Phytochrome-mediated cellular photomorphogenesis

Red light-induced cell elongation and division in intact, etiolated oat (Avena sativa cv Lodi) seedlings have been assessed. The middle of coleoptile was especially responsive in the very low fluence range whereas the region immediately below the coleoptile tip and the two regions just above the coleoptilar node were more responsive than the entire organ in the low fluence range. These responses in the coleoptile are both the result of an increase in cell elongation. Coleoptile cell division is slightly inhibited in the very low and slightly stimulated by red light in the low fluence range.

The one-sixth of the mesocotyl closest to the node is more suppressed in its growth than is any other region in the very low fluence range. However, the low fluence response involved the entire mesocotyl equally. In the apical one-sixth of the mesocotyl, a strong suppression of cell division and a weak suppression of cell elongation occurs. In the lower five regions of the mesocotyl, red light in both fluence ranges suppresses only cell elongation. Apparently, the difference between red light-induced oat growth stimulation and suppression primarily involves differences in the response of the cell elongation process.

     

Light or ethylene treatments induce transverse cell enlargement in etiolated maize mesocotyls

Dark-grown maize seedlings (hybrid WF-9 × 38-11) exposed for 1 or more hours to white light and then returned to darkness developed mesocotyls with enlarged apical diameters. This swelling response was an all-or-none response, and the fraction of the seedling population that showed the response depended on seedling age at irradiation. Irradiation of the coleoptile alone was nearly as effective in causing this response as was irradiation of the nodal region of the epicotyl, but irradiation of the mesocotyl base was ineffective. Removal of the coleoptile prior to irradiation did not prevent the formation of the light-induced swelling. Exogenously applied C₂H₄ (10 microliters per liter) for 24 hours in dark also induced swelling of the mesocotyl. The swelling induced in the intact seedlings was localized in the apical mesocotyl tissues with either light or C₂H₄ treatment, and maximal response to both treatments occurred with 3- to 4-day-old seedlings. Swelling of the mesocotyl was the result of transverse cell enlargement, not increase of cell numbers. The evidence suggests that light and C₂H₄ induce mesocotyl swelling in intact maize shoots by a common mechanism.     

GERMINATION AND SEEDLING GROWTH IN ECHINOCHLOA CRUS-GALLI VAR. ORYZICOLA UNDER ANOXIC CONDITIONS: STRUCTURAL ASPECTS

The morphological and cellular basis of anoxic germination in Echinochloa crus-galli var. oryzicola is reported. The embryo of E. crus-galli var. oryzicola is typically panicoid in its overall morphology, and is relatively large with a prominent coleoptile and mesocotyl. The response to anoxia is essentially the same in light and dark. Shoot growth occurs in both mesocotyl and coleoptile by cell elongation with no cell division. There is no emergence of the radicle without oxygen. Under anoxia the growth response is not the same as etiolation; there is no plumule elongation within the coleoptile, no protochlorophyll(ide) is found, and limited mesocotyl elongation occurs without oxygen. Air-dark treatment after anoxic germination results in a typical etiolated morphological response, including a resumption of mesocotyl growth, elongation of the plumule within the coleoptile, and initiation of pigment synthesis. These results indicate the effects of anoxia are not permanent but rather limiting and reversible.     

Phytochrome control of two low-irradiance responses in etiolated oat seedlings

Light-induced coleoptile stimulation and mesocotyl suppression in etiolated Avena sativa (cv. Lodi) has been quantitated. Etiolated seedlings showed the greatest response to light when they were illuminated 48 to 56 hours after imbibition. Two low-irradiance photoresponses for each tissue have been described. Red light was 10 times more effective than green and 1,000 times more effective than far red light in evoking these responses. The first response, which resulted in a 45% mesocotyl suppression and 30% coleoptile stimulation, had a threshold at 10⁻¹⁴ einsteins per square centimeter and was saturated at 3.0 × 10⁻¹² einsteins per square centimeter of red light. This very low-irradiance response could be induced by red, green, or far red light and was not photoreversible. Reciprocity failed if the duration of the red illumination exceeded 10 minutes. The low-irradiance response which resulted in 80% mesocotyl suppression and 60% coleoptile stimulation, had a threshold at 10⁻¹⁰ einsteins per square centimeter and was saturated at 3.0 × 10⁻⁸ einsteins per square centimeter of red light. A complete low-irradiance response could be induced by either red or green light but not by far red light. This response could be reversed by a far red dose 30 times greater than that of the initial red dose for both coleoptiles and mesocotyls. Reciprocity failed if the duration of the red illumination exceeded 170 minutes. Both of these responses can be explained by the action of phytochrome.     

Photobiology of phytochrome-mediated growth responses in sections of stem tissue from etiolated oats and corn

The far-red reversibility of the phytochrome-controlled stimulation of elongation of coleoptile sections by low fluence red light has been characterized in subapical coleoptile sections from dark-grown Avena sativa L., cv Lodi seedlings. The fluence dependence of the far-red reversal was the same whether or not the very low fluence response is also expressed. The capacity of far-red light to reverse the red light-induced response began to decline if the far-red light was given more than 90 minutes after the red irradiation. Escape was complete if the far red irradiation was given more than 240 minutes after the red irradiation. Sections consisting of both mesocotyl and coleoptile tissue from dark-grown Avena seedlings were found to have physiological regulation of the very low fluence response by indole 3-acetic acid and low external pH similar to that seen for sections consisting entirely of coleoptile tissue. The fluence-dependence of the red light-induced inhibition of mesocotyl elongation was studied in mesocotyl sections from dark grown Zea mays L. hybrid T-929 seedlings. Ten micromolar indole 3-acetic acid stimulates the control elongation of the sections, while at the same time increasing the sensitivity of the tissue for the light-induced inhibition of growth by a factor of 100.     

Response of actin microfilaments during phytochrome-controlled growth of maize seedlings

Summary In seedlings of maize (Zea mays L. cv. Percival), growth is controlled by the plant photoreceptor phytochrome. Whereas coleoptile growth is promoted by continuous far-red light, a dramatic block of mesocotyl elongation is observed. The response of the coleoptile is based entirely upon light-induced stimulation of cell elongation, whereas the response of the mesocotyl involves light-induced inhibition of cell elongation. The light response of actin microfilaments was followed over time in the epidermis by staining with fluorescence-labelled phalloidin. In contrast to the underlying tissue, epidermal cells are characterized by dense longitudinal bundles of microfilaments. These bundles become loosened during phases of rapid elongation (between 2–3 days in irradiated coleoptiles, between 5–6 days in dark-grown coleoptiles). The condensed bundles re-form when growth gradually ceases. The response of actin to light is fast. If etiolated mesocotyls are transferred to far-red light, condensation of microfilaments can be clearly seen 1 h after the onset of stimulation together with an almost complete block of mesocotyl elongation. The observations are discussed in relation to a possible role of actin microfilaments in the signal-dependent control of cell elongation.     

Phytochrome Action in Oryza sativa L: IV. Red and Far Red Reversible Effect on the Production of Ethylene in Excised Coleoptiles

Excised apical segments of etiolated rice (Oryza sativa L.) coleoptiles produced ethylene. Increasing the number of cut sites per coleoptile increased the rate of ethylene formation. Ethylene produced by an etiolated-intact seedling in the dark was about a half of that by the excised coleoptile segment. Red light of low energy as well as of continuous irradiation inhibited the production of ethylene. The inhibition by a low energy dose of red light was partly relieved, if the red light was followed immediately by a small dose of far red light. The effect of red and far red light was repeatedly reversible, indicating that ethylene production was regulated by a phytochrome system. If the exposure to far red light was preceded by a period of darkness, this photoreversibility disappeared; 50% of the initial reversibility was lost within 5 hours. Applied ethylene (10 microliters per liter) significantly promoted the growth of intact coleoptiles of either totally etiolated or red light-treated seedlings, but had no effect on the excised apical segment of coleoptile.     

Photomodulation of mesocotyl elongation in maize seedlings: Is there a correlative relationship between phytochrome,auxin and cell wall extensibility?

Three h white light irradiation of etiolated maize seedlings ( Zea mays L. cv. Jubilee) inhibited mesocotyl elongation and caused a sharp decrease in cell wall plastic extensibility as measured by the Instron technique. The plastic extensibility following white light irradiation (3 h) was photomodulated by phytochrome. Although the photomodulation of the plastic extensibility was correlated with growth during 20 h, no such correlation was observed at shorter times. The addition of indole-3-acetic acid to light-inhibited intact seedlings, or seedlings from which the coleoptile and inner leaves were excised, resulted in a stimulation of growth. However, none of the IAA concentrations could reverse light inhibition. The possibility of a correlative relationship between phytochrome, auxin and cell wall extensibility is discussed.     

Salinity reduces membrane-associated calcium in corn root protoplasts

Mesocotyl elongation in 4 day old etiolated seedlings immediately following 3 hours of white light (3 h W) is reversibly controlled by phytochrome. Time-lapse video measurements were made of the 5 millimeter zone just below the coleoptile which is the main growth region of the mesocotyl. The growth kinetics were determined for five contiguous 1 millimeter zones subtending the coleoptile node for nonirradiated seedlings, for seedlings given 3 h W, and 3 h W followed by terminal far-red (FR) or red subsequent to the far-red (FR/R) irradiation. Each zone in nonirradiated seedlings exhibits exponential elongation kinetics during the early stages of elongation. This finding suggests that during elongation, a growth limiting factor is also exponentially increasing. Following 3 h W differences in the kinetic responses were found for each zone. In all zones, the inhibitory effect following the 3 h W is totally FR reversible. The effect of FR is reversed by R. The upper zone exhibits the fastest response and is the most plastic in its growth response. The three upper zones all exhibit spontaneous and sharp recoveries with time. It is suggested that the control by phytochrome is not inductive but rather continuous, the controlling factor being either the level of the far red-absorbing form of phytochrome (Pfr) or the ratio Pfr to total phytochrome.     

Phytochrome-controlled extension growth of Avena sativa L. seedlings

The effects of continuous red and far-red light and of brief light pulses on the growth kinetics of the mesocotyl, coleoptile, and primary leaf of intact oat (Avena sativa L.) seedlings were investigated. Mesocotyl lengthening is strongly inhibited, even by very small amounts of P_fr, the far-red light absorbing form of phytochrome (e.g., by [P_fr]0.1% of total phytochrome, established by a 756-nm light pulse). Coleoptile growth is at first promoted by P_fr, but apparently inhibited later. This inhibition is correlated in time with the rupturing of the coleoptile tip by the primary leaf, the growth of which is also promoted by phytochrome. The growth responses of all three seedling organs are fully reversible by far-red light. The apparent lack of photoreversibility observed by some previous investigators of the mesocotyl inhibition can be explained by an extremely high sensitivity to P_fr. Experiments with different seedling parts failed to demonstrate any further obvious interorgan relationship in the light-mediated growth responses of the mesocotyl and coleoptile. The organspecific growth kinetics, don't appear to be influenced by P_fr destruction. Following an irradiation, the growth responses are quantitatively determined by the level of P_fr established at the onset of darkness rather than by the actual P_fr level present during the growth period.Abbreviation P_fr far-red light absorbing form of phytochrome     

Graviresponding sites in shoots of normal and'lazy'rice seedlings

We have examined the graviresponding sites in the shoots of seedlings of rice ( Oryzasativa L.) and their relation to the agravitropic growth of a'lazy'line. The graviresponding sites of the seedling shoots of a japonica type of rice. cv. Kamenoo. shifted from the mesocotyl/coleoplile region to the leaf-shealh base when the shoots grew in the dark. A lazy line ot rice. lazy-Kamenoo. showed gravicurvature in the mesocotyl/ coleoptile region at the early stage of growth, hut eventually lost its graviresponse as the seedlings grew. The loss of graviresponsiveness of lazy-Kamenoo was attributed to a reduced response of the coleoptile and a diminished response of the leal-sheath base to gravity. Later. the leaf-sheath base of lazy-Kamenoo became gravitropically incompetent. causing agravitropic growth of the shoots. Thus, shoots of lazy-Kamenoo lose graviresponsiveness in an organ-dependent fashion.     

乙酰胆碱对黄化玉米幼苗中胚轴通透性与物质运转的调控效应

对乙酰胆碱处理前后的黄化玉米 (ZeamaysL .)幼苗中胚轴切段节和节间的通透性和物质运转进行了比较。用电阻法测定通透性 ;通过加在胚芽鞘切口的经共质体转运的特异荧光物质羧基荧光素 (carboxyfluorescein ,CF)的分布检察物质运转。节间由柱状的、排列方向多少和长轴方向平行的细胞构成 ;而构成节的细胞短、排列不规则。结果表明跨节比电阻比节间的高 ,通透性低的短的节细胞比柱状节间细胞累积更多的CF。 0 .1mmol/L乙酰胆碱 (ACh)处理增加了节和节间的通透性 ,促进了CF的运转。物质在节和节间运转的不同 ,以及ACh对此的调控效应很大程度上可归结于细胞通透性的差异     

Asymmetric distribution of acetylcholinesterase in gravistimulated maize seedlings

Acetylcholinesterase (AChE) activity has previously been studied by this laboratory and shown to occur at the interface between the stele and cortex of the mesocotyl of maize (Zea mays L.) seedlings. In this work we studied the distribution of AChE activity in 5-d-old maize seedlings following a gravity stimulus. After the stimulus, we found an asymmetric distribution of the enzyme in the coleoptile, the coleoptile node, and the mesocotyl of the stimulated seedlings using both histochemical and colorimetric methods for measuring the hydrolysis of acetylthiocholine. The hydrolytic capability of the esterase was greater on the lower side of the horizontally placed seedlings. Using the histochemical method, we localized the hydrolytic capability in the cortical cells around the vascular stele of the tissues. The hydrolytic activity was inhibited 80 to 90% by neostigmine, an inhibitor of AChE. When neostigmine was applied to the corn kernel, the gravity response of the seedling was inhibited and no enzyme-positive spots appeared in the gravity-stimulated seedlings. We believe these results indicate a role for AChE in the gravity response of maize seedlings.     

The Physiology of Plant Integrity

The original concept of the plant integration system is presented and exemplified by the data from the studies of the regulatory controls that mediate the effects of red light (R) on the growth of etiolated maize seedlings. The integrity of higher-plant behavior depends on the functional activity and interaction of the dominant (control center). In vegetating plants as the simplest case, these centers include the shoot apex and the distal part of the root comprising the sensory tissues, the zones of the synthesis of specific hormones, and the zones of high morphogenetic and sink capacities. The system of propagating electric signals is usually devoid of the permanent generation centers. The dominant centers recognize the external and internal signals and induce the development of polarity (the bioelectric and physiological gradients), canalized connections (the conducting bundles), and oscillations. Trophic, hormonal, and electrophysiological signals of intercellular regulation are propagated along the conducting bundles and affect the intracellular membrane, metabolic, and genic control systems. The regulatory controls comprise the receptor cells recognizing the external and internal signals, the tissues of connection channels, the effector cells, and the feedback loop elements. When three-day-old etiolated maize (Zea maysL.) seedlings are treated with red light (RL), the photosignal is recognized by the phytochrome in the cells of the mesocotyl intercalary meristem; as a result, the positive biopotential is prolonged in these cells and in the coleoptilar node. An electric field (the receptor potential) thus produced would hamper, by electroosmosis, IAA transport from the coleoptile into the mesocotyl and in this way, would drastically inhibit the growth of the latter and temporarily promote the growth of the former. The primary leaves, also recognize R, as a result R promotes cell growth and the synthesis of gibberellins. The Ukhtomskii's principle of the dominant is used to interpret the plant ability for switching over its physiological systems in response to specific signals.     

Phytochrome-mediated responses in light-grown corn showing rapid,reverse reciprocity failure*

Abstract. Three responses (mesocotyl and coleoptile elongation and anthocyanin accumulation in the coleoptile) to end- of-day far-red irradiation in light-grown corn show rapid failure of the reciprocity law such that short, high fluence rate irradiations are much more effective than long, low fluence rate ones of the same fluence (reverse reciprocity failure). The reciprocity failure cannot be explained by escape from photoreversibility, a change in sensitivity to Pfr, reciprocity failure for photoconversion, or a high irradiance response taking over for long irradiation times. Fluence–response curves measured by varying irradiation time at a low fluence rate show the threshold fluence shifted to higher energy in comparison with fluence–response curves obtained at a high fluence rate. Red reversal of these responses also shows rapid reciprocity failure in the same direction, a process which can be only partially explained by escape. These responses to end-of-day far-red and red illumination are distinguished from high irradiance reactions by their low fluence requirements and ready reversibility. These same characteristics are similar to those of classical phytochrome- mediated, induction-reversion responses in etiolated tissue, but it is difficult to explain the rapid, reverse reciprocity failure in terms of standard phytochrome dogma.     

Tissue to tissue symplastic communication in the shoots of etiolated corn seedlings

Carboxyfluorescein, a symplastic probe, was applied to the cut mesocotyl base or coleoptile apex of etiolated Zea mays cv. Silver Queen seedlings and its transport measured and tissue distribution determined. Long-distance longitudinal symplastic transport of the carboxyfluorescein was mainly in the vascular stele. It moved laterally from the mesocotyl stele to the mesocotyl cortex but the presence of a weak barrier limited the movement. A partial symplastic barrier was also present near the coleoptile-mesocotyl node.     

Distribution of phytochrome and chlorophyll-a/b-binding-protein mRNAs in etiolated Avena seedlings

In 4-d-old dark-grown oat (Avena sativa L.) seedlings, the majority of the type-I-phytochrome (phyA) mRNA was found within 10 mm of the tip of the coleoptile sheath and in the mesocotyl node; almost none was detected in the enclosed primary leaf. In contrast, chlorophyll-a/b-binding-protein (cab) mRNAs were found almost exclusively in the enclosed primary leaf and were barely detectable in total-RNA samples from the coleoptile sheath or mesocotyl node of red-light-treated etiolated seedlings. Separated, dark-grown primary leaves responded to a red-light treatment by increasing cab-mRNA abundance in the absence of the coleoptile sheath or mesocotyl node tissues.Abbreviations cab gene for chlorophyll-a/b-binding protein - kb kilobase - phyA gene for type-I-phytochrome protein We are grateful to the members of the laboratory Dave Higgs, Theresa Tirimanne, Dr. Dennis Byrne, Bruce Held, Linda Barnes, Dr. Isaac John, and Iffat Rahim, for their helpful discussions and critical review. This work was supported by USDA grant No. 88-37261-4196 and No. 91-37304-6397, the Iowa State University Biotechnology Program, and the Molecular, Cellular, and Developmental Biology Program.     

Phytochrome-mediated phototropism in maize seedling shoots

Unilateral irradiation with red light (R) or blue light (BL) elicits positive curvature of the mesocotyl of maize (Zea mays L.) seedlings raised under R for 2 d from sowing and kept in the dark for 1 d prior to curvature induction. The fluenceresponse curve for R-induced mesocotyl curvature, obtained by measuring curvature 100 min after phototropic induction, shows peaks in two fluence ranges, designated first positive range (from the threshold to the trough), and second positive range (above the trough). The fluence-response curve for BL is similar to that for R but shifted two orders of magnitude to higher fluences. Blue light elicits the classical first positive curvature of the coleoptile, whereas this response is not found with R. Positive mesocotyl curvature induced by either R or BL is eliminated by R given from above just before the unilateral irradiation, whereas BL-induced coleoptile curvature is not eliminated. The above results collectively offer evidence that phototropic curvature of the mesocotyl is induced by R-sensitive photosystem(s). Mesocotyl curvature in the second positive range is reduced by vertical far-red light (FR) applied after phototropic induction with R, but is not affected by FR applied before R. Unilateral irradiation with FR following vertical irradiation with a high R fluence leads to negative curvature of the mesocotyl. It is concluded that mesocotyl curvature in the second positive range results from a gradient in the amount of the FR-absorbing form of phytochrome (Pfr) established across the plant axis. Mesocotyl curvature in the first positive range is inhibited by vertical FR given either before or after phototropic induction with R. Since the FR used here is likely to produce more Pfr than the very low fluences of R eliciting the mesocotyl curvature in the first positive range, it is assumed that FR reduces the response in this case by adding Pfr at both sides of the plant axis. By rotating seedlings on a clinostat with its axis horizontal, the kinetics of mesocotyl curvature can be studied in the absence of a counteracting gravitropic response. On the clinostat, the R-induced mesocotyl curvature develops after a lag, through two successive phases having different curvature rates, the late phase is slower than the early phase. Negative curvature of the coleoptile can be induced by either R or BL; the BL-induced negative curvature is found at fluences higher than those giving positive curvature. The clinostat experiments show that the negative coleoptile curvature induced by either R or BL is a gravitropic compensation for positive mesocotyl curvature.Abbreviations BL blue light - FR far-red light - Pfr phytochrome in the far-red-absorbing form - Pr phytochrome in the red-absorbing form - R red light C.I.W.-D.P.B. Publication No. 824     

A Critical Study of the Auxin Theory of Growth Regulation in the Mesocotyl of Avena sativa

A method of growing Avena seedlings is described, which allowsthem to be handled individually in darkness. Mesocotyls of seedlinge from which the tip of the coleoptileis repeatedly removed are as long as those of control plantsnot so decapitated. Mesocotyls of seedlings which are deseeded on the 3rd day ofgrowth, followed by decapitation of the cleoptile tip on the4th day, are, at 7 days old, as long as those of controls notso decapitated. When deseeded plants are decapitated, regeneration of auxinproduction occurs at the tip of the coleoptile stump. Where a reduction in the length of the mesocotyl results fromdecapitation, a wound reaction is probably concerned in additionto any auxin changes. Removal of the coleoptilar node causes a sharp decrease in thefinal length of the mesocotyl. Heating intact seedlings at 40° C. for 3 hours causes areduction in the length of the mesocotyl but not of the coleoptile.The effect of heating is not reversed by subsequent treatmentat low temperature, which instead appears to augment these effects. When seedlings are exposed to the action of KCN, iodoacetate,or anaerobic conditions, and illuminated while so exposed, perceptionof light takes place, resulting in a reduction in the lengthof the mesocotyl. Perception of light takes place in seedlings germinated at normaltemperatures, but maintained at low temprature during illuminationand also in seedlings grown for 6 weeks at 2° C. withoutany previous growth at normal temperature. Light perception takes place in embryos excised from dry grainand grown on a culture medium. No difference in free amino-acid content is apparent betweendark grown and illuminated seedlings. The effects of illumination survive a period of drying downand become apparent upon subsequent germination of the grainin darkness. The drying process itself causes an additionalreduction in mesocotyl length. It is concluded that auxin itself is not the primary reactantin the perception process, and that the growth of the mesocotylis probably controlled by the coleoptilar node and plumulargrowing point, rather than by auxin diffusing downward fromthe tip of the coleoptile.