afterward, and (3) the light sensitivity, reflected in the position of the fluence-response curve along the log fluence axis, is also reduced by the pre-irradiation and recovers gradually. Analyses of these results, based on kinetic models, suggest that the bell-shaped fluence-response curve is caused by the difference in the amounts of a photoproduct between irradiated and shaded sides, and that fPIPP represents a mechanism of TDP. It is also indicated that phytochrome in the red-absorbing form exerts two separate effects on phototropism: reduction of the light sensitivity and enhancement of the responsiveness. Along with the discussion of the mechanisms of phototropism, their ecological implications are considered.     

Phytochrome is required for the occurrence of time-dependent phototropism in maize coleoptiles

Time-dependent phototropism (TDP), sometimes called second positive curvature, occurs when the duration of phototropic stimulation with blue light (B) exceeds a few minutes. TDP was characterized in maize (Zea mays L.) coleoptiles raised under continuous red light (R). Subsequently, coleoptiles adapted to darkness were used to investigate the effect of R on TDP. It was found that TDP, which is induced in R-grown coleoptiles, does not occur in dark-adapted coleoptiles and that dark-adapted coleoptiles begin to show TDP after treatment with R. The TDP responsiveness became maximal 1-2 h after treatment with a R pulse and decreased during the next few hours. At least 10 min was required after a short pulse of R before the coleoptile began to respond to B for the induction of TDP. The effect of R in establishing the TDP responsiveness was totally suppressed by a pulse of far-red light given immediately after an inductive pulse of R. It is concluded that the mechanism of TDP requires for its establishment a R signal perceived by phytochrome. The TDP of R-grown and R-pretreated coleoptiles showed relationships to stimulation times and fluence rates that are similar to those reported for oat coleoptiles, except that TDP of maize showed a sharp increase in its magnitude within a narrow range of stimulation times as short as 5-10 min.     

Effects of red light on the fluence–response relationship for pulse-induced phototropism of maize coleoptiles

Dark-adapted coleoptiles of maize (Zea mays L.) were treated with red light (3min at 10.5 μmol m^?2S^?1) and were Stimulated, after a dark interval, with a pulse of unilateral blue light to induce phototropism. Phototropic fluence-response curves were obtained in this way for different dark intervals. It was confirmed that the bell-shaped fluence-response curve for the first pulse-induced positive phototropism (FPIPP) shifts to higher fluences following the red-light treatment, the maximal shift being achieved at a dark interval of 2h. We found, however, that the two arms of the Fluence-response curve do not shift synchronously. The shift of the descending arm to higher fluences began at 15 min. The ascending arm showed a slight shift to lower fluences before a greater shift to higher flucnces. the change of the shift direction occurring at 30–40min. Accordingly, the fluence-response curve obtained for a 30 min dark interval was comparatively wide. Although dark-adapted coleoptiles showed only fPIPP, another bell-shaped fluence-response curve, representing the second pulse-induced positive phototropism (sPIPP), appeared gradually after the red-light treatment. These changes of the phototropic fluence– respnse curve following exposure to red light are likely to have adaptive values because they favour phototropism under brighter light.     

Restoration of phototropic responsiveness in decapitated maize coleoptiles

The literature indicates that the tip of maize (Zea mays L.) coleoptiles has the localized functions of producing auxin for growth and perceiving unilateral light stimuli and translocating auxin laterally for phototropism. There is evidence that the auxinproducing function of the tip is restored in decapitated coleoptiles. We examined whether the functions for phototropism are also restored by using blue-light conditions that induced a first pulse-induced positive phototropism (fPIPP) and a time-dependent phototropism (TDP). When the apical 5 mm, in which photosensing predominantly takes place, was removed, no detectable fPIPP occurred even if indole-3-acetic acid (lanolin mixture) was applied to the cut end. However, when the blue-light stimulation was delayed after decapitation, fPIPP became inducible in the coleoptile stumps supplied with indole-3-acetic-acid/lanolin (0.01 mg g-1), indicating that phototropic responsiveness was restored. This restoration progressed 1 to 2 h after decapitation, and the curvature response became comparable to that of intact coleoptiles. The results for TDP were qualitatively similar, but some quantitative differences were observed. It appeared that the overall TDP was based on a major photosensing mechanism specific to the tip and on at least one additional mechanism not specific to the tip, and that the tip-specific TDP was restored in decapitated coleoptiles with kinetics similar to that for fPIPP. It is suggested that the photoreceptor system, which accounts for fPIPP and a substantial part of TDP, is regenerated in decapitated coleoptiles, perhaps together with the mechanism for lateral auxin translocation.     

Photosensitivity of Rumex obtusifolius seeds for stimulation of germination: Influence of light and temperature

A population of Rumex obtusifolius L. seeds imbibed for 24 h at 25°C exhibits a sigmoid logarithmic fluence-response relationship for stimulation of germination by red light (R), 11.0 μmol m⁻² being necessary for 50% of the response. After 24 h imbibition at 35°C the fluence-response relationship for stimulation of germination by R is biphasic. For 50% response the very sensitive phase (very low fluence-response) requires 4.7 − 10⁻²μmol m⁻² whereas the less sensitive phase (low fluence-response) requires 4.0 μmol m². A few seconds of far-red light (FR) satisfies the germination requirement of the sensitive seeds after 24 h at 35°C. However, a longer period of FR (2 h) results in low germination. The fluence-response relationship for induction of these seeds by R is sigmoid, 4.8 μmol m⁻² being necessary for 50% response, demonstrating that 2 h FR desensitizes the sensitive proportion of the seed population induced by 24 h at 35°C. A proportion of the seed population can be further sensitized by 60 min at 35°C following this desensitization.     

Red Light-Induced Shift of the Fluence-Response Curve for First Positive Curvature of Maize Coieoptiles

The fluence-response curve for first positive phototropic curvtureof dark-grown maize coleoptiles is shifted to ten-fold higherfluences if the coieoptiles are irradiated with red light 2h prior to the phototropic induction with blue light. Fluence-responsecurves for this red-induced shift were obtained with unilateralred irradiations 2 h prior to inductive blue pulses of differentfluences. They differ significantly depending on whether thered light was given from the same side as or the opposite sideto the respective inductive blue pulse, thus demonstrating thatthe red light effect is a local response of the coleoptile.The fluence-response curves for an inductive blue pulse in theascending part were compared with those for an inductive bluepulse in the descending part of the fluence-response curve forblue light induced phototropism. They are quite different inthreshold of red light sensitivity and shape for irradiationsfrom both the same and the opposite sides. This offers evidencefor the hypothesis that at least two different photosystemsare involved in phototropism, and that they are modulated differentlyby a red light preirradiation. All these fluence-response curvesindicate that it is possible to increase the response in thecoleoptile, if the red light preirradiation is given oppositeto the inductive blue pulse. This is supported by blue lightfluence-response curves obtained after a weak unilateral redpreirradiation. (Received September 11, 1986; Accepted October 18, 1986)     

Time course of phytochrome-mediated changes in growth gradients on coleoptiles of Triticum aestivum L.

The length of parenchyma cells along the axis of dark-grown coleoptiles of Triticum aestivum L. and the pattern of competence for red-light-(R-) induced stimulation or inhibition of cell elongation in the course of coleoptile development were determined by microscopic measurements in a file of 240 cells from the tip to the base. On the basis of these measurements distinct zones (responding in different ways to R) were selected for studying the early time course of phytochrome-mediated growth-rate changes in intact coleoptiles by use of a sensitive transducer system. Between 2 d and 4 d after sowing dark-grown coleoptiles showed a graded incline in cell growth activity from the apex to the base (growth gradient). Whereas cell elongation in the coleoptile base ceased 4 d after sowing, cell elongation speeded up in the tip and middle region at that time. Those cells that grew slowly in darkness (tip and middle region between 2d and 3 d after sowing) were stimulated in growth by R-pulse irradiation (1 min R, 660 nm, 1000 J · m^–2). In contrast, the growth of fast-growing cells (base between 2 d and 4 d after sowing, tip and middle region between 4 d and 5 d after sowing) was inhibited by R. However, the starting time for R-induced growth changes was different for different coleoptile zones. The respective data point to the storage of a phytochrome-mediated signal in the cells of the middle region, until these cells become competent to respond to it; alternatively, Pfr, the far-red-light-absorbing form of phytochrome, may be stored in a stable form. Continuous recordings on the effect of R, far-red (FR) and R/FR on the zonal growth responses were made on intact coleoptiles, selected 3 d after sowing. During a 5-h investigation period the R-induced changes in growth rate could be divided into two phases: (i) A transient growth inhibition which started approx. 15 min after R. This response was qualitatively the same in all coleoptile zones investigated (tip, middle region, base). (ii) Zonal-specific growth responses which became measurable approx. 2.5 h after R, i.e. growth promotion in the tip, growth inhibition in the base and an adaptation of growth rate to the dark control level in the middle region. The R-induced growth rate changes were reversible by FR for both phases. Additional growth experiments on excised coleoptile segments under R and auxin application indicated that the zonal-specific growth promotion or inhibition may be not mediated by an influence of R on the auxin level.Abbreviations FR far-red light - Pfr far-red-light-absorbing form of phytochrome - R red light The technical assistance of Mrs. B. Liebe is gratefully acknowledged.     

Role of Calcium Channels in Phytochrome-Mediated Regulation of Gravitropic Response

The effect of the inhibitors of calcium channels on red-light (R)-mediated inhibition of gravitropic bending was studied in excised wheat (Triticum aestivumL.) coleoptiles. The effect of a short R pulse (2 min) preceding the gravitropic stimulation was completely alleviated by a similar pulse of far-red light (FR), when the latter preceded the gravitropic stimulation and the delay between R and FR pulses did not exceed 20 min. Plant memory of the R pulse lasted up to 40 min. Neither R nor FR exerted any effect on the gravitropic reaction when applied after gravitropic stimulation. Treatment with 1 M of verapamil, LaCl₃, GdCl₃, or ruthenium red before the gravitropic stimulation prevented or released the R-exerted suppression of the gravitropic response (GR). The GR in coleoptiles is apparently regulated by the phytochrome system at the induction phase and involves calcium channels.     

Circumnutation of rice coleoptiles: its relationships with gravitropism and absence in lazy mutants

Although circumnutation occurs widely in higher plants, its mechanism is little understood. The idea that circumnutation is based on gravitropism has long been investigated, but the reported results have been controversial. We used dark-grown coleoptiles of rice (Oryza sativa L.) to re-investigate this issue. The following results supported the existence of a close relationship between gravitropism and circumnutation: (1) circumnutation disappears on a horizontal clinostat; (2) circumnutation is interrupted by a gravitropic response and re-initiated at a definable phase after gravitropic curvature; (3) circumnutation can be re-established by submergence and a brief gravitropic stimulation in the coleoptiles that have stopped nutating in response to red light; and (4) lazy mutants show no circumnutation. In spite of these results, however, there were cases in which gravitropism and circumnutation could be separated. Firstly, the non-circumnutating lazy coleoptile showed nearly a wild-type level of gravitropic responsiveness in its upper half, although this part was an active site of both gravitropism and circumnutation in wild-type coleoptiles. Secondly, coleoptiles could nutate without overshooting the vertical when developing phototropic curvature. It is concluded that gravitropism influences, but it is not directly involved in the process of circumnutation. It is further suggested that a gravity signal, shared with gravitropism, contributes to the maintenance of circumnutation.