Differential effect of auxin on in vivo extensibility of cortical cylinder and epidermis in pea internodes

The effect of auxin indole-3-acetic acid (IAA) on growth and in vivo extensibility of third internode sections from red light grown pea seedlings (Pisum sativum L. cv Alaska) and the isolated tissues (cortex plus vascular tissue = cortical cylinder, and epidermis) was investigated. Living tissue was stretched at constant force (creep test) in a custom-built extensiometer. In the intact section, IAA-induced increase in total (E_tot), elastic (E_el), and plastic (E_pl) extensibility is closely related to the growth rate. The extensibility of the cortical cylinder, measured immediately after peeling of intact sections incubated for 4 hours in IAA, is not increased by IAA. Epidermal strips, peeled from growing sections incubated in IAA, show a E_pl increase, which is correlated to the growth rate of the intact segments. The isolated cortical cylinder expands in water; IAA has only a small growth-promoting effect. The extensibility of the cortical cylinder is not increased by IAA. Epidermal strips contract about 10% on isolation. When incubated in IAA, they do not elongate, but respond with an E_pl increase. The amount of expansion of the cortical cylinder and contraction of the epidermis (tissue tension), measured immediately following excision and peeling, stays constant during IAA-induced growth of intact sections. The results support the hypothesis that IAA induces growth of the intact section by causing an E_pl increase of the outer epidermal wall. The driving force comes from the expansion of the cortical cylinder which is under constant compression in the intact section.     

Epidermis integrity and epicotyl growth in azuki bean

In order to verify if epidermis integrity played a determinant role in epicotyl elongation induced by fusicoccin (FC), buffers at different pH's, and indoleacetic acid (IAA), we studied the short-term kinetics of elongation growth, the increase of fresh weight in long-term treatment, and the H⁺ excretion in intact, abraded, and peeled azuki bean epicotyl sections. We demonstrated that the epidermis is more sensitive to IAA, whereas the cortex is highly responsive to protons. Our data are consistent with the acid growth theory. In addition, our studies support the idea that the epidermis may be the tissue target for auxin, but its integrity is necessary for IAA-induced elongation.     

Growth, in vivo extensibility, and tissue tension in developing pea internodes

The relationship between growth, in vivo extensibility, and tissue tension in the first 3 internodes of 5, 6, and 7 day-old pea plants (Pisum sativum L. cv Alaska), grown under continuous red light was investigated. The upper 15 millimeters of each internode was marked with ink and its elongation growth measured over the next subsequent 8 hours. In vivo extensibility was measured by stretching living tissue at constant force (creep test) in a custom-built extensiometer. Tissue tension was determined by (a) measuring the rate of expansion of the isolated cortical cylinder after adding water and the amount of contraction of the epidermis after peeling, and (b) by use of the `split section test.' A good correlation between rate of elongation growth, in vivo extensibility, and tissue tension was established. The epidermis peeled from the growing third internode of 7 day-old plants and measured immediately showed a plastic extensibility (E<sub>pl</sub> twice that of peels from nongrowing excised sections. This high E<sub>pl</sub>-value was lost on incubation of the sections in distilled water, and was subsequently restored by incubating the sections in auxin (indole-3-acetic acid). We conclude that the in situ growth of the internodes is a function of tissue-tension, which provides the driving force of organ growth, and the extensibility (E<sub>pl</sub> of the outer epidermal wall, which is in the growing plant in a `loosened' state. We furthermore suggest that in the intact plant auxin is causally involved in the wall loosening process in the epidermis.     

The role of the epidermis in auxin-induced and fusicoccin-induced elongation of Pisum sativum stem segments

The effects of peeling and wounding on the indole-3-acetic acid (IAA) and fusicoccin (FC) growth response of etiolated Pisum sativum L. cv. Alaska stem tissue were examined. Over a 5 h growth period, peeling was found to virtually eliminate the IAA response, but about 30% of the FC response remained. In contrast, unpeeled segments wounded with six vertical slits exhibited significant responses to both IAA and FC, indicating that peeling does not act by damaging the tissue. Microscopy showed that the epidermis was removed intact and that the underlying tissue was essentially undamaged. Neither the addition of 2% sucrose to the incubation medium nor the use of a range of IAA concentrations down to 10^-8 M restored IAA-induced growth in peeled segments, suggesting that lack of osmotic solutes and supra-optimal uptake of IAA were not important factors over this time period. It is concluded that, although the possibility remains that peeling merely allows leakage of hydrogen ions into the medium, it seems more likely that peeling off the epidermis removes the auxin responsive tissue.Abbreviations IAA indole-3-acetic acid - FC fusicoccin     

Differential Effect of Auxin on Molecular Weight Distributions of Xyloglucans in Cell Walls of Outer and Inner Tissues from Segments of Dark Grown Squash (Cucurbita maxima Duch.) Hypocotyls

Effects of indole-3-acetic acid (IAA) on the mechanical properties of cell walls and structures of cell wall polysaccharides in outer and inner tissues of segments of dark grown squash (Cucurbita maxima Duch.) hypocotyls were investigated. IAA induced the elongation of unpeeled, intact segments, but had no effect on the elongation of peeled segments. IAA induced the cell wall loosening in outer tissues as studied by the stress-relaxation analysis but not in inner tissues. IAA-induced changes in the net sugar content of cell wall fractions in outer and inner tissues were very small. Extracted hemicellulosic xyloglucans derived from outer tissues had a molecular weight about two times as large as in inner tissues, and the molecular weight of xyloglucans in both outer and inner tissues decreased during incubation. IAA substantially accelerated the depolymerization of xyloglucans in outer tissues, while it prevented that in inner tissues. These results suggest that IAA-induced growth in intact segments is due to the cell wall loosening in outer tissues, and that IAA-accelerated depolymerization of hemicellulosic xyloglucans in outer tissues is involved in the cell wall loosening processes.     

The Epidermis of the Pea Epicotyl Is Not a Unique Target Tissue for Auxin-Induced Growth

Previous research has suggested that the epidermis of dicotyledonous stems is the primary site of auxin action in elongation growth. We show for pea (Pisum sativum L.) epicotyl sections that this hypothesis is incorrect. In buffer (pH 6.5), sections from which the outer cell layers were removed (peeled) elongated slowly and to the same extent as intact sections. Addition of 10 micromolar indoleacetic acid to this incubation medium caused peeled sections to grow to the same extent and with the same kinetics as auxin-treated nonpeeled sections. This indicates that both epidermis and cortical tissues have the ability to respond rapidly to auxin and that the epidermis is not the sole site of auxin action in dicotyledonous stems. Previous reports that peeled pea sections respond poorly to auxin may have resulted from an acid extension of these sections due to the use of distilled water as the incubation medium.     

Effect of salt on auxin-induced acidification and growth by pea internode sections

The capacity of excised internode sections of pea to grow and secrete protons in response to indoleacetic acid (IAA) and Ca²⁺ and K⁺ treatments was examined. By incubating unpeeled and unabraded sections in rapidly flowing solutions, it was shown that acidification of the external medium in the presence or absence of IAA is dependent on the presence of Ca²⁺ and K⁺. Similar results were obtained when unpeeled and unabraded sections were incubated in dishes with shaking. When peeled or abraded sections were incubated with shaking in IAA, H⁺ release was also dependent on the presence of Ca²⁺ and K⁺. The release of H⁺ from sections incubated in Ca²⁺ and K⁺ is not caused by displacement of H⁺ from binding sites in the cell wall. Rather, the release of protons from sections is temperature dependent, and it is concluded that this is a metabolically linked process. Although Ca²⁺ and K⁺ are essential for the release of H⁺ from isolated stem sections of peas, these cations do not influence elongation. Despite the large increase in proton release induced by Ca²⁺ and K⁺ either in the presence or absence of auxin, growth in the presence of these ions was never greater than it was in their absence. Furthermore, cations do not affect the neutral sugar or uronic acid composition of the solution which can be centrifuged from isolated sections. As is the case for growth, an increase in the neutral sugar and uronide composition of the cell wall solution is dependent only on IAA. It is concluded that IAA-induced growth of pea stem sections is independent of the secretion of protons.     

Relationships between auxin- and acid-induced growth in Vigna radiata hypocotyl segments

The H⁺- and IAA-induced growth responses of isolated Vigna radiata (L.) Wilczek hypocotyl segments were investigated concurrently with IAA-induced H⁺ excretion. The effects of external pH on these reactions were also studied. Experiments were performed with intact, peeled and abraded segments. Only abraded segments reacted to H⁺ and to IAA. In short-term experiments, the cuticle prevented proton efflux and influx; however, it allowed gradual ion movements which become measurable after 1 h. Both phases of the IAA growth response reacted to external pH. The interactions between these two phases and their pH dependencies are discussed.     

A Possible Regulation of Ethylene Production by the Epidermis in Mung Bean Hypocotyl Sections

IAA-induced and l-aminocyclopropane-l-carboxylic acid (ACC)-dependentethylene production in etiolated mung bean (Vigna radiata [L]Wilczek) hypocotyl sections does not occur in epidermal cells(Todaka and Imaseki 1985). Mung bean hypocotyls contain a proteinwhich inhibits auxin-induced ethylene biosynthesis in hypocotylsections (Sakai and Imaseki 1975a, b). This inhibitory proteinwas also found to inhibit ACC-dependent ethylene productionin hypocotyl sections, but not in hypocotyl sections from whichthe epidermis had been removed. Uptake of ACC by both unpeeledand peeled sections was not inhibited by the protein. Similarly,IAA-induced ethylene production was inhibited by the proteinin unpeeled hypocotyl sections, but not in peeled sections.The protein was not inactivated in peeled sections, as proteinsynthesis by peeled sections was inhibited to the same extentas in unpeeled sections. The protein inhibited incorporationof 3,4-[¹⁴C]-methionine into ACC and ethylene in unpeeled sections,but not in peeled sections, whereas oxidation of the labeledmethionine into CO₂ was inhibited by the protein to a similarextent in both types of hypocotyl sections. KCN, a potent inhibitorof ethylene production, inhibited both IAA-induced and ACC-dependentethylene production in both peeled and unpeeled hypocotyl sections.It is likely that the epidermis plays some role in controllingethylene production which occurs in stem cells other than epidermalcells. (Received July 16, 1985; Accepted October 21, 1985)     

Interactions of phenolic acids, metallic ions and chelating agents on auxin-induced growth

By growth experiments in indoleacetic acid-1-¹⁴C (IAA), and determination of the ¹⁴CO₂ evolved, it has been shown directly that polyphenols synergize IAA-induced growth by counteracting IAA decarboxylation. Sinapic and ferulic acids act like polyphenols. Endogenous polyphenols doubtless exert the same influence in intact plants. Monophenols stimulate the decarboxylation of IAA under conditions where they depress growth. When Mn⁺⁺ is present as well, this effect is enhanced. All these growth effects are paralleled by effects on the isolated IAA oxidizing enzyme of Avena.     

Role of cell-wall biogenesis in the initiation of auxin-mediated growth in coleoptiles of Zea mays L.

The involvement of cell-wall polymer synthesis in auxin-mediated elongation of coleoptile segments from Zea mays L. was investigated with particular regard to the growth-limiting outer epidermis. There was no effect of indole acetic acid (IAA) on the incorporation of labeled glucose into the major polysaccharide wall fractions (cellulose, hemicellulose) within the first 2 h of IAA-induced growth. 2,6-Dichlorobenzonitrile inhibited cellulose synthesis strongly but had no effect on IAA-induced segment elongation even after a pretreatment period of 24 h, indicating that the growth response is independent of the apposition of new cellulose microfibrils at the epidermal cell wall. The incorporation of labeled leucine into total and cell-wall protein of the epidermis was promoted by IAA during the first 30 min of IAA-induced growth. Inhibition of IAA-induced growth by protein and RNA-synthesis inhibitors (cycloheximide, cordycepin) was accompanied by an inhibition of leucine incorporation into the epidermal cell wall during the first 30 min of induced growth but had no effect on the concomitant incorporation of monosaccharide precursors into the cellulose or hemicellulose fractions of this wall. It is concluded that at least one of the epidermal cell-wall proteins fulfills the criteria for a growth-limiting protein induced by IAA at the onset of the growth response. In contrast, the synthesis of the polysaccharide wall fractions cellulose and hemicellulose, as well as their transport and integration into the growing epidermal wall, appears to be independent of growth-limiting protein and these processes are therefore no part of the mechanism of growth control by IAA.Abbreviations CHI cycloheximide - COR cordycepin - DCB 2,6-dichlorobenzonitrile - GLP growth-limiting protein(s) - IAA indole-3-acetic acid     

Comparison of the effect of some phenolic compounds on wheat coleoptile section growth with their effect on iaa-oxidase activity

P-coumaric acid (HCA), 2,4-dichlorophenol (DCP) and resorcionol acted as cofactors for IAA-oxidase isolated from young wheat plants. Ferulic acid (FA) and 3,4-dihydroxybenzoic acid (DHBA) induced a lag phase prior to IAA oxidation. HCA, FA (0.2-1 mg ml^-1) and DCP (0.03-1 mg ml^-1) strongly inhibited wheat coleoptile section growth. DHBA (0.01-1 mg ml^-1) slightly stimulated it and resorcinol was without effect. HCA inhibited IAA-induced growth of coleoptile sections and FA stimulated it at low IAA levels and inhibited it at higher ones. DHBA, DCP and resorcinol did not affect IAA-induced growth of coleoptile sections.     

Studies on the role of RNA synthesis in auxin induction of cell enlargement

Selective inhibitors were used to study the connection between nucleic acid synthesis and indoleacetic acid (IAA) induction of cell enlargement. Actinomycin D (act D) and azaguanine (azaG) almost completely inhibit IAA-induced growth in aged artichoke tuber disks when they are added simultaneously with IAA. In contrast, when they are added 24 hours after the hormone, these inhibitors have little or no effect on the induced growth which continues for 48 hours or more with little or no inhibition. Inhibitors of protein synthesis still stop growth when applied 24 hours after the IAA, thus protein synthesis and presumably supporting metabolism are still essential.

In corn coleoptile sections auxin-induced growth did not show any pronounced tendency to become less sensitive to act D as the IAA treatment progressed. Act D did not completely inhibit the response to IAA unless the sections were pretreated with act D for 6 hours. In contrast to act D, cordycepin produced almost complete inhibition of IAA-induced growth when added with the IAA.

Although IAA has a very large and very rapid stimulatory effect (within 10 min) on incorporation of ³²P-orthophosphate into RNA in disks, it did not cause a detectable change in the base composition of the RNA synthesized. Furthermore, the promotive effect could be accounted for through increased uptake of the ³²P. That much of the RNA synthesis in these tissues is not necessary for auxin action is indicated by the results with fluorouracil (FU). FU strongly inhibits RNA synthesis, probably acting preferentially on ribosomal RNA synthesis, without inhibiting auxin-induced growth in the disks or coleoptile sections. FU also strongly inhibited respiration in auxin-treated disks indicating that the large promotion of respiration by auxin likewise may not be entirely necessary for growth.

At least in the artichoke disks, RNA synthesis is required for auxin induction of cell enlargement and not for cell enlargement itself.

The possible relationships of auxin induction of cell enlargement and RNA synthesis are discussed.

     

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     

Biphasic response of cucumber hypocotyl sections to auxin

The pattern of the response to auxin of cucumber hypocotyl sections,its relation to acid-induced growth and the role of the epidermiswere investigated. In longterm incubation, IAA had practicallyno effect on sections without epidermis (peeled sections). Timecourse measurementsshowed that the response to IAA of nonpeeledsections was biphasic; the first phase started right after IAAtreatment and continued for about 1 hr, then after a periodof 1 hr with a greatly decreased growth rate the second phasestarted with a higher rate. Peeled sections lacked thesecondphase; their growth rate in the first phase depended on theacidity of the incubation medium. These results were confirmedby utilizing one side-peeled sections and measuring the curvatureof the sections which represented the difference in the growthrate between the peeled and nonpeeled sides. The following pointswere suggested. The first phase resembles acid-induced growthand the growth capacity is limited by the epidermis; the secondphase is specific to auxin and requires the presence of theepidermis. The first phase was hardly influenced by temperature,while the second one was greatly affected; its Q,₁₀ being morethan 4.0, suggesting that the first phase is of physical nature. (Received December 26, 1975; )     

Inhibiting Effect of Auxin on Glucosamine Incorporation into Cell Walls of Rice Coleoptiles

Auxin induced growth and decreased the hexosamine content ofthe cell walls of rice coleoptile sections. Indole-3-aceticacid (IAA) at 10^–5 M inhibited the incorporation of ¹⁴C-glucosamineinto the cell walls. IAA did not affect the ¹⁴C-incorporationinto the cytoplasm, while inhibitors of glycoprotein synthesis,unicamycin and monensin, suppressed the incorporation into boththe cytoplasm and the cell walls. The radioactivity due to labeledglucosamine in the cell walls increased during the chase, butthis increase was inhibited by IAA. Among the cell wall fractions,the increase in radioactivity and its inhibition by IAA wereconspicuous in the hemicellulose I fraction. The inhibitoryeffect of IAA on glucosamine incorporation into the cell wallswas observed even in the presence of 0.15 M mannitol solutionwhich completely suppressed the IAA-induced growth. These resultssuggest that auxin induces growth at least partly by inhibitingthe transport of asparagine-linked glycoproteins from the cytoplasmto the cell walls. ¹ Present address: Department of Biology, Faculty of Science,Osaka City University, Sumiyoshi-ku, Osaka 558, Japan (Received July 23, 1986; Accepted December 22, 1986)     

Indoleacetic Acid-Induced Decrease of the Ribomiclease Activity in vivo

A study has been made on the influence of indole-3-acetic acid (IAA) on the ribonuclease (RNase) activity in wheat coleoptile sections and green pea stem sections. The hormonal effects on the enzyme activity, ribonncleic acid (RNA) metabolism and growth have been compared. Addition of 10^?5M IAA to the plant sections causes their RNase activity to decrease and their elongation to increase. Removal of the added IAA results in increasing enzyme activity and decreasing growth. The altered enzyme activities are paralleled by opposite changes in the RNA net synthesis. Administration of crystalline RNase to the plant tissue depresses growth. There is thus evidence that the in vivo effect of IAA on the RNase activity is of importance for the hormonal regulation of RNA metabolism and growth. The IAA-induced reduction in the enzyme activity involves cellular metabolism. The effect can be suspended by means of p-chloromercuribenzoate. A possible mechanism for the reduction is discussed.     

Auxin-induced leaf blade expansion in Arabidopsis requires both wounding and detachment

Elevation of leaf auxin (indole-3-acetic acid; IAA) levels in intact plants has been consistently found to inhibit leaf expansion whereas excised leaf strips grow faster when treated with IAA. Here we test two hypothetical explanations for this difference in growth sensitivity to IAA by expanding leaf tissues in vivo versus in vitro. We asked if, in Arabidopsis, IAA-induced growth of excised leaf strips results from the wounding required to excise tissue and/or results from detachment from the plant and thus loss of some shoot or root derived growth controlling factors. We tested the effect of a range of exogenous IAA concentrations on the growth of intact attached, wounded attached, detached intact, detached wounded as well as excised leaf strips. After 24 h, the growth of intact attached, wounded attached, and detached intact leaves was inhibited by IAA concentrations as little as 1 µM in some experiments. Growth of detached wounded leaves and leaf strips was induced by IAA concentrations as low as 10 µM. Stress, in the form of high light, increased the growth response to IAA by leaf strips and reduced growth inhibition response by intact detached leaves. Endogenous free IAA content of intact attached leaves and excised leaf strips was found not to change over the course of 24 h. Together these results indicate growth induction of Arabidopsis leaf blade tissue by IAA requires both substantial wounding as well as detachment from the plant and suggests in vivo that IAA induces parallel pathways leading to growth inhibition.     

Effect of inhibition of protein glycosylation on auxin-induced growth and the occurrence of osmiophilic particles in maize (Zea mays L.) coleoptiles

The dependence of auxin (IAA)-induced elongation growth on proteinglycosylation was investigated in abraded maize (Zea mays L.)coleoptile segments, employing 2-deoxy-D-glucose (DOG) and tunicamycin(TUM) as inhibitors of protein glycosylation. TUM had no detectableeffect on growth at 100µg ml^–1. DOG impaired growthat concentrations larger than 1 mM. Total inhibition of growthoccurred at a concentration of 20 mM. Similar effects were observedwith mannose and glucosamine. The effect on wall-synthetic processesin the growth-limiting epidermis was analysed by tracer incorporationstudies. Within 30 min hemicellulose and cellulose synthesis,measured as ³H-glucose incorporation, was not affected by DOG,indicating that inhibition of growth is not causally relatedto synthesis of both wall components. In contrast, protein synthesisand secretion into the walls, measured as incorporation of ³H-leucineinto the TCA-precipitable protoplasmic and wall-bound protein,was rapidly inhibited by DOG. Concomitant with the effect ongrowth, DOG as well as mannose inhibited the occurrence of osmiophilicparticles (OPs) which specifically occur at the growth-limitingepidermis during IAA-induced growth. The results provide evidencethat IAA-induced wall loosening underlying elongation growthis dependent on O-glycosylation of proteins and their subsequentsecretion into the epidermal walls. It appears that interferencewith these processes is responsible for inhibition of IAA inducedgrowth by hexoses acting as anti-glucose antimetabolites. Key words: Auxin-induced growth, cell-wall synthesis, 2-deoxy-D-glucose, mannose, osmiophilic particles, tunicamycin     

Effect of cycloheximide on IAA-induced proton excretion and IAA-induced growth in abraded Avena coleoptiles

IAA-induced proton excretion in peeled or abraded oat ( Avena saliva L. cv. Victory) coleoptiles is closely associated with IAA-induced growth. It was attempted to separate these two processes by using cycloheximide to inhibit them differentially. Growth of abraded coleoptile segments was measured by a shadow graphic method, and their IAA-induced acidification of the external solution was monitored with a pH meter. IAA stimulated proton excretion in abraded Avena coleoptile segments after a 13 min lag. IAA-induced proton excretion was inhibited within 5 min by cycloheximide at concentrations of 1.8 × 10⁻⁶, 3.6 × 10 or 3.6 × 10⁻⁵ M. Cycloheximide at these concentrations, added within 4 min of IAA, prevented IAA-induced acidification of the medium for at least 60 min. However, it did not prevent IAA-induced growth during this time. It is concluded that some of the initial IAA-induced growth seen in Avena coleoptiles is independent of detectable IAA-induced proton excretion.