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Preface Progress in molecular biology and studies of small molecule binding to nu- cleic acids have been inextricably linked. A testament to that fact is the inclusion of eight papers directly concerned with drug-DNA interactions among the recently published list of the 100 most cited articles in the Journal of Molecular Biology. Few other scientific areas are as well represented on that list. Small molecules have perhaps taught us more about DNA than DNA has taught us about small molecules. Watson, for example, notes in the Molecular Biology of the Gene that the "fact that intercalation occurs so readily indicates that it is energetically favored... and is additional evidence for the metastability of the double-helical structure--its ability to assume many inherently unstable configurations that normally revert quickly back to the standard B conformation." From that point of view, intercalation pro- vided one of the very first indications of the plasticity of DNA, an area that has blossomed to reveal an incredible diversity of structural forms. Perhaps the most widespread interest in small molecules that bind to nucleic acids stems from their potential as useful pharmaceutical agents. Indeed, some of the very best anticancer drugs are well-documented DNA binders. While interest in drug-DNA interactions has at times waned, recent advances in chemical synthesis, analytical instrumenta- tion to measure binding, and structural biology have greatly enhanced the potential for rational design of new therapeutic compounds. Accordingly, studies on the in- teraction of small molecules with nucleic acids have taken on new life and have helped spawn several emergent biotechnology companies dedicated to exploiting the promise of making new types of pharmaceuticals targeted at nucleic acids. The aim of this volume is to consolidate key methods for studying ligand- nucleic acid interactions, both old and new, into a convenient source. Accordingly, we have solicited from experts in a variety of disciplines articles that concisely but completely describe useful methods and strategies for studying small molecule binding to nucleic acids. Techniques that are useful now range from biophysical and chemical approaches to methods rooted in molecular and cell biology. We hope that this volume will serve as a useful compendium of methods both to newcomers entering the field as well as to scientists already actively engaged in research in this area. NAHTANOJ B. SERIAHC LEAHCIM J. GNIRAW iiix Contributors to Volume 340 Article numbers are in parentheses following the names of contributors. Affiliations listed are current. NAITSIRHC BAILLY (24, 31), INSERM NEELRAC M. ENAN1LLUC (23), Pharma- U-524, and Laboratoire de Pharmaco- cology and Developmental Therapeutics logie Antitumorale du Centre Oscar ,tinU Peter MacCallum Cancer Institute, Lambret IRCL, 59045 Lille, France airotciV 3002, Australia TREBLA S. BENIGHT (8), Department ENNAZUS M. CUTrS, (23), Department of of Chemistry, University of Illinois, Biochemistry, La Trobe University, Bun- ,ogacihC Illinois 60607 and DNA Codes doora, Victoria 3083, Australia LLC, Chicago, Illinois 10606 SEMAJ C. KAIWORBAD (21), Department of ECNERWAL A. YELMOTTOB (11), School of Chemistry, Center for Science and -hceT Chemistry and Biochemistry, Georgia In- nology, Syracuse University, Syracuse, stitute of ,ygolonhceT Atlanta, Georgia New York 44231 30332 TINA M. DAVIS (2), Department of Chem- AIHPOS .Y B MEGESUER (10), Laboratoryfi~r istry, Georgia State University, Atlanta, Fluorescence Dynamics, Department of Georgia 30303 Physics, University of Illinois, Urbana, Illinois 61801 PETER B. DERVAN (22), Department of Chemistry, California Institute of -hceT NAHTANOJ B. CHAIRES (1, 5, 27), De- ,ygolon Pasadena, California 91125 partment of Biochemistry, University of Mississippi Medical Center, Jackson, ANELADGAM NOSSKIRE (4), Department of Mississippi 39216 Physical Chemistry, Chalmers University of Technology, Gothenburg SE-41296, NEY CHOO (30), Gendaq Limited, London Sweden, and Department of BiD- NW7 lAD, United Kingdom chemistry, University of Gothenburg, RUBAB Z. YRHDWOHC (6), School of Chem- Gothenburg SE-40530, Sweden ical and Life Sciences, University of EHPOTSIRHC ~IDUCSE (16), Laboratoire Greenwich, London SE18 6PF, United de Biophysique, INSERM U201, CNRS Kingdom UMR 8646, Museum National d'Histoire TREBOR M. CLEGG (10), Laboratory for Naturelle, 75231 Paris Cedex ,50 Fluorescence Dynamics, Department of France Physics, University of Illinois, Urbana, ALEBAZI FOKT (27), .M .D Anderson Can- Illinois 10816 cer ,retneC University of ,saxeT Houston, DLANOD M. SREHTORC (3, 23), Depart- saxeT 77030 ment of Chemistry, Yale University, New HTIEK R. Fox (20), Division of Biochemistry Haven, Connecticut 06520-8107 and Molecular Biology, School of Bio- MARK S. YELREBBUC (28), Department of logical Sciences, University of Southamp- Chemistry and Biochemistry, University ton, Southampton S016 7PX, United of ,saxeT Austin, Texas 78712 Kingdom x CONTRIBUTORS TO VOLUME 340 ES~IR~IHT GARESTIER (16), Laboratoire KISEB I. KANKIA (7), Department of de Biophysique, 1NSERM U201, CNRS Pharmaceutical Sciences, University ~f UMR 8646, Museum National d'Histoire Nebraska Medical Center, Omaha, Naturelle, 75231 Paris Cedex ,50 France Nebraska 68198 YRREJ NAMS1DOOG (21), Department of ATIMSA KUMAR (33), Department of Bio- Chemistry, Center for Science and -hceT chemistry, University of Mississippi, nology, Syracuse University, Syracuse, Jackson, Mississippi 39216 New York 13244 DLANOD W. KUPKE (7), Department of DAVID E. GRAVES (18), Department of ,yrrtsimehC University of ,ainigriV Char- Chemistry, University of Mississippi, lottesville, Virginia 10922 ,ytisrevinU Mississippi 38677 HTIEK A. IDLAMIRG (17), CRC Drug-DNA WERDNA N. LANE (12), Division of Molecu- Interactions Research Group, Royal Free lar Structure, National Institute for Med- and University College Medical School, ical Research, London NW7 IAA, United University College London, London WI P Kingdom ,TB8 United Kingdom YROGERG H. LENO (33), lnfgen Incorpo- R1M1DALV M. VELEUG (28), Department of rated, DeForest, Wisconsin 53532 Chemistry and Biochemistry, "~isrevinU of ,saxeT Austin, Texas 21787 RETEP T. IEHELLIL (l l), School of Chem- istry and Biochemistry, Georgia Institute LUMAHSTHI HAG (6), Krebs Institute of ,ygolonhceT Atlanta, Georgia 30332 for Biomolecular Science, Department of Chemisto, University of Sheffield, R. SCOTT LOKEY (28), Department of Sheffield $3 ,FH7 United Kingdom Chemistry and Biochemistr); University of ,saxeT Austin, Texas 21787 NHOJ A. YELTRAH (17), CRC Drug-DNA Interactions Research Group, Royal Free FRANK G. SNEITNOOL (10), Laboratory and University College Medical School, for Biochemistry, WEVIO, University of University College London, London W1P Gent, Gent 9000, Belgium ,TB8 United Kingdom PAUL B. HOPKINS (19), Department of NAYR A. LUCE (19), Department of Chem- istr); University of Washington, Seattle, Chemistry, University of ,notgnihsaW notgnihsaW 98195 Seattle, Washington 98195 ECNERUAL H. HURLEY (29), College of EHPOTSIRHC DNAHCRAM (32), Laboratory Pharmacy, University of Arizona, ,noscuT of Molecular Pharmacology, Division Arizona 85721 and Arizona Cancer Cen- of Basic Sciences, National Cancer -nI ,ret Tucson, Arizona 85724 stitute, National Institutes of Health, Bethesda, Maryland 20892 MARK ISALAN (30), Gendaq Limited, London NW7 laD, United Kingdom SIUL A. MARKY (7), Department of BRENT L. NOSREVI (28), Department of Pharmaceutical Sciences, University of Chemistry and Biochemistry, University Nebraska Medical Center, Omaha, of ,saxeT Austin, Texas 21787 Nebraska 68198 ECNERET C. SNIKNEJ (6), Yorkshire Cancer ERIALC J. MCGURK (17), CRC Drug-DNA Research Laboratory of Drug Design, Interactions Research Group, Royal Free Cancer Research Group, University of and University College Medical School, Bradford, Bradford BD7 1DP, United University College London, London WI P Kingdom ,TB8 United Kingdom CONTRIBUTORS TO VOLUME 340 xi RETEP J. MCHUGH (17), CRC Drug-DNA NOD R. PHILLIPS (23), Department snoitcaretnI Research ,puorG Royal Free of Biochemistry, LaTrobe ;3tisrevinU and University College Medical ,loohcS ,aroodnuB airotciV 3083, Australia ytisrevinU College London, London W1P SEVY REIMMOP (32), Laboratory of -celoM ,TB8 United Kingdom ular Pharmacolog); Division of Basic KRAM .P MCPIKE (21), Department of ,secneicS National Cancer ,etutitsnI Na- ,yrtsimehC Center for Science and -hceT tional Institutes of Health, Bethesda, nolog); Syracuse University, ,esucaryS Maryland 20892 New York 13244 ~lSOJ LAGUTROP (25, 27), Departamento de HTIDEREM M. MURR (28), Department of aigoloiB Molecular y ,raluleC lnstituto de Chemistry and ,yrtsimehcoiB Universi~ aigoloiB Molecular de ,anolecraB ,CISC of ,saxeT Austin, Texas 21787 anolecraB 08034, Spain IRUON ITAMAEN (32), yrotarobaL of -celoM RAMEDLAW PRIEBE (27), .M .D Ander- ular Pharmacology, Division of Basic nos Cancer ,retneC University of ,saxeT ,secneicS National Cancer ,etutitsnI -aN ,notsuoH Texas 77030 tional Institutes of Health, Bethesda, ASERET AKOLWEZRP (27), .M .D Ander- Maryland 29802 nos Cancer ,retneC University of ,saxeT VALSORAJ LI~ITESEN (8), Department of ,notsuoH Texas 77030 Applied Mathematics, Faculty of -htaM PETER SSUFNEGER (10), Laboratory for ematics and Physics, Charles ,~isrevinU Fluorescence Dynamics, Department of 811 0O Praha ,1 Czech Republic Physics, Universi~' of Illinois, ,anabrU PETER E. NIELSEN (15), Department of sionillI 10816 Medical Biochemistry and Genetics, ehT GNOSNIJ NER (5), Department of -mehcoiB Panum Institute, University of Copen- ,yrtsi University of Mississippi Medical ,negah Copenhagen DK-2200, Denmark ,retneC ,noskcaJ Mississippi 39216 TGNEB NORD~N (4), Department of Phys- RETEP .V RICCELLI (8), Department ical Chemistry, Chalmers University of Chemistry, University of ,sionillI of ,ygolonhceT Gothenburg ,69214-ES ,ogacihC Illinois 60607, and AND Codes Sweden ,CLL ,ogacihC Illinois 10606 RICHARD OWCZARZY (8), Department DRAHCIR D. YDRAEHS (26), Department of of Chemistry, University of ,sionillI yrtsimehC and ,yrtsimehcoiB Seton Hall ,ogacihC Illinois 60607, and Integrated ;)tisrevinU South Orange, New Jersey AND Technologies, Coralville, Iowa 97070 14225 ALEGNA M. SNOW (26), Memorial High PETR AKSO~(NAP (8), Department of -mehC ,loohcS Elmwood ,kraP New Jersey 07407 ,yrtsi University of Illinois, ,ogacihC SELRAHC H. SPINK (9), Department of Illinois 60607, and Center for Discrete ,yrtsimehC State ytisrevinU of New ,kroY ,scitamehtaM Applied Computer Science ,dnaltroC New kroY 54031 and Applications DIMAT1A, Charles ,ytisrevinU Prague, Czech Republic, and UYKEAD NUS (29), Institute for Drug De- AND Codes LLC, Chicago, Illinois ,tnempolev naS Antonio, Texas 54287 10606 GNEHS-NAIJ NUS (16), Laboratoire de MARY HTEBAZILE PEEK (13), School of Biophysique, INSERM U201, CNRS yrtsimehC and ,yrtsimehcoiB Georgia -nI RMU 8646, Museum National d'Histoire stitute of ,ygolonhceT Atlanta, Georgia Naturelle, 75231 Paris Cedex ,50 23303 ecnarF xii CONTRIBUTORS TO VOLUME 340 LEAHCIM J. TILBY (17), Cancer hcraeseR bridge, Cambridge 2BC IQJ, United ,tinU Medical School, University of New- modgniK castle Upon Tyne, Newcastle NE2 4HH, NASUS E. WELLMAN (9), Department United Kingdom of Pharmacology and Toxicolog), Uni- JOHN W. TRAUGER (22), Department versity of Mississippi Medical ,retneC of Chemistry, California Institute ,noskcaJ Mississippi 39216 of Technology, Pasadena, California NEROL DEAN WILLIAMS (13), School of 52119 yrtsimehC and ,yrtsimehcoiB Georgia -nI NHOJ O. TRENT (14, 27), James Gra- stitute of ,ygolonhceT Atlanta, Georgia ham Brown Cancer ,retneC Department 23303 of Medicine, University of Louisville, Louisville, Kentucky 40202 W. DAVID WILSON (2), Department of Chemistry, Georgia State ,ytisrevinU PETER M. VALLONE (8), Department Atlanta, Georgia 30303 of Chemistry, University of Illinois, Chicago, Illinois 60607 and National 1HZGNOH XU (33), Department of -mehcoiB Institute of "sdradnatS and ,ygolonhceT ,yrtsi University of Mississippi, ,noskcaJ Biotechnology Division, ,grubsrehtiaG Mississippi 39216 Mao, land 20899 NEVETS M. ZEMAN (3), Department of LEAHCIM J. WARING (20, 24), Department ,yrtsimehC Yale ,ytisrevinU New ,nevaH of Pharmacology, University of Cam- Connecticut 06520 1 STSYLANA FO LIGAND-DNA GNIDNIB SMREHTOSI 3 1 Analysis and Interpretation of Ligand-DNA Binding Isotherms By NAHTANOJ B. SER1AHC Introduction To attain a reasonable understanding of any ligand-receptor interaction, it is necessary to answer the questions posed by Scatchard ~ more than 50 years ago: "How many? How tightly? Where? Why? What of it?" The first two Questions (and in part the third) can be answered by equilibrium binding studies, and are the pri- mary focus of this chapter. The remaining questions concisely express the concerns of structural and functional studies, and may be addressed by X-ray crystallogra- phy, nuclear magnetic resonance (NMR) techniques, molecular modeling, and a variety of chemical and molecular biological methods. Macromolecular binding is a phenomenon of general interest, and the underlying general principles are the same for ligand binding to proteins or to nucleic acids. A number of excellent general treatments of macromolecular binding are available that explain the un- derlying physical chemistry in detail .2-6 What distinguishes the binding of small molecules to DNA from their binding to proteins is the need to account for behav- ior arising from the lattice properties of linear DNA molecules. Various neighbor exclusion models have evolved to cope with that complexity, and are described. An excellent discussion of the principles of nucleic acid binding interactions is provided by Bloomfield et al. 7 Determination of the binding constant K allows the binding free energy change, AG, to be calculated by the standard Gibbs equation, AG = - RT In K, where R is the gas constant and T is the temperature in degrees Kelvin. From studies of the temperature dependence of the binding constant, or (preferably) by calorimetric studies, the binding enthalpy (AH) may be obtained. The binding free energy may then be partitioned into its enthalpic and entropic components, AG = AH -- TAS, where AS is the entropy change. Knowledge of these thermodynamic parameters I G. Scatchard, Ann. N.Y. Acad. Sci. 51,660 (1949). 2 j. .T Edsall and J. Wyman, "Biophysical Chemistry." Academic Press, New York, 1958. 3 j. Wyman and S. J. Gill, "Binding and Linkage." University Science Books, Mill Valley, California, 1990. 41. M. Klotz, "Ligand Receptor Energetics." John Wiley & Sons, New York, 1997. 5 E. diCera, "Thermodynamic Theory of Site-Specific Binding Processes in Biological Macro- molecules." Cambridge University Press, Cambridge, 1995. 6 G. Weber, "Protein Interactions." Chapman & Hall, New York, 1992. 7 .V A. Bloomfield, D. M. Crothers, and J. Ignacio Tinoco, "Nucleic Acids: Structures, Properties and Functions," 1st Ed. University Science Books, Sausalito, California, 2000. Copyright © 2001 by Academic Press All rights of reproduction in any form reserved. METHODS IN ENZYMOLOGY, VOL. 340 0076-6879/00 $35.00 4 LACISYHPOIB SEHCAORPPA 11 provides a firm foundation for understanding the molecular forces that govern the binding reaction, allowing one to begin to address Scatchard's question "Why?" Details of attempts to parse binding free energies for ligand-DNA interactions in order to understand the contribution of various molecular forces are described in publications from this and other laboratories, s- 21 The aim of this chapter is to offer a concise guide for the analysis and interpre- tation of ligand-DNA binding isotherms. Methods for experimentally obtaining binding data are not discussed because detailed, practical descriptions of experi- mental protocols are available. 31 51 In this chapter, examples of binding data are taken from results obtained in the author's laboratory with the anticancer agent daunomycin (daunorubicin). Daunomycin is perhaps the best-characterized DNA intercalator, and its binding to a wide variety of DNA sequences and structures has been thoroughly investigated. ~ 71,6 Model-Independent Approaches Figure 1 shows the results from two types of binding experiments, each of which addresses one of Scatcbard's queries as directly as possible. The method of continuous variations 1a-sI may be used to construct a so-called Job plot (Fig. 1A). Binding stoichiometries may be determined from such plots without recourse to any assumed binding model. For the data shown in Fig. 1A for the interaction of daunomycin with calf thymus DNA, an inflection near 0.2 mol fraction ligand indicates a binding stoichiometry of one ligand per 3 or 4 base pairs. The exact stoichiometry from the inflection at 0.21 mol fraction is (1.0 - 0.21)/0.21 = 3.76 base pairs. This value represents the predominant binding mode, although an s j. B. Chaires, Anticancer Drug Des. 11,569 (1996). 9 j. B. Chaires, Biopolymers 44, 201 (1997). l01. Haq, J. E. Ladbury, B. Z. Chowdhry, T. C. Jenkins, and J. B. Chaires, J. Mol. Biol. 271,244 (1997). II j. Ren, T. C. Jenkins, and J. B. Chaires, Biochemistry 39, 8439 (2000). 21 S. Mazur, .F A. Tanious, D. Ding, A. Kumar, D. W. Boykin, I. J. Simpson, S. Neidle, and W. D. Wilson, J. Mol. Biol. 300, 321 (2000). 31 X. Qu and J. B. Chaires, Methods Enzymol. 321, 353 (2000). 4L T. C. Jenkins, in "Drug-DNA Interaction Protocols" (K. R. Fox, ed.), Vol. 90, pp. 195-218. Humana Press, Totowa, New Jersey, 1997. 51 .p C. Dedon, in "Current Protocols in Nucleic Acid Chemistry" (S. L. Beaucage, D. E. Bergstrom, G. D. Glick, and R. A. Jones, eds.), Vol. ,1 pp. 8.2.1-8.2.8. John Wiley & Sons, New York, 2000. 61 j. B. Chaires, in "Advances in DNA Sequence Specific Agents" (L. H. Hurley, ed.), Vol. 2, pp. 141- 167. JAI Press, Greenwich, Connecticut, 1996. 71 j. B. Chaires, Biophys. Chem. 35, 191 (1990). 81 E Job, Ann. Chim. (Paris) 9, 113 (1928). 91 C. .Y Huang, Methods Enzymol. 87, 509 (1982). o2 A. Waiters, Biomed. Biochim. Acta 44, 132t (1985). 12 E G. Loontiens, E Regenfuss, A. Zechel, L. Dumortier, and R. M. Clegg, Biochemistry 29, 9029 (1990). 1 ANALYSIS OF LIGAND-DNA BINDING ISOTHERMS 5 / 1.2 , I I I I I , , , , , 200 1.0 g t 0.8 -200 0.6 -400 0.4 -600 0.2 -800 o.o • B , I , I I I 0.0 0.2 0.4 0.6 0.8 -20 -18 -16 -14 -12 -t0 Mole Fraction Daunomycin nI Cf FIG. I. Daunomycin binding to calf thymus DNA. (A) Job plot obtained from fluorescence titration studies. A F is the difference in fluorescence emission intensity between solutions of daunomycin alone and in the presence of DNA. The minimum indicates a binding stoichiometry of 3 or 4 base pairs. (B) Binding isotherm for the daunomycin--calf thymus DNA interaction. The fractional saturation was calculated assuming a 3-bp binding site. The abscissa is the natural logarithm of the free daunomycin concentration. inflection near 0.5-0.6 mol fraction indicates an additional binding mode at higher drug concentrations. The results shown here, based on fluorescence data, agree well with data based on absorbance changes. °2 The Job plot thus answers the question "How many?" directly. In studies of ligand-DNA interactions, this method has been underutilized and its advantages largely unappreciated. In the case of multiple binding modes, the method of continuous variations is particularly valuable, and clearly reveals complexities in the binding process. Published examples for the groove-binder Hoechst 3325821 and for the bisintercalating anthracycline WP63122 illustrate the value of the method in cases of complicated, multimode binding interactions. Figure B1 shows a titration binding isotherm for the daunomycin-calf thymus DNA interaction. In this form, the fractional occupancy of binding sites is shown as a function of the natural logarithm of the free daunomycin concentration .)-tC( The fractional occupancy was calculated from the experimentally determined binding 22 F. Leng, W. Priebe, and J. B. Chaires, yrtsimehcoiB 37, 1743 (1998). 6 LACISYHPOIB SEHCAORPPA 1 ratio r (moles daunomycin bound per mole base pair) and the binding stoichio- metry was determined from the Job plot shown in Fig. 1A. The form of the plot shown in Fig. B1 is regarded by some 3 as the most fundamental representation of binding data because the logarithm of the free ligand activity is proportional to the chemical potential of the ligand. For simple binding to identical, noninteracting sites, titration binding curves should be symmetric about a midpoint located at a ligand concentration that is the reciprocal of the association binding constant, and should cover a span of 8.1 lOgl0 units (4.14 In units) in going from 0.1 to 0.9 fractional saturation. 3'4'6 The data shown in Fig. B1 cover a span of 5.4 in units (2.4 log~0 units) and represent an essentially complete binding titration curve. The span is greater than expected for simple binding, which indicates negative cooperativity, neighbor exclusion, or heterogeneity of binding sites. Perhaps the main advantage of the data shown in Fig. B1 is that they may be analyzed in a model-independent way by using the Wyman concept of median ligand activity. 5'3 The free energy of ligation (AGx) to go from a state where no ligand is bound to a degree of saturation of ?k is given by Eq. (1): 2 P AGx = RT oJ In Cfg~" (1) where RT has its usual meaning. The pronounced advantage of Eq. (1) is that it provides a free energy estimate to attain any degree of saturation without recourse to any specific binding model. Numerical integration of the data in Fig. 1 B yields an estimate of AGx = -7.8 kcal mol I for the full ligation of a daunomycin binding site. Free energies derived from binding constants obtained by curve fitting to specific models must agree with this model-independent value if the model is reasonable. Neighbor Exclusion Models Figure 2 shows data for the daunomycin-calf thymus DNA interaction in the form of a Scatchard plot, J by far the most common representation of binding data for ligand-DNA interactions. To explain the curvature in such plots, a variety of neighbor exclusion models were proposed, 42'32 and these have become the most commonly used models for the interpretation of binding isotherms. Neighbor exclusion models assume (in their simplest form) that the DNA lattice consists of an array of identical and noninteracting potential binding sites. The base pair is commonly defined as the lattice binding site for duplex DNA. Ligand binding to any one site occludes neighboring sites from binding as defined by the site size n. As the lattice approaches saturation, the probability of finding a stretch 32 .D .M ,srehtorC sremylopoiB ,6 575 .)8691( 42 j. .D eehGcM dna R .H noy ,leppiH .J .loM .loiB ,68 964 .)4791( 1 ANALYSIS OF LIGAND-DNA BINDING ISOTHERMS 7 8.0x10 5 , , , I , , I 6.0xl 0 s "',O • 4.0xl 0 s • o~',~ G~ 3C 2.0x10 5 e ~ - . . 0.0 I I I I I I I 0.00 0.05 0.10 0.15 0.20 0.25 0.30 0.35 r FIG. 2. Scatchard plot for the daunomycin-calf thymus DNA interaction. The solid line is the best fit of the neighbor exclusion model Eq. (2) to the experimental data yielding the parameters shown in Table I. The dashed line is the best fit with the exclusion parameter constrained to an integral value of 3. of unoccupied DNA n base pairs long decreases, producing the curvature seen in Fig. 2. The curvature does not result from a decrease in the intrinsic binding affinity, but rather arises from the decreased probability of finding a free site of the appropriate size. McGhee and von Hippe124 derived a closed form equation that embodies the neighbor exclusion model Eq. (2): r I 1--"r °' -- = K(1 - nr) 1 ; J (2) where K is the association constant for ligand binding to an isolated lattice site, n is

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