1 0 0 w 5.f 2 1 0 0- 98 Aminocyclitol Antibiotics 1 k- b 1/ 2 0 1 0. 1 oi: d 0 | 8 9 1 4, st u g u A e: at D n o ati c bli u P 1 0 0 w 5.f 2 1 0 0- 8 9 1 k- b 1/ 2 0 1 0. 1 oi: d 0 | 8 9 1 4, st u g u A e: at D n o ati c bli u P Aminocyclitol Antibiotics Kenneth L. Rinehart, Jr., EDITOR University of Illinois Tetsuo Suami, EDITOR Keio University 1 0 0 w 5.f 2 1 0 0- 8 9 k-1 Based on a symposium jointly b 1/ 2 0 1 sponsored by the Divisions of 0. 1 oi: 0 | d Carbohydrate Chemistry and 8 9 1 4, Medicinal Chemistry at the st u g u A ACS/CSJ Chemical Congress, e: at D on Honolulu, Hawaii, ati c bli u April 2-3, 1979. P 125 ACS SYMPOSIUM SERIES AMERICAN CHEMICAL SOCIETY WASHINGTON, D.C. 1980 1 0 0 w 5.f 2 1 0 0- 8 9 1 k- 1/b Library of Congress CIP Data 2 0 Aminocyclitol antibiotics. 1 10. (ACS symposium series; 125 ISSN 0097-6156) oi: Includes bibliographies and index. d 0 | 1. Antibiotics—Congresses. 98 I. Rinehart, Kenneth L. II. Suami, Tetsuo, 1920- . st 4, 1 ISIeIr.i eAs.C S/CSJ Chemical Congress, Honolulu, 1979. IV. u QD375.A44 615'.329 80-10502 g u ISBN 0-8412-0554-X ASCMC 8 125 1-437 1980 A e: at D n o ati c bli Copyright © 1980 u P American Chemical Society All Rights Reserved. The appearance of the code at the bottom of the firstp age of each article in this volume indicates the copyright owner's consent that reprographic copies of the article 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. 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 new collective works, for resale, or for information storage and retrieval systems. 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, repro duce, use, or sell any patented invention or copyrighted work that may in any way be related thereto. PRINTED IN THE UNITED ACS Symposium Series 1 0 w0 M. Joan Comstock, Series Editor 5.f 2 1 0 0- 8 9 1 k- b 1/ Advisory Board 2 0 1 10. David L. Allara W. Jeffrey Howe oi: d 0 | Kenneth B. Bischoff James D. Idol, Jr. 8 9 1 4, Donald G. Crosby James P. Lodge st u g Au Donald D. Dollberg Leon Petrakis e: at D Robert E. Feeney F. Sherwood Rowland n o ati c Jack Halpern Alan C. Sartorelli bli u P Brian M. Harney Raymond B. Seymour Robert A. Hofstader Gunter Zweig FOREWORD 1 0 w0 The ACS SYMPOSIUM SERIES was founded in 1974 to provide 5.f a medium for publishing symposia quickly in book form. The 2 1 0 format of the Series parallels that of the continuing ADVANCES 0- 8 IN CHEMISTRY SERIES except that in order to save time the 9 1 k- papers are not typeset but are reproduced as they are sub b 1/ mitted by the authors in camera-ready form. Papers are re 2 0 1 viewed under the supervision of the Editors with the assistance 0. oi: 1 of the Series Advisory Board and are selected to maintain the d integrity of the symposia; however, verbatim reproductions of 0 | 8 previously published papers are not accepted. Both reviews 9 1 4, and reports of research are acceptable since symposia may st embrace both types of presentation. u g u A e: at D n o ati c bli u P PREFACE lhe aminocyclitol class of compounds includes some of our longest and best known antibiotics, streptomycin and neomycin. It also includes some of the most clinically useful antibiotics, such as gentamicin. Because of their clinical utility, and in spite of their long familiarity, interest in the class remains high and, indeed, seems to be increasing. This volume deals with the current status of structural, synthetic, and biosynthetic studies. 1 00 The aminocyclitol class and its members are defined and described pr 5. in Chapter 1, an introduction complete with figures and references to 2 01 recent review articles. The longest section of the book follows, devoted 80- to the very extensive recent synthetic efforts directed toward amino 9 1 k- cyclitol antibiotics. Sumio Umezawa discusses his recent preparation of b 1/ neomycin B, the latest in a series of total syntheses that have developed 2 10 routes useful for preparing modified aminocyclitol antibiotics with 0. doi: 1 rimouptreo vtoed n perwo paemrtiienso. cyIcnl iCtohl aapntteirb i3o, tiTces,t stuhoa tS uinavmoilv dinisgcu mssoesd iafinc aatilotenr noaft iavne 80 | existing antibiotic, describing his own syntheses based on the pseudo- 9 4, 1 disaccharide neamine as a starting material. In Chapter 4 Juji Yoshimura st describes approaches to branched-chain aminocyclitols, employing both u ug Diels-Alder reactions and nitrosugar cyclizations. Other chapters on A e: synthetic research also deal with branched-chain aminocyclitols (Kiely at D and Riordan, Chapter 5) or neamine and its modification (Magerlein, n o Chapter 10; Ku et al., Chapter 12). The latter chapter also treats ati blic modified kanamycins, as do chapters by Verheyden et al. ( Chapter 13 ) u and Cron et al. (Chapter 14), while Chapter 11 by McAlpine et al. treats P modified gentamicins and seldomycins. Finally, there are four chapters on spectinomycin—one (by White et al., Chapter 6) describing the first total synthesis of spectinomycin, and three (by Thomas et al.; Rosen- brook and Carney; Foley and Weigele; Chapters 7-9, respectively) dealing with modification of that antibiotic. The second major section of the book deals with structural studies of aminocyclitol antibiotics. In Chapter 15 Takayuki Naito provides and analyzes a very extensive set of 13C spectra, the most useful spectroscopic data for aminocyclitols' structural assignments. The two other chapters in this section (McAlpine et al., Chapter 16 and Shirahata et al., Chapter 17) assign structures to new fortimicins, aminocyclitols with a 1,4-diamino substitution pattern. ix The final section of the book deals with biochemical studies of the aminocyclitols. In Chapter 22 Bernard Davis discusses the multiple mechanisms of action of this class of antibiotics, while Julian Davies (Chapter 18) discusses the other side of the picture, the various mecha nisms by which the target bacteria enzymatically inactivate the amino cyclitol antibiotics. In Chapter 19 Kenneth Rinehart discusses the biosynthesis of aminocyclitols and describes a technique based on bio- synthetic studies that uses mutants to prepare new antibiotics—a tech nique that is also the subject of the paper by Cléophax et al. (Chapter 21). Finally, the role of mutasynthetic and chemical techniques in preparing improved clinical candidates in the gentamicin class is assessed by Peter Daniels in Chapter 20. Overall, then, the present book and the symposium on which it was 1 0 based point to the vigor of current research on aminocyclitol antibiotics, 0 pr with both elegant and useful organic chemical syntheses being carried 5. 12 out, and antibiotics of novel structure being discovered. New insights into 0 0- the mechanisms of action and inactivation of aminocyclitols are emerging 8 9 1 and their biosynthesis is not only being better understood, but is leading k- 1/b to new, less toxic compounds. 2 0 We would like to thank the authors for their continued patience and 1 10. cooperation, and Lois Shield and Julia Zvilius for their assistance in oi: preparing this book. d 0 | 8 9 1 University of Illinois KENNETH L. RINEHART, JR. 4, st Urbana, Illinois 61801 u g u A e: Keio University TETSUO SUAMI at Yokohama, Japan D n o cati February 5, 1980 bli u P χ 1 Aminocyclitol Antibiotics: An Introduction KENNETH L. RINEHART, JR. and LOIS S. SHIELD Roger Adams Laboratory, University of Illinois, Urbana, IL 61801 Aminocyclitol antibiotics constitute an important class of 1 0 clinically useful therapeutic agents, whose discovery dates from 0 ch that of streptomycin in 1944. These compounds, which are less 25. precisely, though widely, also referred to as aminoglycoside anti­ 1 0 biotics, include some of the most successful commercial antibio­ 0- 8 tics and new members of the class are being added yearly. Nume­ 9 k-1 rous reviews of aminocyclitols are available (1-8), providing 1/b references to the individual antibiotics. Thus, the present in­ 02 troductory section will simply indicate the breadth and diversity 1 0. of the class, providing specific references only to the newer 1 oi: members. 80 | d contaAinm 2in-doecoyxcylisttorelsp tacamnin bee (daiv 1id,2e,d3- tirnitdoe oax yv-e1r,y3- dlaiargmei ngoro uanpa lwoghi ch 9 1 of scyllo-inositol) and a somewhat smaller group containing other st 4, aminocyclitols. The deoxystreptamine antibiotics can be further gu grouped according to the number and location of substituents u A attached to the deoxystreptamine unit. 4,5-Disubstituted deoxy­ e: streptamines include neomycins, paromomycins, lividomycins and at D 2230-C (Figure 1). These pseudotetra- and pseudopentasaccharides n o all contain one or more diaminohexoses. Another group of 4,5- cati disubstituted deoxystreptamine antibiotics consists of pseudotri­ bli saccharides, including ribostamycin, xylostasin, the butirosins u P and the compounds now referred to (9) as 6'-deamino-6'-hydroxy­ butirosins (formerly BU-1709 E and E), and LL BM408α (10) 1 2 (Figure 2). These compounds are characterized by a di- or mono­ aminohexose and a ribose or xylose substituent and in some mem­ bers of the class the 1-amino group of deoxystreptamine is sub­ stituted by an α-hydroxy-γ-aminobutyryl group. The 4,6-disubstituted deoxystreptamine antibiotics are characterized by the presence at C-4 of a 2-aminohexose (usually modified), together with a second amino (usually a 3-amino) sugar at C-6. These antibiotics include the kanamycins, tobramycin and the nebramycins (Figure 3), the seldomycins (V\_,}2) (Figure 4), as well as the very large group of gentamicins and related com­ pounds (Figure 5), and the dehydro analogs of the gentamicins 0-8412-0544-X/80/47-125-001$05.00/0 © 1980 American Chemical Society 2 AMINOCYCLITOL ANTIBIOTICS 1 0 0 h c 5. 2 1 0 0- 8 9 1 k- b 1/ 2 0 0.1 NH 1 oi: Journal of Antibiotics d 0 | Figure 1. Neomycin group of 4,5-disubstituted deoxystreptamine antibiotics (1) 8 9 1 4, st u g u A CHR ate: 2-Q R R' R" pl„ R,v D ation wOH RXYIBLOOSSTTAAMSYINC IN NNHH22 OOHH ΗΗ OΗH OΗH blic BUTIROSIN A NH2 OH * OH Η Pu BUTIROSIN Β NH2 OH * Η OH 4-DE0XYBUTIR0SIN A NH2 Η * OH Η 4-DE0XYBUTIR0SIN Β NH Η * Η OH 2 LL BM408a OH OH Η Η OH R"NH 9 DAH-BUTIROSIN A OH OH * OH Η HOCHj>o DAH-BUTIROSIN Β OH OH * Η OH *R"« -C0CH0HCHCHNH 2 2 2 Journal of Antibiotics Figure 2. Ribostamycin group of 4,5-disubstituted deoxystreptamine antibiotics w