Your search keyword '"Hertel, R."' showing total 22 results

1. Auxin Binding to Subcellular Fractions from Cucurbita Hypocotyls: In Vitro Evidence for an Auxin Transport Carrier

Author

Jacobs, M. and Hertel, R.

Published

1978

2. Riboflavin-binding sites associated with flagella of Euglena: A candidate for blue-light photoreceptor?

Author

Nebenführ, A., Schäfer, A., Galland, P., Senger, H., and Hertel, R.

Published

1991

3. In-vitro Auxin Binding to Particulate Cell Fractions from Corn Coleoptiles

Author

Hertel, R., Thomson, K.-St., and Russo, V. E. A.

Published

1972

4. N-1-Napthylphthalamic-acid-binding Activity of a Plasma Membrane-rich Fraction from Maize Coleoptiles

Author

Lembi, Carole A., Morré, D. James, St.-Thomson, K., and Hertel, R.

Published

1971

5. Effect of Auxins on the Auxin Transport System in Coleoptiles

Author

Rayle, D. L., Ouitrakul, R., and Hertel, R.

Published

1969

6. Geotropism and the Lateral Transport of Auxin in the Corn Mutant Amylomaize

Author

Hertel, R., de la Fuente, R. K., and Leopold, A. C.

Published

1969

7. Amyloplasts are necessary for full gravitropic sensitivity in roots of Arabidopsis thaliana

Author

Kiss, J. Z, Hertel, R, and Sack, F. D

Subjects

Life Sciences (General)

Abstract

The observation that a starchless mutant (TC7) of Arabidopsis thaliana (L.) Heynh. is gravitropic (T. Caspar and B.G. Pickard, 1989, Planta 177, 185-197) raises questions about the hypothesis that starch and amyloplasts play a role in gravity perception. We compared the kinetics of gravitropism in this starchless mutant and the wild-type (WT). Wild-type roots are more responsive to gravity than TC7 roots as judged by several parameters: (1) Vertically grown TC7 roots were not as oriented with respect to the gravity vector as WT roots. (2) In the time course of curvature after gravistimulation, curvature in TC7 roots was delayed and reduced compared to WT roots. (3) TC7 roots curved less than WT roots following a single, short (induction) period of gravistimulation, and WT, but not TC7, roots curved in response to a 1-min period of horizontal exposure. (4) Wild-type roots curved much more than TC7 roots in response to intermittent stimulation (repeated short periods of horizontal exposure); WT roots curved in response to 10 s of stimulation or less, but TC7 roots required 2 min of stimulation to produce a curvature. The growth rates were equal for both genotypes. We conclude that WT roots are more sensitive to gravity than TC7 roots. Starch is not required for gravity perception in TC7 roots, but is necessary for full sensitivity; thus it is likely that amyloplasts function as statoliths in WT Arabidopsis roots. Furthermore, since centrifugation studies using low gravitational forces indicated that starchless plastids are relatively dense and are the most movable component in TC7 columella cells, the starchless plastids may also function as statoliths.

Published

1989

8. The specificity of the auxin transport system

Author

Hertel, R., Evans, M. L., Leopold, A. C., and Sell, H. M.

Abstract

In an effort to examine the specificity of the auxin transport system, the movement of a variety of growth substances and of auxin analogues through corn coleoptile sections was measured in both the basipetal and acropetal directions. In contrast to the basipetal, polar transport of the auxins indoleacetic acid (IAA) and 2,4-dichlorophenoxyacetic acid, no such movement was found for benzoic acid or for gibberellin A1. A comparison of the a- and ß-isomers of naphthaleneacetic acid showed that the growth-active a-form is transported, but not the inactive ß-analogue. Both the dextro (+) and leavo (-) isomer of 3-indole-2-methylacetic acid showed the basipetal movement characteristic of IAA, the dextro isomer being more readily transported than the (-)-form. In this instance, too, the transport was roughtly proportional to the growth promoting activity. The antiauxin p-chlorophenoxyisobutyric acid inhibited auxin transport as it inhibited auxin-induced growth. These results agree with the hypothesis that processes involved in auxin transport are closely linked to or even identical with the primary auxin action.

Published

1969

9. Versuche zur Analyse des Auxintransports in der Koleoptile vonZea mays L.

Author

Hertel, R. and Leopold, A. C.

Published

1963

10. Species differences in ligand specificity of auxin-controlled elongation and auxin transport: comparing Zea and Vigna.

Author

Zhao H, Hertel R, Ishikawa H, and Evans ML

Subjects

Biological Transport drug effects, Cotyledon drug effects, Cotyledon growth & development, Cotyledon metabolism, Dose-Response Relationship, Drug, Fabaceae drug effects, Fabaceae metabolism, Glycolates pharmacology, Hypocotyl drug effects, Hypocotyl growth & development, Hypocotyl metabolism, Indoleacetic Acids chemistry, Indoleacetic Acids metabolism, Kinetics, Ligands, Plant Roots drug effects, Plant Roots growth & development, Plant Roots metabolism, Plant Shoots drug effects, Plant Shoots growth & development, Plant Shoots metabolism, Species Specificity, Zea mays drug effects, Zea mays metabolism, Fabaceae growth & development, Indoleacetic Acids pharmacology, Zea mays growth & development

Abstract

The plant hormone auxin affects cell elongation in both roots and shoots. In roots, the predominant action of auxin is to inhibit cell elongation while in shoots auxin, at normal physiological levels, stimulates elongation. The question of whether the primary receptor for auxin is the same in roots and shoots has not been resolved. In addition to its action on cell elongation in roots and shoots, auxin is transported in a polar fashion in both organs. Although auxin transport is well characterized in both roots and shoots, there is relatively little information on the connection, if any, between auxin transport and its action on elongation. In particular, it is not clear whether the protein mediating polar auxin movement is separate from the protein mediating auxin action on cell elongation or whether these two processes might be mediated by one and the same receptor. We examined the identity of the auxin growth receptor in roots and shoots by comparing the response of roots and shoots of the grass Zea mays L. and the legume Vigna mungo L. to indole-3-acetic acid, 2-naphthoxyacetic acid, 4,6-dichloroindoleacetic acid, and 4,7-dichloroindoleacetic acid. We also studied whether or not a single protein might mediate both auxin transport and auxin action by comparing the polar transport of indole-3-acetic acid and 2-naphthoxyacetic acid through segments from Vigna hypocotyls and maize coleoptiles. For all of the assays performed (root elongation, shoot elongation, and polar transport) the action and transport of the auxin derivatives was much greater in the dicots than in the grass species. The preservation of ligand specificity between roots and shoots and the parallels in ligand specificity between auxin transport and auxin action on growth are consistent with the hypothesis that the auxin receptor is the same in roots and shoots and that this protein may mediate auxin efflux as well as auxin action in both organ types.

Published

2002

11. Auxin-induced elongation of short maize coleoptile segments is supported by 2,4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one.

Author

Park WJ, Schäfer A, Prinsen E, van Onckelen H, Kang BG, and Hertel R

Subjects

Benzoxazines, Cell Division, Cotyledon drug effects, Glycosides pharmacology, Oxazines chemistry, Oxazines isolation & purification, Zea mays chemistry, Cotyledon growth & development, Indoleacetic Acids pharmacology, Oxazines pharmacology, Plant Growth Regulators pharmacology, Zea mays growth & development

Abstract

Endogenous extractable factors associated with auxin action in plant tissues were investigated, especially their effects on elongation of 1-mm coleoptile segments of maize (Zea mays L.), in the presence of saturating 10 microM indole-3-acetic acid (IAA). The relative growth response, to auxin alone, was much smaller in segments shorter than 2-3 mm compared to 10-mm segments. Fusicoccin-induced elongation, however, was less affected by shortening the segments. A reduced auxin response may result from the depletion through cut surfaces of a substance required for IAA-mediated growth. Sucrose, phenolics like flavonoids, and vitamins were ruled out as the causal factors. A partially purified methanol extract of maize coleoptiles supported longterm, auxin-controlled elongation. The active material was also found among substances bleeding from scrubbed maize coleoptiles. The active factor from maize was further purified by HPLC and characterised by the UV spectrum and its pH shift. This factor was identified as 2,4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA) by mass spectroscopy. Activity tests confirmed that pure DIMBOA from other sources sustained auxin-induced elongation of short maize coleoptile segments. However, DIMBOA only partially restored the activity lost from short segments. This indicates that an additional factor, other than DIMBOA, is required. Extracts from Avena or Cucurbita did not contain the factor DIMBOA; it was active on maize elongation, but not on Avena coleoptiles or Cucurbita hypocotyls. This narrow specificity and the lack of DIMBOA action in short-term tests with maize indicate that DIMBOA is not the general auxin cofactor but may specifically "spare" the co-auxin in maize.

Published

2001

12. Heterogeneity of auxin-accumulating membrane vesicles from Cucurbita and Zea: a possible reflection of cell polarity.

Author

Lützelschwab M, Asard H, Ingold U, and Hertel R

Abstract

When microsomes from hypocotyls of Cucurbita pepo L. or coleoptiles of Zea mays L. were centrifuged on dextran-sucrose gradients a heterogeneity of auxin-accumulating vesicles was observed. Vesicles from the top part of the gradient showed saturable, specific accumulation of indole-3-acetic acid with only a small stimulation by phytotropins, and with very few binding sites for 1-N-naphthylphthalamic acid. In the vesicles from the lower part of the gradient, net accumulation of indole-3-acetic acid could be strongly increased by addition of phytotropins; binding of 1-N-naphthylphthalamic acid was high in this region. After two-phase partitioning, both kinds of vesicles were found in the upper-phase membrane fraction considered to be purified plasma membrane. The hypothesis is discussed that vesicles can be separated from the apical and basal parts of the cell's plasmalemma.

Published

1989

13. Properties of auxin binding sites in different subcellular fractions from maize coleoptiles.

Author

Dohrmann U, Hertel R, and Kowalik H

Abstract

In-vitro binding of labeled auxins to sedimentable particles was tested in subcellular fractions from homogenates of maize (Zea mays L.) coleoptiles. The material was fractionated by differential centrifugation or on sucrose density gradients. It was confirmed that the major saturable binding activity (site I) for 1-naphthyl[1-(14)C]acetic acid is associated with vesicles derived from the endoplasmatic reticulum. A second type of specific auxin binding (site II) could be distinguished by several criteria, e.g. by the low affinity towards phenylacetic acid. The particles carrying site II could be clearly separated from markers of the endoplasmatic reticulum, the plasmalemma, the mitochondria and the nuclei, while their density as well as sedimentation velocity correlated with particle-bound acid phosphatase, indicating a localization at the tonoplast. In contrast to site I, binding at site II was hardly affected by a supernatant factor and by sulfhydryl groups. However, the specificity pattern of site II towards auxins and auxin analogs was very similar to that of site I tested in the presence of supernatant factor. The existence of a third auxin receptor localized in plasma membrane-rich gradient fractions was indicated by a preferential in-vitro binding of 2,4-dichlorophenoxyacetic acid.

Published

1978

14. In vitro binding of riboflavin to subcellular particles from maize coleoptiles and Cucurbita hypocotyls.

Author

Hertel R, Jesaitis AJ, Dohrmann U, and Briggs WR

Abstract

Saturable and reversible in vitro binding of [(14)C]riboflavin was found to occur on subcellular, sedimentable particles from maize coleoptiles and Cucurbita hypocotyls. The KD was ca. 6 μM, the pH optimum was near 6.0, and the number of binding sites amounted to 0.1-0.5 μM on a fresh-weight basis. When the reducing agent dithionite was present, riboflavin binding increased-the KD was 2.5 μM, and the pH optimum above 8.0. The binding was specific: flavin mononucleotide (FMN) and flavin adenosine-dinucleotide (FAD) bound less tightly to these sites than riboflavin and another major soluble flavin, the previously described riboflavin-analog "FX", occurring in grass coleoptiles. These flavin-binding sites were localized on vesicles derived from plasmalemma and endoplasmic reticulum by analyzing sucrose and metrizamide density gradients and marker enzymes.

Published

1980

15. 1-N-naphthylphthalamic acid and 2,3,5-triiodobenzoic acid : In-vitro binding to particulate cell fractions and action on auxin transport in corn coleoptiles.

Author

Thomson KS, Hertel R, Müller S, and Tavares JE

Abstract

Auxin transport in corn coleoptile sections was inhibited by 2,3,5-triiodobenzoic acid (TIBA) as well as by 1-N-naphthylphthalamic acid (NPA); this inhibition was effected within 1 min of application.A particulate cell fraction-presumably plasma-membrane vesicles-specifically binds NPA and properties of these binding sites were studied using (3)H-NPA and a pelletting technique. The saturation kinetics of the physiological NPA effect, i.e. the inhibition of auxin transport, is similar to that of the specific in-vitro NPA binding. Half saturation of the inhibitory effect was found with about 5×10(-7) M TIBA and with 10(-7) M NPA. Both substances also decreased the speed of movement of auxin pulses within coleoptile sections.NPA dissociates from its binding site when the particulate cell material is centrifuged through an NPA-free cushion. The NPA that is washed from its binding site can be used in another binding test without any apparent change and is chromatographically unaltered. Therefore, the NPA binding is probably reversible and non-covalent. Inhibition of auxin transport by TIBA or NPA could also be reversed when the coleoptile sections were washed in buffer.The movement of (131)I-TIBA in corn coleoptiles appears to be polar in a basipetal direction. Higher concentrations of indoleacetic acid or TIBA inhibited this polar movement, suggesting that TIBA moves in the same channels as auxin. With (3)H-NPA, however, no polar transport could be detected. Together with the in-vitro binding results, these data indicate that TIBA acts directly at the auxin receptor while NPA has a different receptor site.The effect of TIBA and NPA on elongation, with or without auxin, is neglegible in comparison to their effects on auxin transport.

Published

1973

16. In-vitro auxin transport in membrane vesicles from maize coleoptiles.

Author

Heyn A, Hoffmann S, and Hertel R

Abstract

When membrane vesicles from maize (Zea mays L.) coleoptiles are extracted at high buffer strength, a pH-driven, saturable association of [(14)C] indole-3-acetic acid is found, similar to the in-vitro auxin-transport system previously described for Cucurbita hypocotyls. The phytotropins naphthylphthalamic acid and pyrenoylbenzoic acid increase net uptake, pressumably by inhibiting the auxin-efflux carrier.

Published

1987

17. Lateral electrical potential following asymmetric auxin application to maize coleoptiles.

Author

Morath M and Hertel R

Abstract

Following asymmetric application of indoleacetic acid to maize (Zea mays L.) coleoptiles the early time course of changes in lateral electrical potential was externally monitored with static-drop electrodes. First, an early negative potential change of ca.-1 mV was measured at the surface on the side of a strong auxin application. This negative auxin effect ended after ca. 15 min and was followed by a strong and lasting auxin stimulation of a positive lateral potential up to +12 mV at the auxin-treated side. The initial auxin effect appeared to depend on the size of the step-up in auxin concentration.

Published

1978

18. Auxin transport in membrane vesicles from Cucurbita pepo L.

Author

Hertel R, Lomax TL, and Briggs WR

Abstract

Association of (14)C-labelled indole-3-acetic acid (IAA) with membrane particles from zucchini (Cucurbita pepo L.) hypocotyls - previously described as "site III binding" (M. Jacobs and R. Hertel, 1978, Planta 142, 1-10) - is reinterpreted as a carrier-mediated uptake into closed and sealed vesicles driven by a pH gradient. Accumulation of the radioactive auxin is saturable, sensitive to the protonophore, carbonyl cyanide p-trifluoromethoxyphenyl hydrazone (FCCP), and to nigericin, and requires a pH gradient across the membranes with proton concentration greater outside than inside. The pH gradient decays within 1-2 h at 4°C and can be restored by re-equilibration of the particle preparation at more alkaline pH followed by return to more acidic medium. Osmotic shock and sonication release the IAA from the vesicles. 1-N-naphthylphthalamic acid (NPA) and 2,3,5-triiodobenzoic acid (TIBA), both inhibitors of auxin transport in vivo, increase the amount of net IAA accumulation in the vesicles, presumably by blocking efflux. Analogs of NPA less active or inactive in vivo are respectively less active or inactive in vitro. It is proposed that these membrane particles are outside-out plasma membrane vesicles, and that they perform the essential functions of auxin transport according to the chemiosmotic theory, with a specific, saturable proton symport uptake and an export anion carrier which is inhibited by NPA and TIBA.

Published

1983

19. Initial phases of gravity-induced lateral auxin transport and geotropic curvature in corn coleoptiles.

Author

Hild V and Hertel R

Abstract

Wild-type corn coleoptiles showed an initial downward bending upon transfer from the vertical to the horizontal position. Strong upward curvature started only 15-30 min after the begin of horizontal exposure.Little, if any at all, initial downward geotropic bending was found with amylomaize coleoptiles at 1 X g. With stronger stimuli (10 or 20 X g) the amylomaize mutant reacted initially strongly in the "wrong" direction, i.e. opposite to the later response.When wild-type coleoptiles had been symmetrically prestimulated for 60 min with alternating 2-min horizontal exposures from opposite sides, no initial downward bending occurred if the plane of horizontal exposure was maintained from pretreatment to the continuous horizontal stimulation of the test. If, however, the coleoptiles were rotated 90° around their long axis between pretreatment and test, the initial downward bending reaction developed as in the non-prestimulated controls. Thus changes in reactivity remained localized to the site of stimulation.Following the same pretreatments used for the curvature measurements, lateral (3)H-IAA transport was measured in coleoptile segments for 10 or 12.5 min. The auxin distribution found was strikingly parallel to the bending for all pretreatments.The dependence of reaction pattern on the duration of prestimulation in the same plane was tested. The function indicates a "half life" of 10-20 min for the change in sensitivity. The findings are discussed in view of a model of overstimulation and adaptation.

Published

1972

20. Auxin movement in corn coleoptiles.

Author

Hertel R and Flory R

Abstract

Movement of radioactive auxins was analysed in corn coleoptile sections. The results support the idea that processes involved in the transport of indoleacetic acid (IAA) are specific for growth-promoting auxins.Inhibition of IAA transport by triiodobenzoic acid is caused by a reversible block of the exit; the auxin held back remains in the transport pool. The observed increase in immobilization may be a secondary effect caused by the increased concentration of free IAA in the tissue.Auxin molecules are most likely transported by anon-covalent mechanism. IAA and naphthaleneacetic acid (NAA) move through the cell and exit as free molecules. A search for a transient auxin complex, chaseable as required for any transport carrier intermediate, yielded negative results. No(18)O was lost from NAA labeled with(18)O in the carboxyl group during transport of the auxin through coleoptile tissue.After application of IAA to auxin-depleted tissue, the transport rate undergoes oscillations with a period length of ca. 25 min.The movement of the auxin 2.4-dichlorophenoxyacetic acid which is usually sluggish, increased several times if some IAA was added. Auxin, thus, stimulates its own transport.A model is discussed in which auxin-binding to the plasma membrane and reversible changes of membrane conformation may provide a basis for active secretion and for the observed cooperativity.

Published

1968

21. Some aspects of geotropism in coleoptiles.

Author

Filner B, Hertel R, Steele C, and Fan V

Abstract

Auxin transport was studied in coleoptile sections that were stimulated geotropically. The early time course of auxin-transport asymmetry was measured. An initial phase in which more IAA was delivered into the receptor for the upper half was found after 5 min of horizontal exposure. After about 15 min this was followed by the expected known asymmetry in which more auxin flows in the lower side of the coleoptile. Upon return of the coleoptile to a vertical position, this asymmetry disappeared within 30 min.Earlier correlations of geosensitivity of the auxin transport system with sedimentation of amyloplasts in comparisons of wild type corn and an amylomaize mutant were confirmed and extended. It was also shown that, in contrast to the geotropic effect, phototropically induced lateral auxin asymmetry was not significantly different in wild type and amylomaize. Eleven other single-gene endosperm starch mutants of corn were compared to their corresponding normals. In all pairs, if a difference in geosensitivity of lateral auxin transport was present, it was correlated with a parallel difference in amyloplast sedimentation: e.g., sugary 1 ("67") had an amyloplast asymmetry index of 0.32 and a 13% gravity effect on auxin transport; the paired wild-type had both a greater amyloplast asymmetry (0.61) and a greater gravity effect on transport (23%).Correlations between gravity effects on auxin transport and amyloplasts were also shown in comparisons of apical and basal sections of corn, oat and Sorghum coleoptiles.Further results, confirming the increased effect of centrifugal acceleration greater than 1xg on lateral auxin transport and on curvature, are in agreement with the hypothesis that the pressure exerted by amyloplasts, acting as statoliths, locally stimulates the auxin transport system in the individual cells.

Published

1970

22. Effect of gravity and centrifugal acceleration on auxin transport in corn coleoptiles.

Author

Ouitrakul R and Hertel R

Abstract

Inversion of corn coleoptile sections resulted in a 10-20% inhibition of basipetal transport of 3-indoleacetic acid (IAA) and a more pronounced inhibition (20-50%) of the transport of 1-naphthaleneacetic acid (NAA).The effect of inversion on basipetal NAA transport was compared in wild-type corn and in the amylomaize mutant which contains smaller and slower sedimenting amyloplasts: the gravity induced inhibition was higher in the wild type coleoptiles (27% versus 9%).In wild type the inhibitory effect on basipetal NAA transport appeared within less than 30 min after inversion; then the effect remained relatively constant over at least 2 hr of transport. When the sections were returned to the upright position the transport rate increased, reaching the level of upright controls within 30 min.An effect of gravity on lateral transport of NAA was also demonstrated and shown to be expressed within 10 min after placing the tissue horizontally.When basipetal transport was tested in the direction of gravity and/or centrifugal acceleration, auxin movement incrased with increasing acceleration. Transport against centrifugal acceleration (10 x g) was less than transport of control sections (inverted at 1 x g).The results agree with the hypothesis that starch statoliths act by a pressure mechanism on the membrane transport system of auxin.

Published

1969