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Brassinosteroids. Chemistry, Bioactivity, and Applications PDF

357 Pages·1991·7.892 MB·English
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ACS SYMPOSIUM SERIES 474 Brassinosteroids Chemistry, Bioactivity, and Applications Horace G. Cutler, EDITOR 1 00 U.S. Department of Agriculture w 4.f 7 4 0 1- Takao Yokota, EDITOR 9 9 k-1 Teikyo University (Utsunomiya, Japan) b 1/ 2 0 1 10. Günter Adam, EDITOR oi: d Institute of Plant Biochemistry (Halle/Saale, Germany) 1 | 9 9 1 4, er b m e v o Developed from a symposium sponsored N e: by the Division of Agrochemicals at D at the 200th National Meeting n atio of the American Chemical Society, blic Washington, D.C., u P August 26-31, 1990, and an international workshop sponsored by the Federation of European Chemical Societies at the Institute of Plant Biochemistry, Halle/Saale, Germany, October 29-November 2, 1990 American Chemical Society, Washington, DC 1991 Library of Congress Cataloging-in-Publication Data Brassinosteroids: chemistry, bioactivity, and applications / Horace G. Cutler, editor, Takao Yokota, editor, Gunter Adam, editor. p. cm.—(ACS symposium series; 474) "Developed from a symposium sponsored by the Division of Agrochemicals at the 200th National Meeting of the American Chemical Society, Washington, D.C., August 26-31, 1990, and an international workshop sponsored by the Federation of European Chemical Societies at the Institute for Plant Biochemistry, Halle/Saale, Germany, October 1 0 29-November 2,1990." 0 w 4.f Includes bibliographical references and index. 7 4 1-0 ISBN 0-8412-2126-X 9 9 1 1. Brassinosteroids—Congresses. k- b 1/ I. Cutler, Horace G., 1932- . II. Yokota, Takao, 1942- . III. 2 0 Adam, Gunter. IV. American Chemical Society. Division of 1 0. Agrochemicals. V. Federation of European Chemical Societies. oi: 1 VI. Series. d 91 | Q58K18.1998-2.B78—5Bdc7230 1991 91-31405 19 CIP 4, er b m e ov The paper used in this publication meets the minimum requirements of American National N Standard for Information Sciences—Permanence of Paper for Printed Library Materials, ANSI ate: Z39.48-1984. D n Copyright © 1991 o cati American Chemical Society bli Pu All Rights Reserved. The appearance of the code at the bottom of the first page of each chapter in this volume indicates the copyright owner's consent that reprographic copies of the chapter may be made for personal or internal use or for the personal or internal use of specific clients. This consent is given on the condition, however, that the copier pay the stated per-copy fee through the Copyright Clearance Center, Inc., 27 Congress Street, Salem, MA 01970, for copying beyond that permitted by Sections 107 or 108 of the U.S. Copyright Law. This consent does not extend to copying or transmission by any means—graphic or electronic—for any other purpose, such as for general distribution, for advertising or promotional purposes, for creating a new collective work, for resale, or for information storage and retrieval systems. The copying fee for each chapter is indicated in the code at the bottom of the first page of the chapter. The citation of trade names and/or names of manufacturers in this publication is not to be construed as an endorsement or as approval by ACS of the commercial products or services referenced herein; nor should the mere reference herein to any drawing, specification, chemical process, or other data be regarded as a license or as a conveyance of any right or permission to the holder, reader, or any other person or corporation, to manufacture, reproduce, use, or sell any patented invention or copyrighted work that may in any way be related thereto. Registered names, trademarks, etc., used in this publication, even without specific indication thereof, are not to be considered unprotected bv law. PRINTED IN THE UNITED STATES Of AMERICA ACS Symposium Series M. Joan Comstock, Series Editor 1991 ACS Books Advisory Board V. Dean Adams Bonnie Lawlor 1 00 Tennessee Technological Institute for Scientific Information w 4.f University 7 4 John L. Massingill 0 1- Paul S. Anderson Dow Chemical Company 9 9 1 Merck Sharp & Dohme k- 1/b Research Laboratories Robert McGorrin 2 0 Kraft General Foods 1 10. Alexis T. Bell oi: University of California—Berkeley Julius J. Menn d 1 | Plant Sciences Institute, 9 19 Malcolm H. Chisholm U.S. Department of Agriculture er 4, Indiana University mb Marshall Phillips e v Natalie Foster Office of Agricultural Biotechnology, o N e: Lehigh University U.S. Department of Agriculture at D on Dennis W. Hess Daniel M. Quinn cati Lehigh University University of Iowa bli u P Mary A. Kaiser A. Truman Schwartz E. I. du Pont de Nemours and Macalaster College Company Stephen A. Szabo Gretchen S. Kohl Conoco Inc. Dow-Corning Corporation Robert A. Weiss Michael R. Ladisch University of Connecticut Purdue University Foreword THE ACS SYMPOSIUM SERIES was founded in 1974 to provide a medium for publishing symposia quickly in book form. The format of the Series parallels that of the continuing ADVANCES IN CHEMISTRY SERIES except that, in order to save time, the 1 papers are not typeset, but are reproduced as they are submit 0 w0 ted by the authors in camera-ready form. Papers are reviewed 4.f under the supervision of the editors with the assistance of the 7 4 0 Advisory Board and are selected to maintain the integrity of the 1- 99 symposia. Both reviews and reports of research are acceptable, 1 k- because symposia may embrace both types of presentation. b 1/ However, verbatim reproductions of previously published 2 0 1 papers are not accepted. 0. 1 oi: d 1 | 9 9 1 4, er b m e v o N e: at D n o ati c bli u P Preface BRASSINOSTEROIDS, a new group of biologically active natural prod­ ucts, are under consideration as another class of phytohormones. Their discovery and development mark a major milepost in the field of plant growth regulators, and have had a profound effect on plant physiology and agronomy. These natural products are also of interest to other disci­ 1 plines, such as mycology, entomology, horticulture, and (perhaps in the 0 0 pr future) even mammalian physiology. The potential economic effects 4. 7 these environmentally benign compounds may have on grain crop yields 4 0 1- are immense. 9 19 The original discovery of brassinolide, a natural plant-growth promoter k- b extracted from bee-collected pollen, was made at the USDA Agricultural 1/ 2 Research Center in Beltsville, Maryland. Although the USDA terminated 0 1 0. brassinosteroid research, others around the world have carried on the 1 oi: work. This volume addresses the history, biochemistry, physiology, practi­ d 1 | cal applications, production, synthesis, and entomological effects of these 99 compounds. 1 4, As the product of significant international effort, this book offers a ber compilation of the current work in the field. To date, it is the only m ve comprehensive review of the subject. Without the generous support of o N the Division of Agrochemicals of the American Chemical Society and the e: at substantial help of Maureen Rouhi, the book would have been impossible. D n We also thank BASF AG, Hoechst AG, Firmenich AG, Mandaus AG, o ati Schering AG, Shell Agrar AG, and Stickstoffwerke AG Piesteritz which c bli generously supported the Halle workshop. Without the effort of all these u P people, this volume would not have been possible. HORACE G. CUTLER GÜNTER ADAM Richard B. Russell Research Center Institute of Plant Biochemistry Agricultural Research Service Weinberg 3 U.S. Department of Agriculture Halle/Saale, O-4050, Germany Athens, GA 30613 TAKAO YOKOTA Department of Biosciences Teikyo University Utsunomiya 320, Japan July 22, 1991 Chapter 1 U.S. Department of Agriculture Brassins Project: 1970-1980 G. L. Steffens Beltsville Agricultural Research Center, Agricultural Research Service, U.S. Department of Agriculture, Beltsville, MD 20705 1 0 0 h c 4. 47 The discovery of a new naturally occurring group 0 1- of plant growth promoting substances, termed 9 9 brassins, from various sources of pollen was 1 k- reported in 1970 (Nature 1970, 225:1065). In 1974 b 1/ a cooperative effort for identifying the active 2 0 component(s) of brassins was initiated among 1 0. U.S.D.A. scientists at the Northern Regional 1 oi: Research Center (NRRC), Peoria, IL; the Eastern 91 | d RPAe;g ioannadl Rthees eaBrcehl tsCveinlltee r A(EgRriRcCu)l, tuPrhali laRdeeslpeahricah, 9 1 Center (BARC), Beltsville, MD. To obtain enough ber 4, c2r2u7d ek gp oolfl ebne ee-xctorlalcetc tefdo r riadpeen t(iBfircaastsiiocan, naabpouust L.) m e pollen was processed via a pilot plant-size v o solvent extraction procedure at ERRC and N e: partially purified at BARC (Ind. Eng. Chem. Prod. Dat Res. Dev. 1978, 17:351). A few crystals (4 mg) were n obtained at NRRC and subjected to x-ray o ati crystallographic analysis to determine structure blic (Nature 1979, 281:216). This biologically active u plant growth promoter, brassinolide P [2α, 3α, 22α, 23α-tetrahydroxy-24α-methyl-β-homo-7- oxa-5α-cholestan-6-one], was found to be a steroidal lactone with an empirical formula of C H O (MW = 480). The concentration of b2r8a4s8s6inolide in rape pollen is estimated to be about 100 parts per billion. Syntheses of brassinosteroids, biologically active analogues of brassinolide, were first conducted at BARC (J. Organic Chem. 1979, 44:5002) . The structure of the unique biologically active plant growth promoter, brassinolide, from pollen of the rape plant (Brassica napus L.) was published in 1979 (I). That This chapter not subject to U.S. copyright Published 1991 American Chemical Society 1. STEFFENS USDA Brassins Project: 1970—1980 3 publication was the culmination of more than 10 years work, at first by a few USDA scientists at Beltsville, MD and later by a multi-disciplinary team at three USDA locations: The Northern Regional Research Center (NRRC), Peoria, IL; The Eastern Regional Research Center (ERRC), Philadelphia, PA; and The Beltsville Agricultural Research Center (BARC) , Beltsville, MD. This Chapter presents an historical perspective of the research effort that led to the isolation and identification of brassinolide and to the first synthesis of brassinosteroids, the group of compounds that are structural isomers of brassinolide (2). General aspects of the project, along with details of the chemistry of natural and synthetic brassinosteroids have recently been published (3) . Additional information on biological and chemical properties of brassinolides will be presented 01 in the Chapters that follow. 0 h c 4. Prior to 1970 - BARC, Beltsville, MD 7 4 0 1- Early in his career, J.W. Mitchell (ret.) was interested in 9 19 the possibility of finding plant hormones and growth bk- substances in extracts of pollen (4) and immature seeds 21/ (5). The rationale for this was the fact that such plant 10 tissues have the capacity for rapid growth which most 10. likely is stimulated or triggered by specific hormones or oi: growth substances. In order to determine if plant growth d 1 | inhibiting or promoting substances reside in these or other 9 plant tissues, active components needed to be extracted, at 9 4, 1 least partially separated from impurities, and then er subjected to some type of biological assay system. b Mitchell sought out and developed plant bioassay systems m e for the purpose of evaluating and documenting specific v No responses to known and newly discovered plant hormones and e: growth substances (6) . at D on 1970 to 1974 - BARC ati c bli Mitchells search for biological activity in pollen led in u P 1970 to the first published report on the biologically active fraction, termed brassins, from an ethyl ether extract of pollen of the rape plant (Brassica napus L.) (7). The partially purified biologically active extract from rape pollen will be referred to as "brassins" in this Chapter. The extract was partially purified via a thin layer silica gel chromatographic procedure. Biologically active fractions were detected and monitored via the "bean 2nd internode bioassay" (6) . Fractions from the chromatogram were mixed with a carrier (fractionated lanolin) and applied, with the aid of a dissecting microscope, to 1 mm long 2nd internodes of bean plants (Phaseolus vulgaris L., cv. Pinto). Plants were grown for four days under 700 foot-candles of fluorescent light (9 hr. photoperiod) in a room maintained at 20°-23°C and then the internodes were measured. The initial report indicated 4 BRASSINOSTEROIDS: CHEMISTRY, BIOACTIVITY, AND APPLICATIONS that ...."brassins induced very marked elongation of both second and third internodes of the intact plants when applied at the rate of 10 iiq per plant. For example, second internodes grew an average of 155 mm during four days immediately after treatment, while controls treated with the fractionated lanolin alone grew only 12 mm." (7). Histological studies showed that the response to brassins was different from the response induced by gibberellic acid. Reported chemical and physical properties of brassins suggested that it was a "family" of new plant hormones that appeared to have glyceride structures. Further studies of pollen extracts of a number of different plant types for brassins-like activity showed that some induced the same type activity whereas others did not, and some were inactive (8, 9) . Because rape pollen 1 was a rich source of brassin-like activity, and because it 0 h0 could be relatively easily obtained, it was chosen for c 4. further detailed chemical and biological studies. 7 4 Along with the bioassay studies, an active program to 0 1- investigate the physiological properties of brassins was 9 19 being pursued. Worley and Mitchell (10) showed that k- brassins accelerated growth of the treated internodes, as b 1/ well as internodes above and below the treated area, in 2 10 beans. These responses involved both cell elongation and 10. cell division which caused marked changes in the vascular oi: anatomy of leaves above the site of brassins application. 91 | d Srteusdpioensd ebdy Wtoo rlberya sasnidns Krtirzeeka tsmheonwt edm utchha t twhoeo dsya pmle anatss baelsaon 9 1 plants (11) and that light influenced the way bean er 4, internodes responded to brassins (12). More controversial b was the report by Mitchell and Gregory (13) that brassins m e increased the overall growth of plants. These findings v No were the basis for postulating that brassins may function e: by providing hormonal control at fertilization for Dat accelerating and enhancing overall plant growth and n development - the "alpha hormone" function. Criticism (14) o ati was also directed at the apparent lack of detailed chemical blic and physical information on the active component(s) of u brassins. P Although there was no formal response to the published criticism, much effort was devoted to answering some of the questions posed and to evaluating the effects of brassins on intact plants under both greenhouse and field conditions. Unpublished data [Mitchell, J.W., USDA, (ret.) personal communication, 1973] obtained from several cooperative experiments in different parts of the country suggested that field-grown cereal and vegetable crops responded to brassins treatment by producing larger seed yields and/or larger plants. Many detailed greenhouse and growth chamber studies were also conducted at Beltsville based on the concept that brassins stimulated plants to express, more fully, their growth potential. This then allowed brassins-treated plants to attain full development sooner, provided the environment was suitable (15) . 1. STEFFENS USDA Brassins Project: 1970—1980 5 Because of the need for larger amounts of brassins, one phase of the chemistry program during this period centered on a convenient, practical, and reproducible method for their production from dried rape pollen. The preparative thin- and thick-layer chromatographic method reported by Mitchell et al. (7) was quite time-consuming. Mandava et al. (16) successfully developed a more rapid procedure for the production of brassins using column chromatography. The procedure was based on three steps - 1. the extraction of dried rape pollen with ethyl ether to yield a crude extract, 2. the chromatographic clean-up of the crude extract on a silica gel column with benzene- methanol-acetic acid (45:8:4,v:v:v) to yield a biologically active extract, and 3. the further purification of the active extract v ia preparative silica gel thin layer 1 chromatography with diisopropyl ether-acetic acid 0 h0 (95:5,v:v) to yield brassins. The other phase of the c 4. chemistry program continued to be directed towards 7 4 determining the chemical identity of the active 0 1- component(s) of brassins. At this point Mandava and 9 9 Mitchell (17) speculated that brassins were composed of 1 k- fatty acids linked by an ester bond to glucose at carbon 1 b 1/ in the /?-form. 2 10 Prior to his retirement from the USDA in 1974, 10. Mitchell sought increased support to establish field trials oi: to evaluate the effects of brassins for enhancing yields of 1 | d several crop plants. Because the purification, isolation, 9 and identification of the active component(s) were proving 9 1 to be so very difficult, Mitchell also sought additional er 4, support for a concerted research effort in these area. The b ARS administration considered both aspects to be of m e importance and plans for a multi-disciplined, multi- v No location project were made. e: at 1974 to 1980 - NRRC, Peoria, IL; ERRC, Philadelphia, PA; D n BARC, Beltsville, MD o ati blic In 1974 plans were submitted by the NRRC, ERRC, and BARC u outlining the extent and type of input that would be P available from each location for extracting large amounts of brassins from rape pollen and for the chemical isolation and identification studies. The overall program was coordinated at Beltsville (G.L. Steffens with assistance from M. Jacobson for chemical aspects). The pilot plant- size extraction of rape pollen was conducted at ERRC (M.F. Kozempel); the large scale chromatographic clean-up of the crude extract for the production of active brassins was done at BARC (N. Mandava) ; and the isolation, purification and identification of the active component(s) of brassins were undertaken at NRRC (M.D. Grove) and BARC (N. Mandava). All bean 2nd internode assays required to follow biological activity during a ll stages of the project were conducted at BARC (J.F. Worley and D.W. Spaulding). Field studies in the U.S. and Brazil were also coordinated through BARC 6 BRASSINOSTEROIDS: CHEMISTRY, BIOACTIVITY, AND APPLICATIONS (G.L. Steffens). A number of other scientists made major contribution to the program, as will be shown. It was a multi-phase project and each phase will be discussed separately although several phases were usually being conducted simultaneously. Purification, Isolation, and Identification of Active Component(s) of Brassins. As indicated, the brassins complex was found to contain glucosyl esters of fatty acids (17) which were thought to be the active brassins constituents. Starting with this information, glucosyl esters from rape pollen were purified and esters of these types were synthesized (18, 19, 20) . However, neither the esters purified from pollen nor those synthesized proved to have brassins-like biological activity in the bean 2nd 1 internode test. It was therefore concluded that components 0 0 other than glucosyl esters, most likely present in very h 4.c small amounts, were responsible for the biological activity 47 of brassins. 0 1- Because of the apparent low concentration of the 9 9 active component(s) in the brassins complex, it was 1 k- necessary to plan for the extraction of a large quantity of b 1/ rape pollen. Honeybee-collected rape pollen was available 2 0 from Canada since pollen is used in specialty-type natural 1 0. food products, for example baked goods. Arrangements were 1 oi: made (not without some difficulty) to obtain a large lot d (over 1/4 ton ) of rape pollen from Canada for a pilot 91 | plant-scale extraction at ERRC. Earlier work by Mandava et 19 al. (16) was the basis for the pilot plant extraction 4, procedure that was developed and used (21) . Contributors ber to the project, in addition to M. Kozempel and N. Mandava, m e were H. Kenney of ERRC; J.F. Worley, D. Matthees, J.D. v o Warthen, Jr., M. Jacobson and G.L. Steffens of BARC; and N e: M.D. Grove, NRRC. at D n Pilot Plant Extraction - ERRC. An outline of the o ati pilot plant extraction steps is shown in Figures 1 and 2. ublic oBfa t2c2h7 esk go fp oplollelne)n w(e5r eb aetxcthreasc toefd f45i.r5 st kwgi the adcehi,o nfiozr eda wtaottearl P in a 227 L kettle to remove simple sugars. The aqueous slurry was filtered via a Sparkler filter and the filter cake continuously washed with water until the filtrate was clear and colorless. The washed pollen (filter cake) was then freeze-dried, moved back to the extraction kettle and extracted with 114 L of 2-propanol. The slurry was pumped to a Sparkler filter, allowed to soak, and the 2-propanol drained off. The pollen cake was extracted in this manner 7 more times and then it was recycled to the extraction kettle where it was again extracted with 114 L of 2- propanol. After filtration, the pollen was washed twice with 2-propanol and then recycled to the extraction kettle for a final 2-propanol extraction (a total of eleven 2- propanol extractions). The 2-propanol was evaporated in a glass evaporator at <40°C to yield ca. 7.6 L of concentrate

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