Chromatin Structure and Function Levels of Organization and Cell Function
PartB
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Chromatin Structure and Function Levels of Organization and Cell Function
PartB
Edited by
Claudio A. Nicolini Temple University Philadelphia, PennsylvaniQ
PLENUM PRESS. NEW YORK AND LONDON Published in cooperation with NATO Scientific Affairs Division
Library of Congress Cataloging in Publication Data
Nato Advanced Study Institute, Erice, Italy, 1978. Chromatin structure and function.
(NATO advanced study institutes series: Series A, Life sciences; v. 21) Includes bibliographical references and indexes. CONTENTS: pt. A. Molecular and cellular biophysical methods. - pt. B. Levels
of organization and cell function. 1. Chromatin - Congresses. 2. Carcinogenesis - Congresses. 1. Nicolini, Claudio A.
II. Title. III. Series. QH599.N37 1978 ISBN-13: 978-1-4684-0978-9 DOl: 10.1007/978-1-4684-0976-5
574.8'732
e-ISBN-13: 978-1-4684-0976-5
Second half of the Proceedings of the NATO Advanced Study Institute held at Erice, Italy, April 12-26, 1978
© 1979 Plenum Press, New York Softcover reprint of the hardcover 1st edition 1979 A Division of Plenum Publishing Corporation 227 West 17th Street, New York, N.Y. 10011
All rights reserved
78-24268
No part of this book may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, microfJ1ming, recording, or otherwise, without written permission from the Publisher
To
My Parents and
Uncle Luigi
PREFACE
This volume is the second part of the book on "Chromatin Structure and Function", which resulted from a NATO-Advanced Study Institute held at Erice during April 1978. In addition to giving an updated and detailed description of various levels of chromatin organization, i.e. octamers, nucleosomes, multimers, solenoid and higher order fibers (including the most recent, yet unpublished, findings), it focuses, in a tutorial and organic format, on the possible mechanisms controlling transcription and on the basic biological phenomena (either genetic or epigenetic) related to cell aging, cell cycle, differentiation, transformation and chemical carcinogenesis. The most significant (sometime spirite~ discussion sessions have been included at the end of every section. Their clarifying nature is further supported by the final section (V), which summarizes and reviews the current state of the art on the genetic apparatus and its constituents. All chapters have selected up-to-date references; quite a few have an extensive bibliography both in terms of basic reference books and most recent findings.
A few chapters, dealing at the level of intact cell and/or in classical genetic terms, with aging, differentiation and neoplastic transformation, have been included to furnish a more comprehensive view of fundamental cell functions directly and indirectly related to the structure and function of the genetic apparatus.
At the same time it is hoped that interested students and investigators will find in the chapters of this volume the necessary and stimulating introduction to the wide variety of fundamental mechanism and phenomena occurring in higher eukaryotes.
Claudio Nicolini
vii
CONTENTS OF PART A
Introduction C. Nicolini
SECTION I: WHAT IS THE CHROMATIN?
Properties and Composition of Isolat.ed Chromatin
J. Bonner
Expressed and Nonexpressed Portions of the Genome: Their Separation and Their Characterization • • • • •
J. Bonner
Discussion
SECTION II: PHYSICAL, CHEMICAL AND BIOLOGICAL TECHNIQUES FOR STUDYInG NUCLEOSOME,
CHROMATIN, CHROMOSOME AND NUCLEI
Electron Microscopy: A Tool for Visualizing Chromatin
A. L. Olins
Transcriptional Control of Native Chromatin
R. S. Gilmour
Circular Dichroism of DNA, Protein and Chromatin • • • • • •
G. D. Fasman
Important Hydrodynamic and Spectroscopic Techniques in the Field of Chromatin Structure • • • • • • • • • • • •
D. E. Olins ix
xi
3
15
25
31
41
67
109
x
Preparation and Analysis of Core Particles and Nucleosomes: A Conveinient Method For Studying the Protein Composition of Nucleosomes Using Protamine-Release into Triton-Acid-Urea Gels ••• • • •
B. R. Shaw and R. G. Richards
The Interaction of Histones with DNA: Equilibrium Binding Studies
D. R. Burton, M. J. Butler, J. E. Hyde, D. Phillips, C. J. Skidmore and I. O. Walker
Nucleosome Shape and Structure in Solution from Flow Birefringence
R. E. Harrington
Scattering and Diffraction by Neutrons and X-rays Study of Chromatin
J. F. Pardon
in the
Nuclear Magnetic Resonance Studies of Nucleic Acids and Proteins
P. O. P. Ts'o and L.-S. Kan
Techniques for Cytochemical Studies of the Nucleus and its Substructures
T. Caspers son
Chromatin Study in Situ: I. Image Analysis F. Kendall, F. Beltrame and C. Nicolini
Chromatin Study in Situ: II. Static and Flow Microfluorimetry
C. Nicolini, S. Parodi, S. Lessin,
CONTENTSOFPARTA
125
137
167
187
217
251
265
293
A. Belmont, S. Abraham, S. Zietz and M. Grattarola
Chromatin Study in Situ: III. Differential Effects of Feulgen Hydrolysis •
W. A. Linden, S. M. Fang, S. Zietz and C. Nicolini
323
Scanning and Flow Photometry of Chromosomes • • • • • • •• 341 M. L. Mendelsohn
Discussion 357
Index • • • • xxi
CONTENTS OF PART B
Introduction C. Nicolini
SECTION III: VARIOUS LEVELS OF CHROMATIN ORGANIZATION AND MECHANISMS
FOR TRANSCRIPTIONAL CONTROL
Histones Assembly and Their Structural Role for Nucleosome Core
N. M. Maraldi, S. Capitani, L. Cocco and F. A. Manzoli
Nuclease Digestion and the Structure of Chromatin ••••••
K. E. Van Holde, J. R. Allen, J. K. Tatchell and W. O. Weischet
Reconstitution of Nucleosomes • • • K. Tatchell and K. E. Van Holde
Corden, D. Lohr,
Conformation of Polynucleosomes in Low Ionic Strength Solution
B. R. Shaw and K. S. Schmitz
Chromatin Structure: Relation of Nucleosomes of DNA Sequences • • • • • • • • •
A. Prunell
Histone Complexes, Nucleosomes, Chromatin and Cell-Cycle Dependent Modification of Histones . • . . . . . . . . . .
H. W. E. Rattle, G. G. Kneale, J. P. Baldwin, H. R. Matthews, C. Crane-Robinson, P. D. Cary, B. G. Carpenter, P. Suau and E. M. Bradbury
xi
xiii
371
389
413
427
441
451
xii CONTENTS OF PART B
Evidence for Superstructures of Wet Chromatin • • • • • •
S. Basu
Chromatin Fractionation and the Properties of Transcriptionally Active Regions of Chromatin • • • • • • • • • • •
J. Gottesfeld
Chromatin Reconstitution and Non-Histone Proteins
R. S. Gilmour
Discussion
SECTION IV: STRUCTURE-FUNCTION OF THE GENETIC APPARATUS AND CELL CYCLE, AGING, NEOPLASTIC TRANSFORMATION,
DIFFERENTIATION, CHEMICAL CARCINOGENESIS
The Structure and Function of Chromatin in Lower Eukaryotes
K. E. Davies and I. O. Walker
Chromatin Structure from Angstrom to Micorn Levels, and Its Relationship to Mammalian Cell Proliferation
C. Nicolini
Chromatin Pattern in Situ: Dependence upon Cell Cycle, Preimplantation and Development, and Cellular Aging in Vitro •••••••••••
W. Sawicki
Neoplastic Transformation: The Relevance of in Vitro Studies for the Understanding of Tumor Pathenogenesis and Neoplastic Growth • • • • • • . • • • . • • • • .
L. A. Smets
Cell Differentiation and Malignancy in Leukemia • • • • • • •
L. Sachs
Cellular Morphometry in Transformation, Differentiation and Aging • •
S. Parodi, G. Brambilla, F. Beltrame, S. and C. A. Nicolini
Lessin
515
541
561
593
599
613
667
683
705
721
CONTENTS OF PART B
Basic Mechanisms in Chemical Carcinogenesis • • • • • • • • P. O. P. Ts'o
Carcinogen Induced Alteration in Gene Packing and Its Possible Significance in Carcinogenesis
P. M. Rao, S. Rajalakshmi and D. S. R. Sarma
Covalent Binding of a Carcinogen to DNA as a Probe of Chromatin Structure
F. X. Wilhelm, M. L. Wilhelm and G. Metzger
Carcinogenesis, DNA Repair and Chromatin W. G. Verly and L. Thibodeau
Electromagnetic Induction of Electrochemical Information at Cell Surfaces: Application to Chromatin
xiii
751
771
781
803
Structure Modification • • • • •• 811 A. Chiabrera, M. Hinsenkamp, A. A. Pilla and C. Nicolini
Discussion
SECTION V: REVIEW AND SUMMARY OF THE GENETIC APPARATUS
Session I: Basic Components of the Genetic Apparatus • • • • • • • • • • •
E. M. Bradbury, S. Bram, G. Fasman, D. Olins, J. Pardon, A. Prunell, R. Sperling, K. E. Van Holde and I. Walker
Session II: The Second Level of Organization -Chromat in . • • • • . • • . • • • . .
E. M. Bradbury, G. Fasman, S. Gilmour, J. Gottesfeld, C. Nicolini, D. Olins, J. Pardon, B. Shaw and F. X. Wilhelm
Session III: The Third Level of Organization E. M. Bradbury, S. Bram, J. Gottesfeld, F. Kendall, C. Nicolini and I. Walker
Session IV: Generalized Biological Effects •••• A. Chiabrera, W. Linden, C. Nicolini, S. Parodi and W. Sawicki
Index ••
841
849
855
861
867
871
INTRODUCTION
During April 12-26, 1978, the eighth course of the International School of Biophysics, a NATO - Advanced Study Institute, was held at the "Ettore Majorana Center for Scientific Culture" in Erice, Sicily, co-sponsored by the North Atlantic Treaty Organization, National Science Foundation (USA), The Italian Government and the European Molecular Biology Organization.
The subject of the course was "Chromatin StructUl'e and Function" with 91 participants (from 15 different countries) selected worldwide.
The current high level of interest in the structure and function of chromatin is adequately testified by the thousands of manuscripts which have appeared in the literature during the past five years which have pertained to areas directly related to these subjects. The scope and depth of knowledge and range of disciplines which have been brought to bear in the study of chromatin structure and its relation to cell function are indicated in several recent review articles.
One of the objectives that the Erice course has successfully accomplished has been to promote the close communication and collaboration among scientists active in this field of "chromatin" with different backgrounds and expertise, such as: biologists, physicists, biophysicists, biochemists, engineers, and physicians toward an advancement of knowledge in this basic and interdisciplinary field of life sciences.
The implications of a definite characterization of chromatin structure and function are now obvious since they bear directly on the mechanisms of cancer, aging, medical genetics, chemical carcinogenesis, and cell proliferation.
During the Advanced Study Institute and consequent proceedings, now published by PLENUM, we adopted a structUl'ed, organic and comprehensive app~ach to the p~blem of chromatin structUl'e and function (both at the molecular and cellular level) with focus on
xv
xvi INTRODUCTION
the methodologies, techniques and on the various levels of chromatin organization, stressing their implications for cell function.
Today new knowledge, not only in biophysics which is at the crossing of several "hard" and "soft" sciences, is frequently produced by deeply interdisciplinary interactions among scientists of different backgrounds. In this respect, chromatin constitutes a unique example since we may identify at least three dimensions where research is conducted: one (X-axis), along the level of chromatin organization studied from the Angstrom (histone protein octamers and the nucleosome) through the multimeters and solenoid, up to the micron level, i.e. intact interphase nuclei and metaphase chromosome; the second (Y-axis), along the methodology and technology utilized, from biology through chemistry up to physics and engineering; the third one (Z-axis), along the specific biological system or mechanism, approached from the concept of the cell cycle, through aging and carcinogenesis, up to differentiation. Each investigator, has his own X-Y-Z coordinates in such a "three dimensional configuration" and frequently conducts his search in an isolated environment with occasional and superficial contacts with the remaining "scientific space". As occurs also in all other human endeavors, this frequently leads to an acritical intellectual inertia or at best to self-perpetuating inner circles, whose primary functions are to produce an avalanche of "papers", some of which do fulfill a need for exchange of new findings, but some of which are generated to satisfy personal, academic or economic imperatives. Looking at the rate at which the scientific "literature" is growing, one wonders whether knowledge is growing at the same rate, or whether intellectual energy and economical resources (of finite amount in any society) are wasted because proper '~alue criteria and channels of communications" are not open among scientists active in parallel approaches toward the solution of the same problems. Need exists, therefore, for the adoption of an absolute reference system where findings and efforts are to be judged and/or comprehensive approaches developed. This should also help to decrease the so frequently encountered intellectual arrogance (due to cultural "isolation" or lack of sophistication) and increase the sense of self-criticism and humility (in terms of a more open attitude toward new technology or ideas) in studying the complex mechanisms determining the structure and function of living systems. In the twentieth century any significant conquest of the human race (as splitting the atom or reaching the moon) has been the rigorous (step-by-step, without miraculous shortcuts, as attempted unsuccessfully over the past 20 years in cancer research) and analytical work of teams of scientists with different "hard science" backgrounds and expertise. Even if knowledge is transmitted to younger generations (in the University) through traditionally separated disciplines such as engineering, physics, chemistry, biology or medicine, this surely does not correspond to the way new knowledge is acquired in all fields of sciences, and particularly in life science.
INTRODUCTION
To contribute toward the filling of such gaps, participants and lecturers of the Erice Advanced Study Institute and contributions to this book on chromatin have been chosen in such a manner as to warrant spherically isotropic distribution in the threedimensional space outlined above.
xvii
The simultaneous contribution of several outstanding scientists, each one a world-wide leader in his own specialization, has permitted me to edit this comprehensive book, which hopefully respects such interdisciplinary aims. Several books are available in the area, but they usually cover specific topics, focusing mostly either on a given technique, biological problem, chromatin constituents, or level of organization, but few are covering the extremely broad field in an organic and tutorial format (Le. comprehensive and accessible with profit to a wider scientific community) from histone proteins to intact nuclei, from molecular to cytological approaches.
Within the inherent limitations of any conference proceeding (such as this) I have attempted to structure the entire book in an organic and tutorial format, such as to have not a scattered collection of research papers, incoherent and with frequent unnecessary overlap, but a sequential series of chapters dealt in depth, from the basic properties of chromatin throughout all the numerous techniques employed (occasionally treated in details, including a brief summary of their basic physical principles), through the various levels of chromatin organization, up to their implications for cell function.
The Institute's content did not reflect the volume of literature pertaining to a particular technique or chromatin component, but how they are uniquely useful in providing additional and complementary information on chromatin structure and its relation to cell function.
Specifically the book consists of four parts, each one followed by a chapter on the pertinent discussion which occurred at the time of oral presentation.
I) an introduction to the physical, chemical and biological properties of isolated chromatin and their relationship to chromatin of living cells (Janes Bonner, USA).
II) basic chapters which present the theory and instrumentation of all the numerous physical, chemical, functional, morphological techniques and methodology applicable to the study of chromatin, both IN SITU and isolated from living cells (Stuart Gilmour, UK; G. Harrington, USA; Gerald Fasman, USA; Ada Olins, USA; Donald Olins, USA; Ian Walker, UK; Frank Kendall, USA; John Pardon, UK; Edwin M. Bradbury, UK; Tobjorn Caspersson, Sweden; Claudio Nicolini, USA; Mortimer Mendelsohn, USA: B. Shaw, USA; Paul Ts'o, USA).
xviii
III)
INTRODUCTION
various levels of chromatin organization as determined by the above techniques, i.e. nucleosome, multimers, chromatin, chromosomal proteins and their enzymatic modifications, such as acetylation, methylation, and phosphorylations in determining gene expression and chromatin organization (Kensel Van Holde, USA; I. o. Walker, UK; A. Prunell, USA; John Ploem, The Netherlands; Joel Gottesfield, UK; S. Bram, France; G. Dixon, Canada; Donald Olins, USA; B. Shaw, USA; S. Gilmour, UK).
IV) structure and function of the genetic apparatus in the mammalian cell, stressing their relationship to neoplastic transformation, aging, cell cycle, medical genetics differentiation, and chemical carcinogenesis (Edwin Bradbury, UK; Louis Smets, The Netherlands; Silvio Parodi, Italy; W. Sawicki, Poland; Walfried Linden, West Germany; Leo Sachs, Israel; Paul Tslo, USA; Claudio Nicolini, USA; D. S. Sarma, Canada; Ian Walker, UK; Ferruccio Ritossa, Italy; F. X. Wilhelm, France; G. Verly, France).
At the end of the book, (part V) I have included a final review and synthesis of the genetic apparatus dealing with clarifications of specific topics, or focusing on controversial issues as models for chromatin structure and in new avenues as biophysical cytology or neutron diffraction. The course was of such interdisciplinary nature that the scientists specialized in one field have been teaching scientists highly qualified in a different area. The role of lecturer and student was frequently interchanged during the meeting as the theme of common interest (chromatin study) was developed from the viewpoint of different sciences, in a beautiful small town on top of a mountain overlooking the Mediterranean (that, according to a legend, was founded by Erice, son of Venus, more than three thousand years ago). In synthetic analytical terms we could say, with L. Sachs, that se + AA = LE3 that is Science in Chromatin p'lus Art in Archaeo'logy equa'l Life in El"ice. It is not paradox then to state that the Chromatin Institute was held in the same geographical region where a few thousand years before the Greek Leucippus and Democritus and 'later on the Roman Lucretius (in his poem "De Rerum Natura") gave the foundation of biophysics3 describing how the atoms3 after val"ious interactions3 acquire stab'le configupations3 corresponding to the 'living and inanimate wor'lds. This simple and unitary theory, which brings 'life science into the realm of physical science3 remarkably maintains its validity even after several centuries of alternative vicissitudes.
To follow the evolution of such fundamental ideas in successive steps, is quite impossible in such context: I like however only to recall that the content of this Erice Institute (and therefore of this book) which relates chromatin structure to cell function, represents one of the most recent developments of that old idea.
INTRODUCTION xix
Following the earlier discovery of the direct relationship between spatial structures of such molecules such as methane and benzene and chemical activity, the discovery in 1953 of the structure of the double helix of DNA represents the turning point for a similar relationship between three dimensional structure and biology. It is indeed this relationship that emerged as one of the most intriguing "take home messages" from the institute: the relationship between cell function and tertiary {nucleosome} and quaternary {solenoid or other form of superpacking} structures of chromatin DNA, as modulated by interaction with histone and non-histone proteins (and their enzymatic modifications) during the cell cycle, cell transformation, aging, and differentiation. In addition to affirm a more dynamic view of DNA organization in isolated chromatin, the Erice Institute raises the question as to whether tertiary -quaternary structures are specifically linked to a higher order {quinternary} organization which can now be detected "In Situ" by means of recent technological advancements in the area of biophysical cytology, to an extent up to now impossible to any human observer or biochemical assay.
In conclusion, I hope that this book will constitute a useful and stimulating guideline to doctoral and post-doctoral students as well as to senior scientists, interested in the most recent developments in the wide interdisciplinary approach to structure and function of the genetic apparatus and its constituents and their relationships to cell function.
Finally, I would like to express my graditude to Professor Antonio Borsellino for giving me the opportunity to direct the eighth course of the International School of Biophysics (which have seen in previous years the active participation also of several Noble-Prize winners, such as Wald, Eccles, Katz) and to Ms. Pinola and Dr. Grabriele of the Majorana Centre for coupling high efficiency and courtesy in a unique cultural setting. My last, but not least, acknowledgement is to my wife Julia and my Uncle Luigi for their constant advice and dedication, considering that to realize and operate within a "three-dimensional scientific space" was a quite difficult and absorbing experience, even if challenging, not only in purely scientific terms, but also for its profound social implications.
Claudio Nicolini