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- Volume 77, 2008
Annual Review of Biochemistry - Volume 77, 2008
Volume 77, 2008
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Discovery of G Protein Signaling
Vol. 77 (2008), pp. 1–13More LessThe mechanism of transmembrane signaling by the receptor-activated adenylyl cyclase was an enigma. It was suggested that hydrolysis of GTP is a turn-off mechanism that resets the active adenylyl cyclase to the inactive state. To test this hypothesis, we developed a specific GTPase assay and found that the catecholamine adrenergic agonists stimulated the hydrolysis of GTP. To resolve the question of how the hormone concurrently stimulates GTP hydrolysis and activates the adenylyl cyclase, we suggested the regulatory GTPase cycle. Thus, because the hormone facilitates the binding of GTP, which is subsequently hydrolyzed, the regulatory cycle results in a hormone-stimulated GTPase activity. This model also predicts that two mechanisms could account for stimulation of adenylyl cyclase activity—either by the familiar hormone stimulation of the activation reaction or by an inhibition of the turn-off reaction. Indeed, we showed that cholera toxin enhances adenylyl cyclase activity by inhibition of GTP hydrolysis. Finally, we also showed that the hormone-activated receptor stimulates adenylyl cyclase activity by facilitating the exchange of bound GDP for free GTP. Thus, we presented, for the first time, an explicit mechanism for receptor action.
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Moments of Discovery
Vol. 77 (2008), pp. 15–44More LessDevoted teachers and mentors during early childhood and adolescence nurtured my ambition to become a scientist, but it was not until I actually began doing experiments in college and graduate school that I was confident about that choice and of making it a reality. During my postdoctoral experiences and thereafter, I made several significant advances, most notably the discovery of the then novel acyl- and aminoacyl adenylates: the former as intermediates in fatty acyl coenzyme A (CoA) formation and the latter as precursors to aminoacyl tRNAs. In the early 1970s, my research changed from a focus on transcription and translation in Escherichia coli to the molecular genetics of mammalian cells. To that end, my laboratory developed a method for creating recombinant DNAs that led us and others, over the next two decades, to create increasingly sophisticated ways for introducing “foreign” DNAs into cultured mammalian cells and to target modifications of specific chromosomal loci. Circumstances surrounding that work drew me into the public policy debates regarding recombinant DNA practices. As an outgrowth of my commitment to teaching, I coauthored several textbooks on molecular genetics and a biography of George Beadle. The colleagues, students, and wealth of associates with whom I interacted have made being a scientist far richer than I can have imagined.
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In singulo Biochemistry: When Less Is More
Vol. 77 (2008), pp. 45–50More LessIt has been over one-and-a-half decades since methods of single-molecule detection and manipulation were first introduced in biochemical research. Since then, the application of these methods to an expanding variety of problems has grown at a vertiginous pace. While initially many of these experiments led more to confirmatory results than to new discoveries, today single-molecule methods are often the methods of choice to establish new mechanism-based results in biochemical research. Throughout this process, improvements in the sensitivity, versatility, and both spatial and temporal resolution of these techniques has occurred hand in hand with their applications. We discuss here some of the advantages of single-molecule methods over their bulk counterparts and argue that these advantages should help establish them as essential tools in the technical arsenal of the modern biochemist.
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Advances in Single-Molecule Fluorescence Methods for Molecular Biology
Vol. 77 (2008), pp. 51–76More LessEver since their introduction two decades ago, single-molecule (SM) fluorescence methods have matured and branched out to address numerous biological questions, which were inaccessible via ensemble measurements. Among the current arsenal, SM fluorescence techniques have capabilities of probing the dynamic interactions of nucleic acids and proteins via Förster (fluorescence) resonance energy transfer (FRET), tracking single particles over microns of distances, and deciphering the rotational motion of multisubunit systems. In this exciting era of transitioning from in vitro to in vivo and in situ conditions, it is anticipated that SM fluorescence methodology will become a common tool of molecular biology.
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How RNA Unfolds and Refolds
Vol. 77 (2008), pp. 77–100More LessUnderstanding how RNA folds and what causes it to unfold has become more important as knowledge of the diverse functions of RNA has increased. Here we review the contributions of single-molecule experiments to providing answers to questions such as: How much energy is required to unfold a secondary or tertiary structure? How fast is the process? How do helicases unwind double helices? Are the unwinding activities of RNA-dependent RNA polymerases and of ribosomes different from other helicases? We discuss the use of optical tweezers to monitor the unfolding activities of helicases, polymerases, and ribosomes, and to apply force to unfold RNAs directly. We also review the applications of fluorescence and fluorescence resonance energy transfer to measure RNA dynamics.
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Single-Molecule Studies of Protein Folding
Vol. 77 (2008), pp. 101–125More LessAlthough protein-folding studies began several decades ago, it is only recently that the tools to analyze protein folding at the single-molecule level have been developed. Advances in single-molecule fluorescence and force spectroscopy techniques allow investigation of the folding and dynamics of single protein molecules, both at equilibrium and as they fold and unfold. The experiments are far from simple, however, both in execution and in interpretation of the results. In this review, we discuss some of the highlights of the work so far and concentrate on cases where comparisons with the classical experiments can be made. We conclude that, although there have been relatively few startling insights from single-molecule studies, the rapid progress that has been made suggests that these experiments have significant potential to advance our understanding of protein folding. In particular, new techniques offer the possibility to explore regions of the energy landscape that are inaccessible to classical ensemble measurements and, perhaps, to observe rare events undetectable by other means.
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Structure and Mechanics of Membrane Proteins
Vol. 77 (2008), pp. 127–148More LessEvolution has tuned membrane proteins to exist in a lipid bilayer, provide for cell-cell communication, transport solutes, and convert energies. These proteins exhibit a hydrophobic belt that interacts with the lipid bilayer. Detergents are therefore used to extract membrane proteins and keep them in solution for purification and subsequent analyses. However, most membrane proteins are unstable when solubilized and hence often not accessible to NMR or X-ray crystallography. The atomic force microscope (AFM) is a powerful tool for imaging and manipulating membrane proteins in their native state. Superb images of native membranes have been recorded, and a quantitative interpretation of the data acquired using the AFM tip has become possible. In addition, multifunctional probes to simultaneously acquire information on the topography and electrical properties of membrane proteins have been produced. This progress is discussed here and fosters expectations for future developments and applications of AFM and single-molecule force spectroscopy.
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Single-Molecule Studies of RNA Polymerase: Motoring Along
Vol. 77 (2008), pp. 149–176More LessSingle-molecule techniques have advanced our understanding of transcription by RNA polymerase (RNAP). A new arsenal of approaches, including single-molecule fluorescence, atomic-force microscopy, magnetic tweezers, and optical traps (OTs) have been employed to probe the many facets of the transcription cycle. These approaches supply fresh insights into the means by which RNAP identifies a promoter, initiates transcription, translocates and pauses along the DNA template, proofreads errors, and ultimately terminates transcription. Results from single-molecule experiments complement the knowledge gained from biochemical and genetic assays by facilitating the observation of states that are otherwise obscured by ensemble averaging, such as those resulting from heterogeneity in molecular structure, elongation rate, or pause propensity. Most studies to date have been performed with bacterial RNAP, but work is also being carried out with eukaryotic polymerase (Pol II) and single-subunit polymerases from bacteriophages. We discuss recent progress achieved by single-molecule studies, highlighting some of the unresolved questions and ongoing debates.
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Translation at the Single-Molecule Level
Vol. 77 (2008), pp. 177–203More LessDecades of studies have established translation as a multistep, multicomponent process that requires intricate communication to achieve high levels of speed, accuracy, and regulation. A crucial next step in understanding translation is to reveal the functional significance of the large-scale motions implied by static ribosome structures. This requires determining the trajectories, timescales, forces, and biochemical signals that underlie these dynamic conformational changes. Single-molecule methods have emerged as important tools for the characterization of motion in complex systems, including translation. In this review, we chronicle the key discoveries in this nascent field, which have demonstrated the power and promise of single-molecule techniques in the study of translation.
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Recent Advances in Optical Tweezers
Vol. 77 (2008), pp. 205–228More LessIt has been over 20 years since the pioneering work of Arthur Ashkin, and in the intervening years, the field of optical tweezers has grown tremendously. Optical tweezers are now being used in the investigation of an increasing number of biochemical and biophysical processes, from the basic mechanical properties of biological polymers to the multitude of molecular machines that drive the internal dynamics of the cell. Innovation, however, continues in all areas of instrumentation and technique, with much of this work focusing on the refinement of established methods and on the integration of this tool with other forms of single-molecule manipulation or detection. Although technical in nature, these developments have important implications for the expanded use of optical tweezers in biochemical research and thus should be of general interest. In this review, we address these recent advances and speculate on possible future developments.
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Mechanism of Eukaryotic Homologous Recombination
Vol. 77 (2008), pp. 229–257More LessHomologous recombination (HR) serves to eliminate deleterious lesions, such as double-stranded breaks and interstrand crosslinks, from chromosomes. HR is also critical for the preservation of replication forks, for telomere maintenance, and chromosome segregation in meiosis I. As such, HR is indispensable for the maintenance of genome integrity and the avoidance of cancers in humans. The HR reaction is mediated by a conserved class of enzymes termed recombinases. Two recombinases, Rad51 and Dmc1, catalyze the pairing and shuffling of homologous DNA sequences in eukaryotic cells via a filamentous intermediate on ssDNA called the presynaptic filament. The assembly of the presynaptic filament is a rate-limiting process that is enhanced by recombination mediators, such as the breast tumor suppressor BRCA2. HR accessory factors that facilitate other stages of the Rad51- and Dmc1-catalyzed homologous DNA pairing and strand exchange reaction have also been identified. Recent progress on elucidating the mechanisms of action of Rad51 and Dmc1 and their cohorts of ancillary factors is reviewed here.
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Structural and Functional Relationships of the XPF/MUS81 Family of Proteins
Vol. 77 (2008), pp. 259–287More LessProteins belonging to the XPF/MUS81 family play important roles in the repair of DNA lesions caused by UV-light or DNA cross-linking agents. Most eukaryotes have four family members that assemble into two distinct heterodimeric complexes, XPF-ERCC1 and MUS81-EME1. Each complex contains one catalytic and one noncatalytic subunit and exhibits endonuclease activity with a variety of 3′-flap or fork DNA structures. The catalytic subunits share a characteristic core containing an excision repair cross complementation group 4 (ERCC4) nuclease domain and a tandem helix-hairpin-helix (HhH)2 domain. Diverged domains are present in the noncatalytic subunits and may be required for substrate targeting. Vertebrates possess two additional family members, FANCM and Fanconi anemia-associated protein 24 kDa (FAAP24), which possess inactive nuclease domains. Instead, FANCM contains a functional Superfamily 2 (SF2) helicase domain that is required for DNA translocation. Determining how these enzymes recognize specific DNA substrates and promote key repair reactions is an important challenge for the future.
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Fat and Beyond: The Diverse Biology of PPARγ
Vol. 77 (2008), pp. 289–312More LessThe nuclear receptor PPARγ is a ligand-activated transcription factor that plays an important role in the control of gene expression linked to a variety of physiological processes. PPARγ was initially characterized as the master regulator for the development of adipose cells. Ligands for PPARγ include naturally occurring fatty acids and the thiazolidinedione (TZD) class of antidiabetic drugs. Activation of PPARγ improves insulin sensitivity in rodents and humans through a combination of metabolic actions, including partitioning of lipid stores and the regulation of metabolic and inflammatory mediators termed adipokines. PPARγ signaling has also been implicated in the control of cell proliferation, atherosclerosis, macrophage function, and immunity. Here, we review recent advances in our understanding of the diverse biological actions of PPARγ with an eye toward the expanding therapeutic potential of PPARγ agonist drugs.
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Eukaryotic DNA Ligases: Structural and Functional Insights
Vol. 77 (2008), pp. 313–338More LessDNA ligases are required for DNA replication, repair, and recombination. In eukaryotes, there are three families of ATP-dependent DNA ligases. Members of the DNA ligase I and IV families are found in all eukaryotes, whereas DNA ligase III family members are restricted to vertebrates. These enzymes share a common catalytic region comprising a DNA-binding domain, a nucleotidyltransferase (NTase) domain, and an oligonucleotide/oligosaccharide binding (OB)-fold domain. The catalytic region encircles nicked DNA with each of the domains contacting the DNA duplex. The unique segments adjacent to the catalytic region of eukaryotic DNA ligases are involved in specific protein-protein interactions with a growing number of DNA replication and repair proteins. These interactions determine the specific cellular functions of the DNA ligase isozymes. In mammals, defects in DNA ligation have been linked with an increased incidence of cancer and neurodegeneration.
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Structure and Energetics of the Hydrogen-Bonded Backbone in Protein Folding
Vol. 77 (2008), pp. 339–362More LessWe seek to understand the link between protein thermodynamics and protein structure in molecular detail. A classical approach to this problem involves assessing changes in protein stability resulting from added cosolvents. Under any given conditions, protein molecules in aqueous buffer are in equilibrium between unfolded and folded states, U(nfolded)
N(ative). Addition of organic osmolytes, small uncharged compounds found throughout nature, shift this equilibrium. Urea, a denaturing osmolyte, shifts the equilibrium toward U; trimethylamine N-oxide (TMAO), a protecting osmolyte, shifts the equilibrium toward N. Using the Tanford Transfer Model, the thermodynamic response to many such osmolytes has been dissected into groupwise free energy contributions. It is found that the energetics involving backbone hydrogen bonding controls these shifts in protein stability almost entirely, with osmolyte cosolvents simply dialing between solvent-backbone versus backbone-backbone hydrogen bonds, as a function of solvent quality. This reciprocal relationship establishes the essential link between protein thermodynamics and the protein's hydrogen-bonded backbone structure.
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Macromolecular Modeling with Rosetta
Rhiju Das, and David BakerVol. 77 (2008), pp. 363–382More LessAdvances over the past few years have begun to enable prediction and design of macromolecular structures at near-atomic accuracy. Progress has stemmed from the development of reasonably accurate and efficiently computed all-atom potential functions as well as effective conformational sampling strategies appropriate for searching a highly rugged energy landscape, both driven by feedback from structure prediction and design tests. A unified energetic and kinematic framework in the Rosetta program allows a wide range of molecular modeling problems, from fibril structure prediction to RNA folding to the design of new protein interfaces, to be readily investigated and highlights areas for improvement. The methodology enables the creation of novel molecules with useful functions and holds promise for accelerating experimental structural inference. Emerging connections to crystallographic phasing, NMR modeling, and lower-resolution approaches are described and critically assessed.
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Activity-Based Protein Profiling: From Enzyme Chemistry to Proteomic Chemistry
Vol. 77 (2008), pp. 383–414More LessGenome sequencing projects have provided researchers with a complete inventory of the predicted proteins produced by eukaryotic and prokaryotic organisms. Assignment of functions to these proteins represents one of the principal challenges for the field of proteomics. Activity-based protein profiling (ABPP) has emerged as a powerful chemical proteomic strategy to characterize enzyme function directly in native biological systems on a global scale. Here, we review the basic technology of ABPP, the enzyme classes addressable by this method, and the biological discoveries attributable to its application.
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Analyzing Protein Interaction Networks Using Structural Information
Vol. 77 (2008), pp. 415–441More LessDetermining protein interaction networks and predicting network changes in time and space are crucial to understanding and modeling a biological system. In the past few years, the combination of experimental and computational tools has allowed great progress toward reaching this goal. Experimental methods include the large-scale determination of protein interactions using two-hybrid or pull-down analysis as well as proteomics. The latter one is especially valuable when changes in protein concentrations over time are recorded. Computational tools include methods to predict and validate protein interactions on the basis of structural information and bioinformatics tools that analyze and integrate data for the same purpose. In this review, we focus on the use of structural information in combination with computational tools to predict new protein interactions, to determine which interactions are compatible with each other, to obtain some functional insight into single and multiple mutations, and to estimate equilibrium and kinetic parameters. Finally, we discuss the importance of establishing criteria to biologically validate protein interactions.
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Integrating Diverse Data for Structure Determination of Macromolecular Assemblies
Vol. 77 (2008), pp. 443–477More LessTo understand the cell, we need to determine the macromolecular assembly structures, which may consist of tens to hundreds of components. First, we review the varied experimental data that characterize the assemblies at several levels of resolution. We then describe computational methods for generating the structures using these data. To maximize completeness, resolution, accuracy, precision, and efficiency of the structure determination, a computational approach is required that uses spatial information from a variety of experimental methods. We propose such an approach, defined by its three main components: a hierarchical representation of the assembly, a scoring function consisting of spatial restraints derived from experimental data, and an optimization method that generates structures consistent with the data. This approach is illustrated by determining the configuration of the 456 proteins in the nuclear pore complex (NPC) from baker's yeast. With these tools, we are poised to integrate structural information gathered at multiple levels of the biological hierarchy—from atoms to cells—into a common framework.
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From the Determination of Complex Reaction Mechanisms to Systems Biology
Vol. 77 (2008), pp. 479–494More LessThis review presents several methods of determining complex chemical reaction mechanisms and their functions. One method is based on correlation functions of measured time series of concentrations of chemical species, another is on measurements of temporal responses of concentrations to various perturbations of arbitrary magnitude, the third deals with the analysis of oscillatory systems, and the fourth describes the use of genetic algorithms. All methods are applicable to chemical, biochemical, and biological reaction systems and to genetic networks. The methods depend on the design of appropriate experiments for the whole system and corresponding theories for interpretation that lead to information on the causal chemical connectivity of species, reaction pathways, reaction mechanisms, control centers in the system, and functions of the system. The first three methods require no assumption of a model or hypothesis, nor extensive calculations, unlike the interpretation of measurements made on a gene network at only one time. The methods offer advantageous approaches to systems biology.
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Previous Volumes
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Volume 93 (2024)
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Volume 92 (2023)
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Volume 91 (2022)
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Volume 90 (2021)
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Volume 89 (2020)
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Volume 88 (2019)
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Volume 87 (2018)
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Volume 86 (2017)
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Volume 85 (2016)
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Volume 84 (2015)
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Volume 83 (2014)
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Volume 82 (2013)
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Volume 81 (2012)
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Volume 80 (2011)
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Volume 79 (2010)
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Volume 78 (2009)
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Volume 77 (2008)
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Volume 76 (2007)
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Volume 75 (2006)
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Volume 74 (2005)
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Volume 73 (2004)
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Volume 72 (2003)
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Volume 71 (2002)
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Volume 70 (2001)
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Volume 69 (2000)
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Volume 68 (1999)
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Volume 67 (1998)
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Volume 66 (1997)
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Volume 65 (1996)
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Volume 64 (1995)
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Volume 63 (1994)
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Volume 62 (1993)
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Volume 61 (1992)
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Volume 60 (1991)
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Volume 59 (1990)
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Volume 58 (1989)
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Volume 57 (1988)
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Volume 56 (1987)
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Volume 55 (1986)
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Volume 54 (1985)
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Volume 53 (1984)
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Volume 52 (1983)
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Volume 51 (1982)
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Volume 50 (1981)
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Volume 49 (1980)
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Volume 48 (1979)
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Volume 47 (1978)
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Volume 46 (1977)
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Volume 45 (1976)
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Volume 44 (1975)
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Volume 43 (1974)
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Volume 42 (1973)
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Volume 41 (1972)
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Volume 40 (1971)
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Volume 39 (1970)
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Volume 38 (1969)
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Volume 37 (1968)
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Volume 36 (1967)
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Volume 35 (1966)
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Volume 34 (1965)
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Volume 33 (1964)
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Volume 32 (1963)
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Volume 31 (1962)
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Volume 30 (1961)
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Volume 29 (1960)
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Volume 28 (1959)
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Volume 27 (1958)
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Volume 26 (1957)
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Volume 25 (1956)
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Volume 24 (1955)
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Volume 23 (1954)
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Volume 22 (1953)
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Volume 21 (1952)
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Volume 20 (1951)
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Volume 19 (1950)
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Volume 18 (1949)
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Volume 17 (1948)
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Volume 16 (1947)
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Volume 15 (1946)
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Volume 14 (1945)
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Volume 13 (1944)
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Volume 12 (1943)
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Volume 11 (1942)
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Volume 10 (1941)
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Volume 9 (1940)
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Volume 8 (1939)
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Volume 7 (1938)
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Volume 6 (1937)
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Volume 5 (1936)
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Volume 4 (1935)
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Volume 3 (1934)
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Volume 2 (1933)
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Volume 1 (1932)
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Volume 0 (1932)