Effects of IAA on oxygen-sensitive growth and on hydroxyproline protein level in cell wall

Indole-3-asscetic acid (IAA) accelerated the incorporation ofradioactivity derived from ¹⁴C-proline into the SLS-insolublecell wall fraction only when the sections were exposed to lowoxygen concentrations. However, IAA showed no effect on theratio of hydroxyproline to proline incorporated into the SLS-insolublefraction in both 20% and 8% O₂-treated sections. The amountof hydroxyproline rigidly bound to the cell wall increased withincreasing IAA concentration in 8% O₂-treated sections, whilethat of the 20% O₂-treated ones decreased with IAA treatment. On the other hand, IAA increased the amount of ¹⁴C-labeled hydroxyprolineincorporated into the SLS-insoluble fraction of sections treatedwith cycloheximide, and their elongation was greatly inhibited. Based on the results that O₂ and IAA affect the auxin-inducedand the oxygen- sensitive growth differently, we suggest thatboth types of growth may antagonize each other in response tochanges in O₂ and IAA concentrations, resulting in balancedgrowth in the cell. (Received October 7, 1977; )     

A possible role of hydroxyproline-protein in oxygen-sensitive growth

Exposure of Avena coleoptile sections to 8% O₂ brought aboutrespiration decrease, resulting in a decrease of ATP production.The pH at the cell wall surface slightly rose in sections exposedto 8% O₂, while their growth was greatly accelerated. Moreover,this growth acceleration was observed even in sections treatedwith CCCP known to make membranes permeable for protons. Weconcluded that the growth acceleration with reduction of O₂concentration is probably not the result of secretion of H₊ions into cell wall compartments. Results of this study provided evidence to support the hypothesisthat there is an inverse relationship between hydroxyproline-proteinlevel and the ability of a cell to undergo rapid cell elongation.Total labeling of the cell wall fraction with ¹⁴C-proline wasunaffected by 8% O₂ treatment, although the radioactivitiesof hydroxyproline incorporated into this fraction during thetreatments fell to about 45% of the control. Moreover, the radioactivitiesof hydroxyproline incorporated into the SLS-insoluble cell wallfraction of sections exposed to 8% O₂ decreased to about 30%of the control. This decrease of hydroxyproline was also observedin sections treated with cycloheximide, which inhibits the secretionof H₊ ions into the cell wall compartment. Reduction of O₂ concentrationin the surrounding atmosphere affects not only the hydroxylationof peptidyl proline, but also the binding of hydroxyproline-protein(s)to cell wall polysaccharides, and the resulting decrease ofthe protein rigidly bound to them may induce cell elongation. (Received December 5, 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)     

Auxin Changes Both the Extensibility and the Yield Threshold of the Cell Wall of Vigna Hypocotyls

Elongation of plant stem is governed by two simultaneous processes:irreversible yielding of the cell wall and uptake of water.Among many candidates for the parameters that regulate and/or restrict growth, we focused on the mechanical propertiesof the cell wall and determined those parameters that governthe process of IAA-induced growth by means of the pressure-jumpmethod combined with the pressure-probe technique. The elongation growth of segments excised from the elongationzone of Vigna hypocotyls was accelerated by xylem perfusionwith 10^–4 M IAA. During the promotion of growth, boththe extensibility () of the cell wall and the effective turgor(Pⁱ–Y) increased while only a little or no change in theintracellular pressure (Pⁱ) occurred. These results indicate that IAA increases not only the extensibilityof the cell wall but also the effective turgor, i.e., the drivingforce for yielding of the cell wall. However, the driving forceis not increased by the increase in Pⁱ but by the decrease inthe yield threshold (Y). These results suggest that Y is adjustableduring the regulation of growth. ¹Present address: Department of Biology, Faculty of Science,Okayama University, Okayama, 700 Japan (Received September 20, 1990; Accepted November 27, 1990)     

Proline-14C metabolism in barley seedlings during vernalization

The metabolism of proline-¹⁴C was examined in vernalized (LT)and unvernalized (HT) barley shoots. The content of prolinein cytoplasmic and cell wall protein fractions was a littlehigher in HT, against the accumulation of free proline in LT.Proline-¹⁴C was more heavily incorporated into HT and the cytoplasmicprotein had a higher radioactivity than the cell wall protein.In LT, the activity in the cytoplasmic protein was lower thanthat in the cell wall. The time course of incorporated proline-¹⁴Cshowed no distinct changes in HT. but decreased remarkably inthe LT cell wall. The distribution of proline-¹⁴C in hydroxyproline and otheramino acids in the two proteins was examined. In the cytoplasmicproteins, the conversion pattern of proline-¹⁴C was very similarin both treatments. The highest hydroxyproline activity wasfound at the beginning of incubation and was maintained at acomparatively high level in the HT cell wall. The LT cell wallshowed a gradual increase in radioactivity due to hydroxyprolineand reached maximum conversion at the last incubation period.Distribution of radioactivity due to incorporated proline-¹⁴Cwas examined by separating barley shoot tissues into three sections. (Received December 5, 1972; )     

Boron deficiency effects on peroxidase, hydroxyproline, and boron in cell walls and cytoplasm of Helianthus annuus L. hypocotyls

Boron-deficient sunflower hypocotyls have, on a fresh weightbasis, more cytoplasmic and cell wall peroxidase, more cytoplasmichydroxyproline but equal cell wall hydroxyproline, and slightlyless cell wall boron, than controls. Incubation of either Bdeficientor control cell wall suspensions with Sclerotium rolfsii culturenitrate released 80% of the peroxidase activity, but only 14to 30% of the hydroxyproline. This differential extraction suggeststhat the hydroxyproline-containing protein of cell walls isnot identical with peroxidase. Boron deficiency increased thesusceptibility of cell walls to degradation by fungal enzymes,as measured by release of peroxidase and hydroxyproline, butnot by reduction in dry weight. ¹Scientific article No. A1847, Contribution No. 4756 of theUniversity of Maryland Agricultural Experiment Station. Thisresearch represents part of a thesis for the M.S. degree, Universityof Maryland, by J.B.S., Jr. This paper is dedicated to ProfessorHugh G. Gauch on the occasion of his sixtieth birthday. (Received December 5, 1972; )     

Effects of 3-Indolylacetic Acid and 3-Indolylacetonitrile on the Growth of Excised Tomato Roots

1. The inhibition by IAA (3-indolylacetic acid) and by IAN (3-indolylacetonitrile)of the growth of excised tomato roots cultured for 7 days at27 C. in a modified White's medium is described. 510^–9g./ml, IAA or 510^–6 g./ml, IAN cause approx, 50 per cent,inhibition of the linear growth of the main axis. With IAA decreasein number of laterals closely parallels the decrease in lineargrowth of the main axis; with IAN reduction in linear growthof the main axis occurs at concentrations above 10^–8 whereasnumber of laterals does not decrease until the concentrationexceeds 10^–6.
2. Study of the course of cell elongationin the exodermal cellsshowed that in the standard medium andin media containing 510^–9IAA or 510^–6 IAN theprocess takes about 7 hours; thefinal cell lengths in IAA andIAN media are lower than in standardmedium owing to a slowerrate of elongation. The decrease inlinear growth of the mainaxis in presence of IAA could be accountedfor by the decreasein cell length; this was not the case withIAN. The implicationsof this are considered.
3. Determinations of the distance (mm.)between, and of the numberof exodermal cells separating, theadjacent laterals in oneorthostichy showed that IAN enhancesthe frequency of lateralswhereas this is either unaffectedor decreased by IAA. The enhancementof lateral frequency inIAN arises from shortening of the cellsof the main axis anddecrease in the number of cells separatingadjacent laterals.
4. The results are considered to support the view that IAN haseffects on root growth different from those of IAA. Study ofthe degree of inhibition of main axis growth and of alterationsin lateral frequency resulting from treatment with mixturesof IAA and IAN provided data which could also be most easilyexplained on this hypothesis.

     

In Vitro Phosphorylation of Proteins in IAA-Treated Mesocotyls in Zea mays

Five-mm sections of elongation zones of Zea mesocotyls wereincubated for designated periods with various concentrationsof IAA. In vitro protein phosphorylation in the soluble fraction(85,000 x g supernatant) prepared from the sections was analyzedby sodium dodecyl sulfate-polyacrylamide gel electrophoresis.The phosphorylation of proteins in the soluble fraction thathad been prepared from sections incubated for 20 min in thepresence of 10{small tilde}^s M IAA was greater than that inthe sections incubated for 20 min without IAA. The amount ofphosphorylation of proteins per protein became higher when higherconcentrations increased (10{small tilde}⁸—10{small tilde}⁵M).The growth of sections incubated in the presence of 10{smalltilde}⁸ M IAA or higher concentrations was greater than thatof sections incubated in the absence of IAA. The promotion ofgrowth by IAA was greater at higher concentrations of IAA. Proteinsin the soluble fraction, prepared from sections incubated for20 min in the presence of 10{small tilde}⁵ M IAA, were phosphorylatedin the presence of either 10 fM cAMP, 10 µM cGMP, 100µM W-7, 100 µM W-5, 20 µM H-7 or 20 µMHA1004. The calmodulin antagonist, W-7, and the inhibitor ofprotein kinase C, H-7, inhibited the phosphorylation of proteinsstimulated by incubation with IAA. These results suggest thatIAA promotes cell elongation via protein phosphorylation thatdepends on calmodulin-dependent protein kinase and protein kinaseC. (Received November 29, 1995; Accepted May 20, 1996)     

Osmoregulation in Rice Coleoptile Elongation as Promoted by Cooperation between IAA and Ethylene

IAA-induced elongation of rice (Oryza sativa L. cv. Sasanishiki)coleoptiles is regulated by cooperation between IAA and ethyleneproduced in response to IAA. However, the presence of some solutes,such as K^$, Na^$, Rb^$, glucose and sucrose, in the incubationmedia was found to be indispensable for this cooperation. Withoutthose solutes, the IAA-induced elongation was not sustainedover a long time period. IAA caused increases in both the osmoticpotentials of the coleoptile cells and the extensibility oftheir cell wall. In epidermal cells of IAA-treated coleoptiles,the osmotic potential increased from –0.87 to –0.62MPa during a 4-h incubation with 1 mM KCl. Moreover, IAA promotedthe uptake of K^$ or Na^$ from the media into the coleoptiles.However, these effects of IAA were partially prevented by aminoethoxyvinylglycine(AVG), and all the AVG effects were completely nullified byethylene applied simultaneously and exogenously. Both IAA andethylene did not affect the wall yield stress. These resultssuggested that the long-term elongation induced by IAA in ricecoleoptile segments results from inhibiting increases in osmoticpotentials of their cells. The maintenance by IAA of low osmoticpotentials may be partly due to the promotive action of ethyleneproduced in response to IAA on the solute uptake from the media. (Received July 6, 1983; Accepted February 15, 1984)     

Studies on soluble RNA binding indoleacetic acid in etiolated mung bean hypocotyl sections

Nucleic acid was extracted by the SLS-phenol method from Phaseolusaureus hypocotyl treated with IAA-2-¹⁴C. Radioactivity in thenucleic acid fraction was found at the positions of sRNA andrRNA on an MAK column. IAA-¹⁴C was released from the radioactivecompound(s) in the sRNA fraction, by alkaline hydrolysis, butnot by ethanol extraction, or by dialysis to 2 M NaCl, 8 M urea,and 0.1 M EDTA. When the radioactive compound at the positionof sRNA on an MAK column was further re-chromatographed on aDEAE-cellulose column and on a BD-cellulose column, it was alwayslocalized only in a settled part of the fraction of each column.From this fraction IAA-¹⁴C was released by alkaline hydrolysis.Also, IAA-¹⁴C was released from the radioactive compound insRNA fraction, by RNase digestion, but not by pronase treatment.Results of these experiments suggest the existence of some kindsof sRNA binding IAA. The genesis of this sRNA binding IAA-¹⁴Cwas observed within 30 min after the supply of IAA-¹⁴C, andthe sRNA became saturated with IAA-¹⁴C about 2 hr after thebeginning of incubation. The behavior of sRNA binding IAA, representedby sRNA binding IAA-¹⁴C, may have a role in IAA induced growthof mung bean hypocotyl sections. (Received July 6, 1971; )     

The Relationship between Growth and Proline Incorporation after Auxin Treatment of Mung Bean Hypocotyls

Indoleacetic acid (IAA) stimulates the incorporation of ¹⁴C-proline into both the cyloplasmic and the cell wall fractions of the hypocotyl of mung bean (Phaseolus aureus Roxb. cv. Black). It neither stimulates the transfer of ¹⁴C-proline from the cyloplasmic fraction into the cell wall fraction, nor the retention of ¹⁴C-proline in the wall or cytoplasmic fractions. Moreover, the stimulation of growth caused by IAA parallels the stimulation of the incorporation of proline into the cytoplasmic fraction, but does not parallel the stimulation into the cell wall fractions. The stimulation of the incorporation into the cyloplasmic fraction seems to appear within 30 minutes after auxin treatment, at about the same time the increase in the growth is observed in response to IAA, suggesting a connection between these effects. On the other hand, the stimulation of the proline incorporation into the cell wall fraction seems to require more than 90 minutes after auxin treatment, suggesting no close connection between growth and proline incorporation into the cell wall fraction.     

Indole-3-Acetic Acid Control on Acidic Oat Cell Wall Peroxidases

Incubation of oat coleoptile segments with 40 μm indoleacetic acid (IAA) induced a decrease of 35–60% in peroxidase activity at the cell wall compartment. Treatment with IAA also produced a similar decrease in the oxidation of NADH and IAA at the cell wall. Isoelectric focusing of ionic, covalent, and intercellular wall peroxidase fractions showed that acidic isoforms (pI 4.0–5.5) were reduced preferentially by IAA treatment. Marked differences were found between acidic and basic wall isoperoxidases in relation to their efficacy in the oxidation of IAA. A peroxidase fraction containing acidic isoforms oxidized IAA with a V _max/s_0.5 value of 2.4 × 10⁻² min⁻¹· g fw⁻¹, 4.0 times higher than that obtained for basic peroxidase isoforms (0.6 × 10⁻² min⁻¹· g fw⁻¹). In contrast, basic isoforms were more efficient than acidic isoperoxidases in the oxidation of coniferyl alcohol or ferulic acid with H₂O₂ (5.6 and 2.1 times, respectively). The levels of diferulate and lignin in the walls of oat coleoptile segments were not altered by treatment with IAA. The decrease in cell wall peroxidase activity by IAA was related more to reduced oxidative degradation of the hormone than to covalent cell wall cross-linking. Received November 1, 1998; accepted December 14, 1998     

The Role of Boron in Plant Growth: IV. INTERRELATIONSHIPS BETWEEN BORON AND INDOL-3YL-ACETIC ACID IN THE METABOLISM OF BEAN RADICLES

The hypothesis that boron deficiency is equivalent to a stateof IAA toxicity was explored. Bioassays showed that extractsof substances similar to IAA taken from boron-deficient rootswere significantly more inhibitory to the growth of bean-rootsegments than those from normal roots. Supplied IAA and borondeficiency together restricted root growth to a greater extentthan either deficiency or IAA treatment separately. Roots werefound to recover more quickly from the inhibitory effects ofsupplied IAA if boron was present at high (0.5 ppm) rather thanlow (0.01 ppm) concentrations. Experiments with ¹⁴C-labelled IAA showed that deficient rootsabsorbed ¹⁴C more slowly than boron-fed roots and there wasalso a lower rate of decarboxylation in the deficient tissue.Consideration of the published evidence showed that many ofthe effects of boron deficiency could follow from an upset inIAA metabolism. It is suggested that boron-deficient tissuesuffers from excess auxin either because the element is necessaryfor some growth process, such as cell wall formation or nucleicacid synthesis, which, when impaired, results in the accumulationof auxin, or because the IAA-oxidation system is affected byphenolic inhibitors which boron normally inactivates by complexformation.     

Auxin- and Acid-Induced Changes in the Mechanical Properties of the Cell Wall

Auxin- and acid-induced changes in the mechanical propertiesof the cell wall were analyzed by measuring the creep of thecell wall using pumpkin (Cucurbita moschata Duch cv. Shirakikuza)hypocotyl segments. Hypocotyl segments were treated with orwithout IAA and stored in 50% glycerol at –15°C formore than 2 weeks before measurements. Creep rate increasedwith the increase in the load. The increase was first very slowup to the phase shift point (yield threshold, y), and afterthat, it was steep. The rate of the creep rate increase (creepcoefficient, Cm) was larger and y was smaller at pH 4.5 thanpH 6.8. This indicates cell wall loosening was facilitated underacidic conditions. IAA-pretreatment of the segments resultedin the lowering of y at pH 6.8 only. Around pH 5 and 45°C,Cm was highest and y was lowest. Boiling in distilled wateralmost lost the differential effect of Cm and y on pH and IAA.The differential effect of pH on Cm and y were recovered bythe addition of a crude extract of cell wall-bound proteins.It is implied that some enzymatic processes are involved inthe control of acid-induced cell wall extension. ¹Present address: Nihon Shokuhin Kako Co., Ltd. 30 Tajima, Fuji-City,Shizuoka, 417-8530 Japan. ²Present address: Graduate School of Environmental Earth Science,Hokkaido University, Sapporo, 060 Japan.     

Studies on the distribution of 14C-malformin A in major fractions of Phaseolus vulgaris L.

The distribution pattern of ¹⁴C-malformin in major fractionsof Phaseolus vulgaris L. seedlings shifted during water treatmentin the absence of malformin. From these shifts, and by comparisonof the ¹⁴C distribution patterns at the base and top of theseedlings, it was concluded that some ¹⁴C-malformin enters thecell and proceeds to the cell wall via intermediate compounds.As a working hypothesis it was suggested that in roots ¹⁴C-malforminfirst appears in a soluble "small molecules" fraction, bindsto a soluble protein fraction, and proceeds via die wall lipidfraction to the wall itself. Direct binding of some ¹⁴C-malforminto the wall fraction was not precluded. In leaves, the pathwayof ¹⁴C-malformin to the cell wall was similar in some respectsto that in roots. ¹ Present address: American Cyanamid, P.O. Box 400, Princeton,New Jersey 08540, U.S.A. (Received January 21, 1976; )     

Effects of Exogenous Auxin on the Regulation of Elongation Growth of Excised Segments of Vigna Hypocotyls under Osmotic Stress

IAA applied simultaneously with osmotica greatly enhanced theadaptive recovery of the elongation growth of segments of Vignahypocotyls during osmotic stress irrespective of whether ornot absorbable solutes were present. IAA stimulated both thesurface pump and the xylem pump, which have been shown to bestimulated by osmotic stress and to control the yielding ofthe cell wall and the absorption of solutes. Thus, wall extensibilityand the effective turgor were further enhanced under osmoticstress in the presence of IAA. These results indicate that thesimultaneous presence of IAA can reduce the inhibition of growthby osmotic stress, and they support numerical predictions basedon the apoplast canal model. The mechanism involved in the rapidrecovery of growth is discussed. ¹ Present address: Research Centre, Guangxi Agricultural University,Xiu Ling Rd., Nanning, Guangxi 530005 China. ² Present address: Biology Institute, Department of GeneralEducation, Nagoya University, 1 Furo-cho, Chikusa-ku, Nagoya,464 Japan. ³ Present address: Graduate School of Integrated Science, YokohamaCity University, 22-2, Seto, Kanazawa-ku, Yokohama, 236 Japan.     

Synthesis of Arabinose-Containing Cell Wall Precursors in Suspension-Cultured Tobacco Cells I. Intracellular Site of Synthesis and Transport

The distribution of arabinose-containing macromolecules in suspension-culturedtobacco cells was examined using sucrose density gradients.Exogenously applied ¹⁴Carabinose was scarcely converted intoother sugars, and concentrated in the Golgi-rich fraction (1.15g/cm³) and then secreted to the cell wall. ¹⁴C-Arabinose wasalso incorporated in a lower sucrose density fraction (1.11g/cm³), which contains small vesicles presumably originatedfrom the Golgi apparatus. The arabinose-containing macromoleculesin this fraction was more easily solubilized in water than thosein the Golgi-rich fraction. Alkaline hydrolysis of the macromoleculesindicated that cell-wall glycoprotein is a major component ofthe macromolecules and that the degree of glycosylation is slightlygreater in the lower density fractions than in the Golgi-richfraction. Based on these results, a scheme is suggested in whichthe glycoproteins and polysaccharides are glycosylated in theGolgi apparatus and secreted to the cell wall via secretionvesicles in the low density fraction. The possibility of ¹⁴C-arabinose-containingmacromolecules, in the early phase of synthesis, being a markerof the plant Golgi apparatus is also proposed. (Received September 21, 1980; Accepted January 27, 1981)     

Auxin-Induced Changes in the Molecular Weight Distribution of Cell Wall Xyloglucans in Avena Coleoptiles

The effect of auxin on the molecular weight (Mw) distributionof cell wall xyloglucans was investigated by gel permeationchromatography using coleoptile segments of Avena sativa L.cv. Victory, and the following results were obtained.

1. The water-insoluble hemicellulose (HC-A) mainly consisted ofxyloglucans. Iodine staining method revealed that relativelylarge amounts of xyloglucans were present in the water-solublehemicellulose (HC-B) and water-soluble polysaccharide (WS) fractions.
2. IAA did not cause remarkable changes in xyloglucan contentsin the hemicellulose, but significantly increased the xyloglucancontent in the WS fraction.
3. IAA substantially decreased theweight-average Mw of HC-A. Thiseffect became apparent within30 min of the incubation period,and was not affected by the0.15 M mannitol or 2% sucrose applied.Hydrogen ions also causeda decrease in the weight-average Mwof HC-A; its effect beingreversible.
4. Neither IAA nor hydrogen ions caused any remarkablechangesin the weightaverage Mw of water-soluble xyloglucansin theHC-B.

These results suggest that cell wall xyloglucans have an importantrole in auxininduced cell wall loosening in oat coleoptile cells. (Received May 10, 1984; Accepted August 20, 1984)     

Involvement of cellulose synthesis in actions of gibberellin and kinetin on cell expansion. Gibberellin-coumarin and kinetin-coumarin interactions on stem elongation

In azuki bean (Azukia angularis = Vignia angularis) epicotylsections, 5 ? 10^–4 M coumarin inhibited the incorporationof radioactivity from [U^–14C]glucose into the cellulosefraction by 35% in the absence of indole-3-acetic acid (IAA)and by 40% in the presence of 1 ? 10^–4 M IAA. There wasno inhibitory effect on the incorporation of radioactivity intothe other fractions. Coumarin at 5 ? 10^–4 M reversed thepromoting effect of 1 ? 10^–5 M gibberellin A₃ (GA) andthe inhibitory effect of 1 ? 10^–5 M kinetin on IAA-inducedelongation of sections with no significant effects on IAA-inducedelongation. Neither GA nor kinetin had any appreciable effectson cellulose synthesis. No inhibition of cellulose syntheiswas observed with 1 ? 10^–3 M colchichine, which has beenreported to have effects similar to those of coumarin on GA-or kinetin-affected stem elongation. Coumarin at 5 ? 10^–4M was ineffectual in breaking up wall microtubules, while adisrupting effect on wall microtubules was clearly demonstratedwith 3 ? 10^–4M colchicine. From these results, the possible involvement of cellulose synthesisin cell expansion controlled by GA or kinetin was suggested. (Received August 3, 1973; )     

Effect of a Growth Inhibitor on the Hydroxyproline Level in Cell Wall of Zea Primary Roots

Evidence supporting the view that there is an inverse relationshipbetween the hydroxyproline-protein level in the cell wall andthe ability of a cell to undergo rapid cell elongation was obtained.A growth inhibitor extracted from Zea primary roots acceleratedthe incorporation of radioactivity derived from ¹⁴C-prolineinto the sodium lauryl sulfate (SLS)-insoluble cell wall fraction.However, the inhibitor had no effect on the ratio of hydroxyprolineto proline that was incorporated into the SLS-insoluble fraction. We have discussed what this growth inhibitor may mean in thegeotropic curvature of Zea primary roots. ¹ Present address: Faculty of Education, University of Yamagata,Yamagata 990, Japan (Received May 9, 1981; Accepted August 8, 1981)