Distribution and activation of the Golgi apparatus in geotropism

We find a differential distribution of dictyosomes in the avascular tip cells of the oat (Avena sativa) coleoptile upon geostimulation. A differential activation (increased vesicle production) of the dictyosomes with respect to gravity also occurs, but only in the tip cells of the lower tissues. Similar differences in distribution and activation of dictyosomes occur also in cells subjacent to the avascular tip (1st and 5th millimeter from the apex) of both the upper and lower half-tissues. When only the outer epidermal cells below the apex are considered, the differential distribution and activation of dictyosomes occur only in the lower outer epidermis. The changes in distribution of dictyosomes begin at 6 minutes, or sooner, from the start of geostimulation, before the onset of geotropism. The kinetics of amyloplast sedimentation and Golgi movement do not appear to differ in the cells of the avascular tip. We suggest that the Golgi participates in, and possibly initiates, the differential elongation of cells of geotropically stimulated coleoptiles.     

Effects of indoleacetic Acid on dictyosomes of apical and expanding cells of oat coleoptiles

We found that the auxin-induced growth is mediated through the activation of the dictyosomes (collectively, the Golgi apparatus). Incubation of oat (Avena sativa) coleoptile segments in indoleacetic acid-sucrose-phosphate buffer changes significantly the number of dictyosomes in the expanding cells. A further indication of auxin enhancement of dictyosome activity is a decrease in dictyosomal cisternae (flattened membranous sacs) number. This decrease occurred after 6 minutes of incubation in auxin, and then was followed by a reduction in the organelle number per se. These times are in keeping with the rapid action of auxin-induced cell elongaton, and the latent period of geotropism. In the apical cells, the effect of indoleacetic acid is more subtle and complex. The periods of increased dictyosome utilization and of increased dictyosome synthesis in auxin-treated segments alter with those of the control. These observations indicate that dictyosomes not only have a function in cell elongation, but also may participate in processes such as auxin transport and stimuli perception. The expanding cells have five times as many dictyosomes as the cells in the apex. Dictyosome number within a cell appears to be directly proportional to the length of the cell. The fluctuation of dictyosome number and the effect of auxin on the rate of elongation of individual outer epidermis are discussed.     

The outer epidermis of Avena and maize coleoptiles is not a unique target for auxin in elongation growth

A controversy exists as to whether or not the outer epidermis in coleoptiles is a unique target for auxin in elongation growth. The following evidence indicates that the outer epidermis is not the only auxin-responsive cell layer in either Avena sativa L. or Zea mays L. coleoptiles. Coleoptile sections from which the epidermis has been removed by peeling elongate in response to auxin. The magnitude of the response is similar to that of intact sections provided the incubation solution contains both auxin and sucrose. The amount of elongation is independent of the amount of epidermis removed. Sections of oat coleoptiles from which the epidermis has been removed from one side are nearly straight after 22 h in auxin and sucrose, despite extensive growth of the sections. These data indicate that the outer epidermis is not a unique target for auxin in elongation growth, at least in Avena and maize coleoptiles.Abbreviations IAA indole-3-acetic acid - PCIB p-chlorophenoxyiso-butyric This research was supported by grants from the National Aeronautics and Space Administration and from the U.S. Department of Energy. The help of S. Ann Dreyer is gratefully acknowledged.     

Indole-3-acetic acid and rice coleoptile elongation under anoxia

To investigate the presence of a possible synergistic effect of IAA and anaerobiosis on rice coleoptile elongation, excised coleoptiles grown in aerobic and anaerobic conditions were tested and compared with intact seedling aerial parts for response to exogenous IAA and for levels of endogenous IAA. Excised coleoptiles were fed with³H-IAA to study aerobic and anaerobic IAA metabolism. Our results can be summarized as follows. (1) IAA and anaerobiosis have no synergistic effect on rice coleoptile elongation. (2) This behavior is due not to an inhibition of IAA uptake but probably to a reduced and different IAA metabolism in coleoptile grown in the absence of oxygen. (3) In anaerobic rice coleoptiles, the conversion to inactive conjugate (IAA-Asp) could be adopted as means of detoxification in the case of abnormally high and unutilized IAA levels. (4) The increase in IAA level found in coleoptiles of intact seedlings during anaerobic treatment could be due, as in the roots, to a translocation from the endosperm, in which the hormone is contained in a great quantity.     

Is Cell Elongation Regulated by Extracellular Auxin?

Experiments with isolated epidermal strips of maize coleoptiles, pretreated with auxin and further incubated on sucrose agar containing different concentrations of auxin (indole-3-acetic acid, IAA or naphthalene-1-acetic acid, NAA) and/or naphthylphthalamic acid (NPA), are described. Preincubation for 2h with 2 . 10^?4M IAA or 10^?5M NAA in buffer, followed by 30 min wash in buffer results in measurable cell elongation during a subsequent incubation for 6 h on sucrose agar. Addition of 10^?4M NPA inhibited the response to auxin and this inhibition could be reversed by providing IAA in addition to NPA. Inner tissue fragments (without outer epidermis) did not respond to external IAA. These results lead to the conclusion that auxin secretion at the outer epidermis may be an essential step in auxin-regulated coleoptile growth.     

Effect of Peeling on IAA-induced Growth in Avena Coleoptiles

The act of peeling removes the epidermis exclusively from Avenacoleoptiles. Peeling inhibits IAA-induced growth, by inhibitingthe growth of segments incubated in the presence of IAA, andpromoting that of those incubated in water. The magnitude ofthe inhibition of IAA-induced growth is proportional to theamount of epidermis removed. It is shown that neither lateralswelling, wounding, anaerobiosis, nor exposure to supraoptimalconcentrations of IAA cause the inhibition. It is concludedthat in Avena coleoptiles the epidermis regulates the rate ofexpansion of the underlying parenchyma cells and is the principaltarget of IAA-action. Avena sativa L., oat, coleoptile, indol-3-ylacetic acid, auxin, extension growth     

RADIOAUTOGRAPHIC STUDY OF CELL WALL DEPOSITION IN GROWING PLANT CELLS

Segments cut from growing oat coleoptiles and pea stems were fed glucose-³H in presence and absence of the growth hormone indoleacetic acid (IAA). By means of electron microscope radioautography it was demonstrated that new cell wall material is deposited both at the wall surface (apposition) and within the preexisting wall structure (internally). Quantitative profiles for the distribution of incorporation with position through the thickness of the wall were obtained for the thick outer wall of epidermal cells. With both oat coleoptile and pea stem epidermal outer walls, it was found that a larger proportion of the newly synthesized wall material appeared to become incorporated within the wall in the presence of IAA. Extraction experiments on coleoptile tissue showed that activity that had been incorporated into the cell wall interior represented noncellulosic constituents, mainly hemicelluloses, whereas cellulose was deposited largely or entirely by apposition. It seems possible that internal incorporation of hemicelluloses plays a role in the cell wall expansion process that is involved in cell growth.     

Plasmodesmata, Tropisms, and Auxin Transport

Attempts were made to disrupt the plasmodesmata between oatcoleoptile cells (Avena saliva L. cv. Victory) by severe plasmolysis.Coleoptiles, allowed to regain turgor after plasmolysis, wereable to execute geotropic and phototropic curvatures and segmentswould grow in response to applied auxin. In coleoptiles similarlytreated, studies with [¹⁴C]IAA have shown that longitudinal,basipetal transport of auxin still takes place and, as in controls,IAA is preferentially redistributed laterally within coleoptilesorientated horizontally. Physical continuity of the symplast of oat coleoptile cellsmay not always be disrupted by severe plasmolysis. Nevertheless,functional continuity appears to be interrupted. Despite this,all the processes involved in the execution of tropistic curvaturesremain intact, including transport of hormones. Plasmodesmatalcontinuity between oat coleoptile cells appears not to be anecessary requirement for auxin transport.     

Rhythmicity in the Basipetal Transport of Indoleacetic Acid through Coleoptiles

¹⁴C-Indoleacetic acid was applied to coleoptiles of corn (Zea mays) and oat (Avena sativa). The coleoptiles were detached from the endosperms at 6-minute intervals after indoleacetic acid application, and the radioactivity was determined in successive 2-millimeter regions. The rate (per cent per minute) of basipetal transport of indoleacetic acid is periodic in various regions of the coleoptile, with a period of about 20 minutes. The possible relation of this cyclic phenomenon to other rhythmic processes of similar periodicities is discussed. A distinct acropetal transport (against the concentration gradient) from the subapical region to the apical 2-millimeter region of the coleoptile was detected.     

Immunohistochemical observation of indole-3-acetic acid at the IAA synthetic maize coleoptile tips

To investigate the distribution of IAA (indole-3-acetic acid) and the IAA synthetic cells in maize coleoptiles, we established immunohistochemistry of IAA using an anti-IAA-C-monoclonal antibody. We first confirmed the specificity of the antibody by comparing the amounts of endogenous free and conjugated IAA to the IAA signal obtained from the IAA antibody. Depletion of endogenous IAA showed a corresponding decrease in immuno-signal intensity and negligible cross-reactivity against IAA-related compounds, including tryptophan, indole-3-acetamide, and conjugated-IAA was observed. Immunolocalization showed that the IAA signal was intense in the approximately 1 mm region and the outer epidermis at the approximately 0.5 mm region from the top of coleoptiles treated with 1-N-naphthylphthalamic acid. By contrast, the IAA immuno-signal in the outer epidermis almost disappeared after 5-methyl-tryptophan treatment. Immunogold labeling of IAA with an anti-IAA-N-polyclonal antibody in the outer-epidermal cells showed cytoplasmic localization of free-IAA, but none in cell walls or vacuoles. These findings indicated that IAA is synthesized in the 0–2.0 mm region of maize coleoptile tips from Trp, in which the outer-epidermal cells of the 0.5 mm tip are the most active IAA synthetic cells.     

Ultrastructure of the vegetative cell ofBrassica napus pollen with particular reference to microbodies

Summary The ultrastructure of the vegetative cell ofBrassica napus tricellular pollen grains, just before anthesis with standard chemical fixation, is reported. The vegetative cell may be regarded as a highly differentiated and metabolically active fat-storage cell. It contains many mitochondria with a well developed internal membrane system, starchless plastids, microbodies, lipid bodies, dictyosomes and numerous vesicles thought to originate from the dictysomes. Rough endoplasmic reticulum organized in stacks of cisternae is also spatially associated with certain organelles, mainly lipid bodies, microbodies and plastids. There are also randomly distributed polyribosome areas. The microbodies are mainly polymorphic in shape and are often observed in contact with lipid bodies. The above spatial relationship implies that the microbodies may have a glyoxysomal function. In the late period of vegetative cell maturation, the microbodies are probably involved in the process of glyconeogenesis in which the conversion of lipid reserves to sugar takes place.Abbreviations VC vegetative cell - VN vegetative nucleus - SC sperm cell - M mitochondria - MB microbodies - L lipid body - P plastid - D dictyosomes     

Uridine and the Control of Phototropism in Oat (Avena sativa L.) Coleoptiles

The short-term growth response of oat (Avena sativa L.) coleoptiles to exogenously applied uridine was studied both in excised apical segments and in the intact seedlings. In both cases growth of coleoptile tissue was inhibited by uridine. The inhibition of coleoptile growth consistently occurred 20–30 min after uridine treatment, which is within the lag period of their phototropic response. Asymmetric application of uridine to coleoptiles in the intact seedlings resulted in their bending toward the direction to which uridine was applied in the absence of light stimulus. These findings suggest that uridine or its metabolites, plays an important role in the phototropism of oat coleoptiles and provide support to the Bruinsma–Hasegawa theory as an alternative to the Cholodny–Went theory for explaining phototropism.     

Distribution of Endogenous Indole-3-acetic Acid and Growth Inhibitor(s) in Phototropically Responding Oat Coleoptiles

The relationship between the flank growth of oat (Avena sativaL. cv. Victory) coleoptiles and the distribution of endogenousindole-3-acetic acid (IAA) and growth inhibitor(s) in the coleoptileswas studied for the second positive phototropic curvature inducedby a continuous unilateral illumination with white light (0.1W.m^–2). The phototropic curvature was caused by growthinhibition at the lighted side and growth promotion at the shadedside. Using electron capture detection gas chromatography, weanalyzed the distribution of endogenous IAA in phototropicallyresponding oat coleoptiles and found that the IAA was evenlydistributed over the lighted and shaded sides during the phototropicresponse; there was also no detectable difference in the amountsof IAA between phototropically stimulated and non-irradiatedcoleoptiles. By contrast, oat coleoptile straight-growth testresults showed that the amount of unknown acidic growth inhibitor(s),different from abscisic acid, increased in the lighted halfof the coleoptiles and decreased in the shaded half, as comparedto the amount in the non-irradiated half. These data suggestthat the phototropic curvature of oat coleoptile is inducedby a difference in lateral flank growth through a lateral gradientof endogenous growth inhibitor(s) rather than of IAA. (Received February 10, 1988; Accepted July 29, 1988)     

Ultrastructure and cytochemistry of the pearl gland in Piper regnellii (Piperaceae)

Pearl glands are scattered throughout the lamina of developing leaves and rarely found on adult leaves of Piper regnellii (Piperaceae). The pearl gland is a bicellular secretory trichome composed of a short broad basal cell and a spatula-like, semiglobular apical cell. Four different stages of the pearl gland were determined during its ontogenesis: origin, pre-secretory, secretory and post-secretory. During the pre-secretory stage, mitochondria, ribosomes, dictyosomes, rough endoplasmic reticulum, and plastids with electron dense inclusions were present in the cytoplasm of the apical cell. During the secretory stage, the most remarkable characteristics of the apical cell are the proliferation of dictyosomes and their vesicles, rough endoplasmic reticulum, and modified plastids. At this stage, electron-dense oil drops occur in the plastids as well as scattered within the cytoplasm, proteins and polysaccharides are seen in the plastids, vesicles, and vacuoles. Only polysaccharides are present in the periplasmic space, wall cavities, and on the surface of the apical cell. The polysaccharides are one of the main components of the mucilagenous exudate that covers the developing leaf structures. The apical cell of the senescing trichomes undergoes a progressive degeneration of its cellular components, the plastids being the first organelles to undergo lysis.     

Auxin Balance in the Avena Coleoptile

Coleoptiles of Avena possessed the capacity to degrade infiltrated indole-3-acetic acid (IAA). This activity decreased along the length of the coleoptile from apex to base on the bases of fresh weight, dry weight and protein; the apical 1 cm segment degraded more IAA than segments from other parts of the coleoptile. The naturally occurring inhibitor of the IAA oxidase activity increased in concentration up to 20 mm from the coleoptile apex; beyond, it decreased gradually towards the base. The spatial distribution of this inhibitor does not explain the gradient in IAA oxidase activity. Growth in length of the coleoptile and the IAA inactivating capacity of the apical 1 cm segment, increased 5- and 4,4-fold, respectively, between the ages of 70 and 130 h; but auxin secretion into agar platelets by the apical 2 mm of the coleoptile registered only a 2.7-fold increase. Deseeding and derooting the seedlings reduced the subsequent growth, diffusible auxin content and the IAA oxidase activity of the coleoptiles; derooting proved to be more deleterious than deseeding. A parallel reduction was evident in auxin content and IAA degrading activity following these treatments. Application of the cytokinin 6-benzylaminopurine (BAP) to coleoptiles of derooted seedlings failed to influence their capacity to degrade IAA. Nor was the activity of the aldehyde oxidase, which converts indole-3-acetaldehyde (IAAld) to IAA, affected by such treatment.     

Metabolism of activated oxygen in detached wheat and rye leaves and its relevance to the initiation of senescence

Pollen grains of Plumbago zeylanica L. were serially sectioned and examined using transmission electron microscopy to determine the three-dimensional organization of sperm cells within the microgametophyte and the quantity of membrane-bound organelles occurring within each cell. Sperm cells occur in pairs within each pollen grain, but are dimorphic, differing in size, morphology and organelle content. The larger of the two sperm cells (S_vn) is distinguished by the presence of a long (approx. 30 m) projection, which wraps around and lies within embayments of the vegetative nucleus. This cell contains numerous mitochondria, up to two plastids and, infrequently, microbodies. It is characterized by a larger volume and surface area and contains a larger nucleus than the other sperm cell. The second sperm cell (S_ua) is linked by plasmodesmata with the S_vn, but is unassociated with the vegetative nucleus. It is smaller and lacks a cellular projection. The S_ua contains relatively few mitochondria, but numerous (up to 46) plastids and more microbodies than the other sperm. The degree of dimorphism in their content of heritable cytoplasmic organelles must at fertilization result in nearly unidirectional transmission of sperm plastids into just one of the two female reproductive cells, and preferential transmission of sperm mitochondria into the other.Abbreviations S_ua sperm cell unassociated with the vegetative nucleus - S_vn sperm cell physically associated with the vegetative nucleus 1=Russell and Cass (1981)     

Gravitropism and Phototropism of Maize Coleoptiles: Evaluation of the Cholodny-Went Theory Through Effects of Auxin Application and Decapitation

It was investigated whether or not gravitropism and phototropismof maize (Zea mays L.) coleoptiles behave as predicted by theCholodny-Went theory in response to auxin application, decapitationand combinations of these treatments. Gravitropism was inducedat an angle of 30° from the vertical, and phototropism,by a pulse of unilateral blue light. Either tropism of the coleoptilewas inhibited by IAA, applied as a ring of IAA-lanolin pasteto its sub-apical part, and by decapitation. The dose-responsecurves for the effects of applied IAA on tropisms and growthof intact coleoptiles as well as the time courses of tropismsinduced in decapitated coleoptiles could be explained by thethree conclusions in the literature: (1) the tip of the coleoptileis the site of auxin production, (2) lateral translocation ofauxin in gravitropism occurs along the length of the coleoptile,and (3) lateral translocation of auxin in phototropism occursin the coleoptile tip. By examining the effects of decapitationmade at different distances from the top and of IAA appliedto the cut surface of decapitated coleoptiles, it was indicatedthat auxin is produced in the apical 1 mm zone of an intactcoleoptile and that lateral auxin translocation for phototropismtakes place in an apical part that somewhat exceeds the zoneof auxin production. (Received October 14, 1994; Accepted December 26, 1994)     

The quantitative ultrastructure of the pea shoot apex in relation to leaf initiation

Summary The ultrastructure of the pea shoot apical meristem was examined quantitatively in longitudinal sections. Photographs were taken at eleven defined positions in the apex, at six developmental stages within a single plastochron. The only change in ultrastructure during the period of a single plastochron was the increase in the proportion of plastids with starch in the central regions of the apex and in the young leaf axils. This increase occurred midway in time between the emergence of successive leaves, at precisely the time that the orientation of growth changes in the region where a new leaf is to emerge. There were quantitative changes in ultrastructure associated with cell differentiation. In the sequence of cell development from the summit of the apex (central zone) to the incipient pith, cell enlargement was accompanied by an increase in the volume of endoplasmic reticulum, dictyosomes, microbodies and vacuoles per cell, an increase in the number of mitochondria, microbodies and vacuoles per cell, and an increase in the volume, but not the number, of plastids per cell. In the sequence of axillary development (before the axillary bud begins to grow) the number of mitochondria per cell decreased as cell volume decreased but the number of plastids per cell remained constant. The number of plastids per cell increased only in the developmental sequence leading to leaf development, in which the number of mitochondria and dictyosomes per cell also increased. There appeared to be no features of ultrastructure, qualitative or quantitative, which could be correlated with the different rates of cell division in different regions of the meristem. The differences in ultrastructure throughout the apex were mainly quantitative and seemed to be associated with cellular differentiation rather than with the plastochronic functioning of the apex during leaf initiation.     

The antagonism of IAA-induced hydrogen ion extrusion and coleoptile growth by diclofop-methyl

Diclofop-methyl (DM) (ester) was readily absorbed by peeled and unpeeled coleoptiles of wheat, Triticum aestivum L. cv. Waldron, and oat, Avena sativa L. cv. Garry. Substantial absorption of diclofop (acid) occurred only in peeled coleoptiles of the two species. IAA-induced acidification in peeled coleoptiles of both species was inhibited by 100 μ M DM or diclofop (acid) during a 3 to 4 h period. There was no recovery of acidification after DM or diclofop inhibition in oat coleoptiles; however, acidification in wheat coleoptiles recovered from inhibition by DM but not from diclofop. The recovery from DM inhibition may be due to a reduction in the diclofop pool derived from DM by efflux and metabolism (detoxification) in peeled wheat coleoptiles. Diclofop was not detoxified in oat coleoptiles. IAA-induced elongation of unpeeled oat coleoptiles was inhibited totally by 100 μ M DM but not by 100 μ M diclofop after 3.3 h of treatment. Wheat coleoptile elongation was relatively unaffected by either DM or diclofop. Basal elongation (no IAA) of both wheat and oat coleoptiles was inhibited by DM and diclofop. The inhibition by DM appeared to be irreversible, whereas the inhibition by diclofop was overcome by the addition of 10 μ M IAA.     

Inhibition of the Coleoptile Growth in Avena sativa by Endosperm Removal--Changes in Auxin, Osmotica and Cell Wall

Removal of the endosperm from 84-h-old etiolated oat seedlingsstrongly retarded the subsequent growth of coleoptiles. Thecontribution of the endosperm to coleoptile growth was studied.Endosperm removal was found to: (1) decrease the endogenouslevel of indole-3-acetic acid (IAA) in the coleoptile tip. IAAapplied to the coleoptile tip stimulated coleoptile growth inseedlings with and without the endosperm. The sensitivity ofthe coleoptile to a suboptimal concentration of IAA was higherin seedlings without the endosperm than in intact ones. At theoptimal concentration of IAA, however, the final length of thecoleoptile was larger in intact seedlings than in those withoutthe endosperm. (2) decrease the concentration of the solublesugars and amino acids in the cell sap. (3) retard the increasein the amount of polysaccharides in the cell wall of the coleoptile,particularly noncellulosic ones. (4) make the cell wall mechanicallyrigid according to stress-relaxation analysis of the cell wall.(5) induce an increase in the osmotic potential of the coleoptilecell sap. From these results, it was concluded that the endosperm suppliesthe coleoptile with IAA, sugars and amino acids, thus promotingcoleoptile growth. (Received September 24, 1987; Accepted February 3, 1988)