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- Volume 47, 2013
Annual Review of Genetics - Volume 47, 2013
Volume 47, 2013
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Causes of Genome Instability
Vol. 47 (2013), pp. 1–32More LessGenomes are transmitted faithfully from dividing cells to their offspring. Changes that occur during DNA repair, chromosome duplication, and transmission or via recombination provide a natural source of genetic variation. They occur at low frequency because of the intrinsic variable nature of genomes, which we refer to as genome instability. However, genome instability can be enhanced by exposure to external genotoxic agents or as the result of cellular pathologies. We review the causes of genome instability as well as how it results in hyper-recombination, genome rearrangements, and chromosome fragmentation and loss, which are mainly mediated by double-strand breaks or single-strand gaps. Such events are primarily associated with defects in DNA replication and the DNA damage response, and show high incidence at repetitive DNA, non-B DNA structures, DNA-protein barriers, and highly transcribed regions. Identifying the causes of genome instability is crucial to understanding genome dynamics during cell proliferation and its role in cancer, aging, and a number of rare genetic diseases.
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Radiation Effects on Human Heredity
Vol. 47 (2013), pp. 33–50More LessIn experimental organisms such as fruit flies and mice, increased frequencies in germ cell mutations have been detected following exposure to ionizing radiation. In contrast, there has been no clear evidence for radiation-induced germ cell mutations in humans that lead to birth defects, chromosome aberrations, Mendelian disorders, etc. This situation exists partly because no sensitive and practical genetic marker is available for human studies and also because the number of people exposed to large doses of radiation and subsequently having offspring was small until childhood cancer survivors became an important study population. In addition, the genome of apparently normal individuals seems to contain large numbers of alterations, including dozens to hundreds of nonfunctional alleles. With the number of mutational events in protein-coding genes estimated as less than one per genome after 1 gray (Gy) exposure, it is unsurprising that genetic effects from radiation have not yet been detected conclusively in humans.
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Dissecting Social Cell Biology and Tumors Using Drosophila Genetics
Vol. 47 (2013), pp. 51–74More LessCancer was seen for a long time as a strictly cell-autonomous process in which oncogenes and tumor-suppressor mutations drive clonal cell expansions. Research in the past decade, however, paints a more integrative picture of communication and interplay between neighboring cells in tissues. It is increasingly clear as well that tumors, far from being homogenous lumps of cells, consist of different cell types that function together as complex tissue-level communities. The repertoire of interactive cell behaviors and the quantity of cellular players involved call for a social cell biology that investigates these interactions. Research into this social cell biology is critical for understanding development of normal and tumoral tissues. Such complex social cell biology interactions can be parsed in Drosophila. Techniques in Drosophila for analysis of gene function and clonal behavior allow us to generate tumors and dissect their complex interactive biology with cellular resolution. Here, we review recent Drosophila research aimed at understanding tissue-level biology and social cell interactions in tumors, highlighting the principles these studies reveal.
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Estimation and Partition of Heritability in Human Populations Using Whole-Genome Analysis Methods
Vol. 47 (2013), pp. 75–95More LessUnderstanding genetic variation of complex traits in human populations has moved from the quantification of the resemblance between close relatives to the dissection of genetic variation into the contributions of individual genomic loci. However, major questions remain unanswered: How much phenotypic variation is genetic; how much of the genetic variation is additive and can be explained by fitting all genetic variants simultaneously in one model, and what is the joint distribution of effect size and allele frequency at causal variants? We review and compare three whole-genome analysis methods that use mixed linear models (MLMs) to estimate genetic variation. In all methods, genetic variation is estimated from the relationship between close or distant relatives on the basis of pedigree information and/or single nucleotide polymorphisms (SNPs). We discuss theory, estimation procedures, bias, and precision of each method and review recent advances in the dissection of genetic variation of complex traits in human populations. By using genome-wide data, it is now established that SNPs in total account for far more of the genetic variation than the statistically highly significant SNPs that have been detected in genome-wide association studies. All SNPs together, however, do not account for all of the genetic variance estimated by pedigree-based methods. We explain possible reasons for this remaining “missing heritability.”
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Detecting Natural Selection in Genomic Data
Vol. 47 (2013), pp. 97–120More LessThe past fifty years have seen the development and application of numerous statistical methods to identify genomic regions that appear to be shaped by natural selection. These methods have been used to investigate the macro- and microevolution of a broad range of organisms, including humans. Here, we provide a comprehensive outline of these methods, explaining their conceptual motivations and statistical interpretations. We highlight areas of recent and future development in evolutionary genomics methods and discuss ongoing challenges for researchers employing such tests. In particular, we emphasize the importance of functional follow-up studies to characterize putative selected alleles and the use of selection scans as hypothesis-generating tools for investigating evolutionary histories.
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Adaptive Translation as a Mechanism of Stress Response and Adaptation
Vol. 47 (2013), pp. 121–137More LessThe composition of the cellular proteome is commonly thought to strictly adhere to the genetic code. However, accumulating evidence indicates that cells also regulate the synthesis of mutant protein molecules that deviate from the genetic code. Production of mutant proteins generally occurs when cells are stressed or when they undergo environmental adaptation, but production varies in amounts and specificity. The deliberate synthesis of mutant proteins suggests that some of these proteins can be useful in cellular stress response and adaptation. This review describes the occurrence of, the translation mechanisms for, and the functional hypotheses on regulated synthesis of mutant proteins.
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Organizing Principles of Mammalian Nonsense-Mediated mRNA Decay
Vol. 47 (2013), pp. 139–165More LessCells use messenger RNAs (mRNAs) to ensure the accurate dissemination of genetic information encoded by DNA. Given that mRNAs largely direct the synthesis of a critical effector of cellular phenotype, i.e., proteins, tight regulation of both the quality and quantity of mRNA is a prerequisite for effective cellular homeostasis. Here, we review nonsense-mediated mRNA decay (NMD), which is the best-characterized posttranscriptional quality control mechanism that cells have evolved in their cytoplasm to ensure transcriptome fidelity. We use protein quality control as a conceptual framework to organize what is known about NMD, highlighting overarching similarities between these two polymer quality control pathways, where the protein quality control and NMD pathways intersect, and how protein quality control can suggest new avenues for research into mRNA quality control.
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Control of Nuclear Activities by Substrate-Selective and Protein-Group SUMOylation
Vol. 47 (2013), pp. 167–186More LessReversible modification of proteins by SUMO (small ubiquitin-like modifier) affects a large number of cellular processes. In striking contrast to the related ubiquitin pathway, only a few enzymes participate in the SUMO system, although this pathway has numerous substrates as well. Emerging evidence suggests that SUMOylation frequently targets entire groups of physically interacting proteins rather than individual proteins. Protein-group SUMOylation appears to be triggered by recruitment of SUMO ligases to preassembled protein complexes. Because SUMOylation typically affects groups of proteins that bear SUMO-interaction motifs (SIMs), protein-group SUMOylation may foster physical interactions between proteins through multiple SUMO-SIM interactions. Individual SUMO modifications may act redundantly or additively, yet they may mediate dedicated functions as well. In this review, we focus on the unorthodox principles of this pathway and give examples for SUMO-controlled nuclear activities. We propose that collective SUMOylation is typical for nuclear assemblies and argue that SUMO serves as a distinguishing mark for functionally engaged protein fractions.
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Genomic Imprinting: Insights From Plants
Vol. 47 (2013), pp. 187–208More LessImprinted gene expression—the biased expression of alleles dependent on their parent of origin—is an important type of epigenetic gene regulation in flowering plants and mammals. In plants, genes are imprinted primarily in the endosperm, the triploid placenta-like tissue that surrounds and nourishes the embryo during its development. Differential allelic expression is correlated with active DNA demethylation by DNA glycosylases and repressive targeting by the Polycomb group proteins. Imprinted gene expression is one consequence of a large-scale remodeling to the epigenome, primarily directed at transposable elements, that occurs in gametes and seeds. This remodeling could be important for maintaining the epigenome in the embryo as well as for establishing gene imprinting.
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Regulation of Bacterial Metabolism by Small RNAs Using Diverse Mechanisms
Vol. 47 (2013), pp. 209–232More LessBacteria live in many dynamic environments with alternating cycles of feast or famine that have resulted in the evolution of mechanisms to quickly alter their metabolic capabilities. Such alterations often involve complex regulatory networks that modulate expression of genes involved in nutrient uptake and metabolism. A great number of protein regulators of metabolism have been characterized in depth. However, our ever-increasing understanding of the roles played by RNA regulators has revealed far greater complexity to regulation of metabolism in bacteria. Here, we review the mechanisms and functions of selected bacterial RNA regulators and discuss their importance in modulating nutrient uptake as well as primary and secondary metabolic pathways.
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Bacteria and the Aging and Longevity of Caenorhabditis elegans
Vol. 47 (2013), pp. 233–246More LessThe molecular genetic analysis of longevity of Caenorhabditis elegans has yielded fundamental insights into evolutionarily conserved pathways and processes governing the physiology of aging. Recent studies suggest that interactions between C. elegans and its microbial environment may influence the aging and longevity of this simple host organism. Experimental evidence supports a role for bacteria in affecting longevity through distinct mechanisms—as a nutrient source, as a potential pathogen that induces double-edged innate immune and stress responses, and as a coevolved sensory stimulus that modulates neuronal signaling pathways regulating longevity. Motivating this review is the anticipation that the molecular genetic dissection of the integrated host immune, stress, and neuroendocrine responses to microbes in C. elegans will uncover basic insights into the cellular and organismal physiology that governs aging and longevity.
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The Genotypic View of Social Interactions in Microbial Communities
Vol. 47 (2013), pp. 247–273More LessDense and diverse microbial communities are found in many environments. Disentangling the social interactions between strains and species is central to understanding microbes and how they respond to perturbations. However, the study of social evolution in microbes tends to focus on single species. Here, we broaden this perspective and review evolutionary and ecological theory relevant to microbial interactions across all phylogenetic scales. Despite increased complexity, we reduce the theory to a simple null model that we call the genotypic view. This states that cooperation will occur when cells are surrounded by identical genotypes at the loci that drive interactions, with genetic identity coming from recent clonal growth or horizontal gene transfer (HGT). In contrast, because cooperation is only expected to evolve between different genotypes under restrictive ecological conditions, different genotypes will typically compete. Competition between two genotypes includes mutual harm but, importantly, also many interactions that are beneficial to one of the two genotypes, such as predation. The literature offers support for the genotypic view with relatively few examples of cooperation between genotypes. However, the study of microbial interactions is still at an early stage. We outline the logic and methods that help to better evaluate our perspective and move us toward rationally engineering microbial communities to our own advantage.
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SIR Proteins and the Assembly of Silent Chromatin in Budding Yeast
Vol. 47 (2013), pp. 275–306More LessSaccharomyces cerevisiae provides a well-studied model system for heritable silent chromatin in which a histone-binding protein complex [the SIR (silent information regulator) complex] represses gene transcription in a sequence-independent manner by spreading along nucleosomes, much like heterochromatin in higher eukaryotes. Recent advances in the biochemistry and structural biology of the SIR-chromatin system bring us much closer to a molecular understanding of yeast silent chromatin. Simultaneously, genome-wide approaches have shed light on the biological importance of this form of epigenetic repression. Here, we integrate genetic, structural, and cell biological data into an updated overview of yeast silent chromatin assembly.
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New Gene Evolution: Little Did We Know
Vol. 47 (2013), pp. 307–333More LessGenes are perpetually added to and deleted from genomes during evolution. Thus, it is important to understand how new genes are formed and how they evolve to be critical components of the genetic systems that determine the biological diversity of life. Two decades of effort have shed light on the process of new gene origination and have contributed to an emerging comprehensive picture of how new genes are added to genomes, ranging from the mechanisms that generate new gene structures to the presence of new genes in different organisms to the rates and patterns of new gene origination and the roles of new genes in phenotypic evolution. We review each of these aspects of new gene evolution, summarizing the main evidence for the origination and importance of new genes in evolution. We highlight findings showing that new genes rapidly change existing genetic systems that govern various molecular, cellular, and phenotypic functions.
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RNA Editing in Plants and Its Evolution
Vol. 47 (2013), pp. 335–352More LessRNA editing alters the identity of nucleotides in RNA molecules such that the information for a protein in the mRNA differs from the prediction of the genomic DNA. In chloroplasts and mitochondria of flowering plants, RNA editing changes C nucleotides to U nucleotides; in ferns and mosses, it also changes U to C. The approximately 500 editing sites in mitochondria and 40 editing sites in plastids of flowering plants are individually addressed by specific proteins, genes for which are amplified in plant species with organellar RNA editing. These proteins contain repeat elements that bind to cognate RNA sequence motifs just 5′ to the edited nucleotide. In flowering plants, the site-specific proteins interact selectively with individual members of a different, smaller family of proteins. These latter proteins may be connectors between the site-specific proteins and the as yet unknown deaminating enzymatic activity.
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Expanding Horizons: Ciliary Proteins Reach Beyond Cilia
Shiaulou Yuan, and Zhaoxia SunVol. 47 (2013), pp. 353–376More LessOnce obscure, the cilium has come into the spotlight during the past decade. It is now clear that aside from generating locomotion by motile cilia, both motile and immotile cilia serve as signaling platforms for the cell. Through both motility and sensory functions, cilia play critical roles in development, homeostasis, and disease. To date, the cilium proteome contains more than 1,000 different proteins, and human genetics is identifying new ciliopathy genes at an increasing pace. Although assigning a function to immotile cilia was a challenge not so long ago, the myriad of signaling pathways, proteins, and biological processes associated with the cilium have now created a new obstacle: how to distill all these interactions into specific themes and mechanisms that may explain how the organelle serves to maintain organism homeostasis. Here, we review the basics of cilia biology, novel functions associated with cilia, and recent advances in cilia genetics, and on the basis of this framework, we further discuss the meaning and significance of ciliary connections.
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The Digestive Tract of Drosophila melanogaster
Vol. 47 (2013), pp. 377–404More LessThe digestive tract plays a central role in the digestion and absorption of nutrients. Far from being a passive tube, it provides the first line of defense against pathogens and maintains energy homeostasis by exchanging neuronal and endocrine signals with other organs. Historically neglected, the gut of the fruit fly Drosophila melanogaster has recently come to the forefront of Drosophila research. Areas as diverse as stem cell biology, neurobiology, metabolism, and immunity are benefitting from the ability to study the genetics of development, growth regulation, and physiology in the same organ. In this review, we summarize our knowledge of the Drosophila digestive tract, with an emphasis on the adult midgut and its functional underpinnings.
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RNase III: Genetics and Function; Structure and Mechanism*
Vol. 47 (2013), pp. 405–431More LessRNase III is a global regulator of gene expression in Escherichia coli that is instrumental in the maturation of ribosomal and other structural RNAs. We examine here how RNase III itself is regulated in response to growth and other environmental changes encountered by the cell and how, by binding or processing double-stranded RNA (dsRNA) intermediates, RNase III controls the expression of genes. Recent insight into the mechanism of dsRNA binding and processing, gained from structural studies of RNase III, is reviewed. Structural studies also reveal new cleavage sites in the enzyme that can generate longer 3′ overhangs.
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Modernizing the Nonhomologous End-Joining Repertoire: Alternative and Classical NHEJ Share the Stage
Vol. 47 (2013), pp. 433–455More LessDNA double-strand breaks (DSBs) are common lesions that continually threaten genomic integrity. Failure to repair a DSB has deleterious consequences, including cell death. Misrepair is also fraught with danger, especially inappropriate end-joining events, which commonly underlie oncogenic transformation and can scramble the genome. Canonically, cells employ two basic mechanisms to repair DSBs: homologous recombination (HR) and the classical nonhomologous end-joining pathway (cNHEJ). More recent experiments identified a highly error-prone NHEJ pathway, termed alternative NHEJ (aNHEJ), which operates in both cNHEJ-proficient and cNHEJ-deficient cells. aNHEJ is now recognized to catalyze many genome rearrangements, some leading to oncogenic transformation. Here, we review the mechanisms of cNHEJ and aNHEJ, their interconnections with the DNA damage response (DDR), and the mechanisms used to determine which of the three DSB repair pathways is used to heal a particular DSB. We briefly review recent clinical applications involving NHEJ and NHEJ inhibitors.
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Enterococcal Sex Pheromones: Signaling, Social Behavior, and Evolution
Vol. 47 (2013), pp. 457–482More LessIn Enterococcus faecalis, lateral transfer of conjugative plasmids that encode antibiotic resistance and virulence determinants can be induced by peptide sex pheromones. The tetracycline-resistance plasmid pCF10 represents a paradigm for illustrating important conserved features of a large family of pheromone-responsive enterococcal plasmids. The pheromone is released into the growth medium by plasmid-free recipient cells and sensed by plasmid-containing donors. The activity of the pheromone is antagonized by a plasmid-encoded inhibitor peptide that prevents conjugation in the absence of an inducing signal and is also required to return the system to the ground state following an induction cycle. The pheromone response involves multiple transcriptional and posttranscriptional mechanisms as well as bi-stable biological switch behavior. Multiple layers of regulation are essential for proper function, and evolution of this tight control system may have been favored by reduction of the fitness cost of plasmid maintenance to the host cell.
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Previous Volumes
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Volume 57 (2023)
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Volume 56 (2022)
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Volume 55 (2021)
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Volume 54 (2020)
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Volume 53 (2019)
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Volume 52 (2018)
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Volume 51 (2017)
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Volume 50 (2016)
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Volume 49 (2015)
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Volume 48 (2014)
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Volume 47 (2013)
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Volume 46 (2012)
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Volume 45 (2011)
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Volume 44 (2010)
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Volume 43 (2009)
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Volume 42 (2008)
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Volume 41 (2007)
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Volume 40 (2006)
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Volume 39 (2005)
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Volume 38 (2004)
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Volume 37 (2003)
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Volume 36 (2002)
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Volume 35 (2001)
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Volume 34 (2000)
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Volume 33 (1999)
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Volume 32 (1998)
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Volume 31 (1997)
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Volume 30 (1996)
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Volume 29 (1995)
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Volume 28 (1994)
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Volume 27 (1993)
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Volume 26 (1992)
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Volume 25 (1991)
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Volume 24 (1990)
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Volume 23 (1989)
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Volume 22 (1988)
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Volume 21 (1987)
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Volume 20 (1986)
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Volume 19 (1985)
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Volume 18 (1984)
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Volume 17 (1983)
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Volume 16 (1982)
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Volume 15 (1981)
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Volume 14 (1980)
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Volume 13 (1979)
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Volume 12 (1978)
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Volume 11 (1977)
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Volume 10 (1976)
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Volume 9 (1975)
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Volume 8 (1974)
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Volume 7 (1973)
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Volume 6 (1972)
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Volume 5 (1971)
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Volume 4 (1970)
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Volume 3 (1969)
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Volume 2 (1968)
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Volume 1 (1967)
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Volume 0 (1932)