Designing Antibodies Ruth D. Mayforth Chicago, Illinois Academic Press, Inc. A Division ofHarcourt Brace & Company San Diego New York Boston London Sydney Tokyo Toronto This book is printed on acid-free paper. @ Copyright © 1993 by ACADEMIC PRESS, INC. All Rights Reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without permission in writing from the publisher. Academic Press, Inc. 1250 Sixth Avenue, San Diego, California 92101-4311 United Kingdom Edition published by Academic Press Limited 24-28 Oval Road, London NW1 7DX Library of Congress Cataloging-in-Publication Data Mayforth, Ruth D. Designing Antibodies / Ruth D. Mayforth. p. cm. Includes index. ISBN 0-12-481025-X (pbk.) 1. Monoclonal antibodies. 2. Anti-idiotypic antibodies. 3. Immunotherapy. I. Title. [DNLM: 1. Antibodies—genetics. 2. Antibodies—therapeutic use. 3. Drug design 4. Genetic Engineering. QW 575 M468d 1993] QR186.85.M38 1993 616.07'9-dc20 DNLM/DLC for Library of Congress 92-48391 CIP PRINTED IN THE UNITED STATES OF AMERICA 93 94 95 96 97 98 BB 9 8 7 6 5 4 3 2 1 Preface Progress in designing antibodies has been both fast and spectacular. One challenging aspect of designing antibodies is that advancements rely on the expertise of investigators from a variety of different fields, including molecular biology, immunology, biochemistry, chemistry, pharmacology, and medicine. An expansive volume of literature on designing antibodies has been accumulating in these fields over the past few years. This book compiles and integrates this literature to pro- vide useful, readily accessible information. This is not intended to be a step-by-step laboratory manual. Rather, its aim is to describe the tech- niques used in designing antibodies, the kinds of antibodies that have been generated through modern techniques, and their applications in medicine and science. It is hoped that, in addition to the excitement of watching research in this area unfold, many of the creative and innova- tive approaches reviewed in this book will be modified or will stimulate new ideas that will further the research and application of designer antibodies. Antibodies themselves are not a recent discovery. Antibodies were first defined functionally in the 1890s as a serum substance capable of conferring passive immunity to other animals. Forty years later, it was discovered that the γ globulin fraction of serum proteins contained antibody reactivity. It was evident that antibodies were important in defending an animal against foreign pathogens, yet scientists were hin- dered from capitalizing on the properties of antibodies until two impor- tant immunological breakthroughs were made. One was the develop- ment of hybridoma technology in 1975, through which hybridomas (immortalized antibody-secreting cells) can be generated against any antigen (ligand) and can secrete virtually limitless quantities of antigen- reactive monoclonal antibodies. These homogeneous antibody prepara- tions (compared to the heterogeneous, polyconal mixtures obtained from the serum of immunized animals) have enabled scientists to study and characterize the structure and function of antibodies in great depth. Another significant milestone was the elucidation of the mecha- nism of antibody gene rearrangement. These immunological discover- vii viii Preface ies, together with recent advances in genetic engineering and biological chemistry, have empowered scientists to exploit many of the advan- tageous properties of antibodies, such as an antibody's high degree of selectivity and affinity for its ligand and the potentially vast number of different antibodies (more than 1010-1011). Already, a number of anti- bodies have been designed as biomolecular tools in research, pro- phylaxis, diagnosis, and therapy. Antibodies can be designed by manipulating either the antibody protein or its genes, or by constructing an antigen that should induce the production of antibodies of the desired specificity. Not only can desirable features be incorporated into an antibody, but undesirable properties can be eliminated through these techniques as well. For ex- ample, in designing antibodies for human therapy, specific changes in an antibody's genes can be incorporated to minimize the antibody's harmful or undesirable side effects. The first two chapters review antibody structure, function, bio- synthesis, and technology, setting the framework for the remainder of the book, which has been developed around the strategies employed to design antibodies with certain properties. In Chapter 3, antibody genes are manipulated to generate antibodies with a desired characteristic, such as rodent/human chimeric and humanized antibodies. Antibodies can be conjugated to other effector molecules and specifically target certain cells (such as cancer cells) for destruction; these antibody- effector molecule conjugates (e.g., immunotoxins) are discussed in Chapter 4. Chapter 5 reviews antibodies (called anti-idiotypic antibod- ies) that have been designed to mimic antigens, a feature that is partic- ularly suited to vaccine development and hormone receptor mimicry. Finally, the calculated design of an antigen can induce the generation of antibodies with enzymatic properties; these catalytic antibodies are re- viewed in Chapter 6. It has been exciting to watch advancements in antibody design unfold, as their present and forseeable impact in sci- ence and medicine has been phenomenal. I am very grateful to the following people for critically reviewing portions of the text and for their comments and suggestions: Jeffrey Bluestone, Mark Duban, Loren Joseph, Jose Quintans, Andrea Sant, Hans Schreiber, Mark Scott, Steven Seung, Ursula Storb, and Howard Tager. I am especially indebted to Sheri Chamberlain, Cindy Go, and Mark S. Scott for their help in producing some of the figures and to Jerry Santos, Pamela Blunt, and my father, Richard Mayforth, for help with typing portions of the manuscript. Ruth D. Mayforth I DI Antibody Overview Introduction In this chapter, an overview of the humoral immune system and of antibody structure, function, and biosynthesis is presented. Its aim is to set the stage for a discussion of recent developments in antibody technology, which is the focus of the remainder of this book. The Humoral Immune System A number of features of antibodies are particularly remarkable, making them amenable to a number of scientific and medical applications. Anti- bodies bind antigens (their ligands, which generally can be thought of as foreign macromolecules) with a high degree of specificity and can discriminate between two very closely related antigens. Another striking characteristic of antibodies is their diversity. Human beings can produce at least 107 (and potentially even more than 1011) antibodies with different specificities. (The genetic mechanisms responsible for generating this vast repertoire are quite extraordinary and are described later in this chapter.) Antibody diversity is so great that virtually any foreign macro- molecule can be recognized. The diversity of antibodies, combined with their specificity, makes them ideal biomolecular tools for scientific, diag- nostic, and therapeutic purposes. The human immune system can be divided into two major compo- nents: the humoral immune system and the cell-mediated immune sys- tem. Each human has about 2 x 1012 lymphocytes (types of white blood cells). There are two kinds of lymphocytes, T cells and B cells, which are represented in approximately equal numbers. Both B cells and T cells express antigen-specific receptors on their cell surface, called the immunoglobulin receptor (IgR) and the T-cell receptor (TCR), respec- 1 2 1 Antibody Overview tively. These receptors are clonally distributed—that is, all of the immuno- globulins that a given B-cell clone expresses are identical and have exactly the same specificity for antigen. When stimulated, B cells can also secrete their immunoglobulins. Immunoglobulins (or antibodies) are an im- portant component of the humoral immune system. T cells form part of the cell-mediated immune system. T cells can be divided into two groups: cytotoxic (CD8+) T cells mediate cytotoxicity and helper (CD4+) T cells "help" generate an antibody response to T-cell-dependent antigens and provide the B cells with necessary lymphokines (biologically active polypeptides secreted by lymphocytes). In general, proteins are T-cell- dependent antigens while polysaccharides are T-cell-independent antigens. Immunoglobulins are synthesized by B lymphocytes and can be either membrane-bound or secreted. Membrane-bound immunoglobulins form part of the IgR on B cells. When this IgR recognizes and binds its antigen, the B cell is stimulated to proliferate (divide and expand) and differentiate into antibody-secreting cells and memory B cells. T helper cells aid in the proliferation and differentiation of antibody-secreting cells (plasma cells) by supplying necessary lymphokines. A B-cell clone and its daughter cells undergo repeated cell divisions and greatly expand in number. Each of them synthesizes antibodies with exactly the same antigenic specificity (although some of the daughter cells may mutate and express slight variants of the antibody, as discussed later). This is referred to as clonal expansion. Fundamental to this process is the "selection" of a preexisting antigen-specific B-cell clone by the foreign antigen. Once selected, the B cell clonally expands, and it and its progeny secrete their antigen-specific antibodies. This is the basic tenet of the clonal selection theory proposed by Macfarlane Burnet in the late 1950s (1956, 1959, 1962). The important point to stress is that each B-cell clone develops with no a priori knowledge of the antigen and expands after it has encount- ered antigen. The diversity of the antibody repertoire ensures that virtually any foreign macromolecule that is encountered will be recognized by at least one (and usually more than one) B-cell clone. Each B-cell clone secretes antibodies of exactly the same antigenic specificity, or monoclonal antibod- ies. In a typical immune response, antigens are recognized in slightly different ways by the antibodies of a number of different B-cell clones. For example, as many as 5,000-10,000 B-cell clones with unique specifici- ties can recognize the antigen dinitrophenol. This is called a polyclonal response. One interesting (and still not well understood) feature of the immune system is that it has memory. The second time that a given antigen is encountered, the response is significantly faster and greater in magni- The Humoral Immune System 3 tude than in the primary response. The following factors contribute to heightened secondary immune responses. Some of the cells that were recruited in the primary response are thought to become long-lived memory B cells that can quickly be recruited the next time antigen is encountered. Also, some of the daughter clones can make small point mutations in their antibody genes, which may result in antibodies with even higher affinities than the parent antibody. (This process is called somatic hypermutation or affinity maturation and is discussed further in the section on antibody biosynthesis.) These factors make a secondary immune response stronger and more rapid, and provide the theoretical basis for vaccinating individuals against highly infectious diseases. Antibodies help defend the body from foreign invaders in a variety of ways. First, antibodies can directly neutralize the antigen by forming antigen-antibody complexes that are cleared from the circulation. In addition, antibodies can bind the antigen on pathogens such as bacteria, coating the bacteria with antibody. These "opsonized" bacteria are more efficiently phagocytosed by macrophages, since the macrophages have Fc receptors that bind the Fc ("fragment crystalline"; see later discussion) portions of the coating antibodies. Furthermore, antibodies that have bound antigen on the surface of a cell can activate the complement system, resulting in the lysis of the cell. The complement system is composed of a series of plasma proteins that, when activated, initiates a sequential cascade of events. The final step in this cascade is the formation of protein pore complexes in the membrane of the target cell that lyses it. Thus, neutralization, opsonization, and complement activation are three defensive strategies used by antibodies to protect their host against foreign invaders. The defensive arsenal of the humoral immune system is rather impres- sive. As previously mentioned, there are as many as 1011 unique antibod- ies in a human being. The concentration of antibodies in human serum is 15 mg/ml, which calculates to be 3 x 1020 secreted immunoglobulin molecules per person! Furthermore, each B cell expresses approximately 105 immunoglobulin molecules of identical specificity on its surface, which means that about 1017 membrane-bound IgRs also scan the body for antigen. To maximize the chances of encountering antigen, lympho- cytes go on a number of "reconnaissance missions," recirculating from lymphoid tissues (such as lymph nodes and spleen) through the blood and back again to the lymphoid tissues. At any given time, there are approximately 1010 lymphocytes in human blood with a mean transit time of approximately 30 min (Pabst, 1988), translating to an exchange rate of almost 50 times per day. 4 1 Antibody Overview Antibody Structure Introduction Immunoglobulins are multifunctional glycoproteins found only in verte- brates. These molecules bind antigen through the variable domains at their amino-terminal (NH ) end and initiate a variety of effector functions 2 (such as complement activation, Fc receptor binding, and placental trans- fer) through the constant region domains at their carboxy-terminal (COOH) tails. Immunoglobulins are composed of four polypeptide chains. Two of the chains are identical heavy chains and two are identical light chains. The light chain consists of about 220 amino acids and has a molecular weight of about 25 kD (kilodaltons). The heavy chain is made up of approximately 450-575 amino acids (depending on the class of the heavy chain) with a molecular weight of about 51-72 kD. As shown in Figure 1.1, a schematic representation of the monomeric antibody molecule resembles a Y or a T. Each arm of the Y or T contains one com- plete light chain and the amino-terminal end of the heavy chain, while the base is comprised of the carboxy-terminal end of the heavy chain. The heavy and light chains are composed of a series of building blocks of globular domains that are each about 110 amino acids long. These domains, called immunoglobulin domains, have a characteristic tertiary structure of two roughly parallel jS-pleated sheets that are joined by a disulfide (S-S) bond. Other proteins also share these immunoglobulin domains, which are discussed later in more detail. Each light chain has two domains, while each heavy chain has either four or five domains. The first 110 amino acids of the amino-terminal portions of both the heavy and light chains exhibit relatively high amino acid sequence vari- ability and are hence designated the variable domains (V and V , re- H L spectively). They contain the antigen-binding sites or hypervariable regions that are complementary to, and thus bind, the antigenic deter- minants. The remainders of both chains are more conserved in amino acid sequence and are designated the constant regions (C and C ). H L Each light chain has one variable domain and one constant domain (V + C ), while each heavy chain has one variable domain and three L L or four constant domains, depending on its class [V + C 1 + C 2 + H H H C 3(+ CH4)] (see Fig. 1.1). H Both covalent and noncovalent interactions hold the four immunoglob- ulin chains together. Covalent disulfide bonds between the carboxy- terminus of the light chain and the carboxy-terminal portion of either the V or C 1 domains link these chains together. (In some IgAs, a H H disulfide bond joins the two light chains together instead.) The V do- H main has a hydrophobic face that interacts with the V domain. The C 1 L H 5 Antibody Structure antigen binding sites Figure 1.1 Immunoglobulin structure. Antibodies are glycoproteins composed of two identical disulfide-linked (S-S) heavy chains and two identical light chains. In most classes of antibodies, as shown here, each light chain is linked to a heavy chain through a disulfide bond. Antibodies are made up of a series of modular structural motifs called immunoglobulin domains, which are made up of a stretch of approximately 110 amino acids (represented in the figure as oval-shaped for the C domains or partially oval shaped for the V domains). Depending on the class of the antibody, there are four or five immunoglobulin domains in the heavy chain. IgG, Ig A, and IgD have V , C 1, C 2, H H H and C 3 domains and have a hinge region between C 1 and C 2. IgM and IgE have an H H H additional domain, C 4, but lack a hinge region. There are two immunoglobulin domains H in each light chain: V and C . Each antibody has two identical antigen-binding sites, L L one on each arm. There are three hypervariable regions (also called complementarity determining regions) in each variable domain, represented in the figure as zig-zag lines on the ends of the V domains. The six hypervariable regions (three from one V and H three from one V domain) form a pocket that makes up the antibody's antigen-binding L site. The effector functions of an antibody molecule (e.g., complement-mediated lysis, antibody-dependent cell-mediated cytotoxicity, and placental transfer) are mediated through the constant-region domains at the carboxy-terminal end of the antibody mole- cule. The glycosylation patterns vary depending on the isotype. All IgG subclasses have one N-linked oligosaccharide on their C 2 domain. The other immunoglobulin isotypes H have two to six N-linked oligosaccharides, and IgAl and IgD have O-linked oligosaccha- rides as well. and C domains also associate through hydrophobic interactions. The L two heavy chains are similarly held together through disulfide bonds and hydrophobic interactions. The hydrophobic interactions are especially important in keeping the C 3 domains juxtaposed. The position of the H 6 1 Antibody Overview Cys residues that form the disulfide bonds depends on the isotype. For IgG, the heavy chains are connected through disulfide bonds near the carboxy-terminus of the hinge region. Closer inspection of the amino acid sequences of the variable regions reveals that sequence variability is not scattered randomly throughout the V domains. Rather, the variability in V domains is localized to three discrete hypervariable regions that are separated by relatively constant "framework" regions (Wu and Kabat, 1970). The hypervariable regions are also called complementarity-determining regions (CDRs) because they create the pockets or grooves that are complementary to and bind the antigenic determinants. (One should keep in mind that the hypervariable regions are defined on the basis of amino acid variability rather than antigen-binding function. Although the actual antigen-binding site is comprised largely of these hypervariable amino acids, funcitonal studies have demonstrated that, depending on the antibody, a few framework residues can also be involved in the binding.) Structurally, the hypervari- able sequences of both the heavy and light chains are clustered near the amino-terminal end of the molecule and project outward from the ß- pleated sheets that make up the V domains. All antibody molecules contain two antigen-binding sites, each consisting of three light-chain CDRs and three heavy-chain CDRs. The antigen-binding site on the antibody is called the paratope, and the complementary region on the antigen that is bound by the antibody is called the epitope or antigenic determinant (see Table 1.1 and Fig. 1.2). The unique stereochemical conformation created by the combination of hypervariable sequences of a given pair of light and heavy chains determines the specificity of the antibody. Table 1.1 Epitopes, Paratopes, and Idiotopes Term Location Ligand Synonyms Epitope Determinant on Paratope Antigenic determinant antigen Antibody binding site Paratope Antibody Epitope Hypervariable regions hypervariable Complementarity-determining regions regions (CDRs) Antigen binding site Antibody combining site Idiotope Antibody V regions Paratope of an Possibly either epitope or paratope anti-idiotypic antibody