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- Volume 56, 2022
Annual Review of Genetics - Volume 56, 2022
Volume 56, 2022
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A Half Century Defining the Logic of Cellular Life
Vol. 56 (2022), pp. 1–15More LessOver more than fifty years, I have studied how the logic that controls and integrates cell function is built into the dynamic architecture of living cells. I worked with a succession of exceptionally talented students and postdocs, and we discovered that the bacterial cell is controlled by an integrated genetic circuit in which transcriptional and translational controls are interwoven with the three-dimensional deployment of key regulatory and morphological proteins. Caulobacter's interconnected genetic regulatory network includes logic that regulates sets of genes expressed at specific times in the cell cycle and mechanisms that synchronize the advancement of the core cyclical circuit with chromosome replication and cytokinesis. Here, I have traced my journey from New York City art student to Stanford developmental biologist.
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The Genetics of Autophagy in Multicellular Organisms
Vol. 56 (2022), pp. 17–39More LessAutophagy, a lysosome-mediated degradation process evolutionarily conserved from yeast to mammals, is essential for maintaining cellular homeostasis and combating diverse cellular stresses. Autophagy involves de novo synthesis of a double-membrane autophagosome, sequestration of selected cellular contents, and subsequent delivery of sequestrated contents to the vacuole (in yeasts and plants) or to lysosomes (in animal cells) for degradation and recycling. Genetic studies in unicellular and multicellular model organisms have systematically revealed the molecular machinery, regulation, and function of autophagy in physiological settings. I review genetic studies in model organisms—from yeast to worm to fly—that enable us to not only identify autophagy genes, including ATG genes and the metazoan-specific EPG genes, but also uncover variants of autophagy in developmental contexts, novel regulatory mechanisms, and signaling events involved in mediating systemic autophagy response. Genetic analysis also helps us understand the liquid–liquid phase separation and transition that control autophagic degradation of protein aggregates. The emerging role of autophagy in zebrafish tissue regeneration is also discussed.
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The Awesome Power of Human Genetics of Infectious Disease
Vol. 56 (2022), pp. 41–62More LessSince the identification of sickle cell trait as a heritable form of resistance to malaria, candidate gene studies, linkage analysis paired with sequencing, and genome-wide association (GWA) studies have revealed many examples of genetic resistance and susceptibility to infectious diseases. GWA studies enabled the identification of many common variants associated with small shifts in susceptibility to infectious diseases. This is exemplified by multiple loci associated with leprosy, malaria, HIV, tuberculosis, and coronavirus disease 2019 (COVID-19), which illuminate genetic architecture and implicate pathways underlying pathophysiology. Despite these successes, most of the heritability of infectious diseases remains to be explained. As the field advances, current limitations may be overcome by applying methodological innovations such as cellular GWA studies and phenome-wide association (PheWA) studies as well as by improving methodological rigor with more precise case definitions, deeper phenotyping, increased cohort diversity, and functional validation of candidate loci in the laboratory or human challenge studies.
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The Epigenetic Control of the Transposable Element Life Cycle in Plant Genomes and Beyond
Vol. 56 (2022), pp. 63–87More LessWithin the life cycle of a living organism, another life cycle exists for the selfish genome inhabitants, which are called transposable elements (TEs). These mobile sequences invade, duplicate, amplify, and diversify within a genome, increasing the genome's size and generating new mutations. Cells act to defend their genome, but rather than permanently destroying TEs, they use chromatin-level repression and epigenetic inheritance to silence TE activity. This level of silencing is ephemeral and reversible, leading to a dynamic equilibrium between TE suppression and reactivation within a host genome. The coexistence of the TE and host genome can also lead to the domestication of the TE to serve in host genome evolution and function. In this review, we describe the life cycle of a TE, with emphasis on how epigenetic regulation is harnessed to control TEs for host genome stability and innovation.
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Gametogenesis: Exploring an Endogenous Rejuvenation Program to Understand Cellular Aging and Quality Control
Vol. 56 (2022), pp. 89–112More LessGametogenesis is a conserved developmental program whereby a diploid progenitor cell differentiates into haploid gametes, the precursors for sexually reproducing organisms. In addition to ploidy reduction and extensive organelle remodeling, gametogenesis naturally rejuvenates the ensuing gametes, leading to resetting of life span. Excitingly, ectopic expression of the gametogenesis-specific transcription factor Ndt80 is sufficient to extend life span in mitotically dividing budding yeast, suggesting that meiotic rejuvenation pathways can be repurposed outside of their natural context. In this review, we highlight recent studies of gametogenesis that provide emerging insight into natural quality control, organelle remodeling, and rejuvenation strategies that exist within a cell. These include selective inheritance, programmed degradation, and de novo synthesis, all of which are governed by the meiotic gene expression program entailing many forms of noncanonical gene regulation. Finally, we highlight critical questions that remain in the field and provide perspective on the implications of gametogenesis research on human health span.
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Asymmetric Histone Inheritance: Establishment, Recognition, and Execution
Vol. 56 (2022), pp. 113–143More LessThe discovery of biased histone inheritance in asymmetrically dividing Drosophila melanogaster male germline stem cells demonstrates one means to produce two distinct daughter cells with identical genetic material. This inspired further studies in different systems, which revealed that this phenomenon may be a widespread mechanism to introduce cellular diversity. While the extent of asymmetric histone inheritance could vary among systems, this phenomenon is proposed to occur in three steps: first, establishment of histone asymmetry between sister chromatids during DNA replication; second, recognition of sister chromatids carrying asymmetric histone information during mitosis; and third, execution of this asymmetry in the resulting daughter cells. By compiling the current knowledge from diverse eukaryotic systems, this review comprehensively details and compares known chromatin factors, mitotic machinery components, and cell cycle regulators that may contribute to each of these three steps. Also discussed are potential mechanisms that introduce and regulate variable histone inheritance modes and how these different modes may contribute to cell fate decisions in multicellular organisms.
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Genome Maintenance in Mammalian Stem Cells
Vol. 56 (2022), pp. 145–164More LessVarious stem cells in the body are tasked with maintaining tissue homeostasis throughout the life of an organism and thus must be resilient to intrinsic and extrinsic challenges such as infection and injury. Crucial to these challenges is genome maintenance because a high mutational load and persistent DNA lesions impact the production of essential gene products at proper levels and compromise optimal stem cell renewal and differentiation. Genome maintenance requires a robust and well-regulated DNA damage response suited to maintaining specific niches and tissues. In this review, we explore the similarities and differences between diverse stem cell types derived from (or preceding) all germ layers, including extraembryonic tissues. These cells utilize different strategies, including implementation of robust repair mechanisms, modulation of cell cycle checkpoints best suited to eliminating compromised cells, minimization of cell divisions, and differentiation in response to excessive damage.
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The Nuclear-to-Cytoplasmic Ratio: Coupling DNA Content to Cell Size, Cell Cycle, and Biosynthetic Capacity
Vol. 56 (2022), pp. 165–185More LessThough cell size varies between different cells and across species, the nuclear-to-cytoplasmic (N/C) ratio is largely maintained across species and within cell types. A cell maintains a relatively constant N/C ratio by coupling DNA content, nuclear size, and cell size. We explore how cells couple cell division and growth to DNA content. In some cases, cells use DNA as a molecular yardstick to control the availability of cell cycle regulators. In other cases, DNA sets a limit for biosynthetic capacity. Developmentally programmed variations in the N/C ratio for a given cell type suggest that a specific N/C ratio is required to respond to given physiological demands. Recent observations connecting decreased N/C ratios with cellular senescence indicate that maintaining the proper N/C ratio is essential for proper cellular functioning. Together, these findings suggest a causative, not simply correlative, role for the N/C ratio in regulating cell growth and cell cycle progression.
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Transcription-Translation Coupling in Bacteria
Vol. 56 (2022), pp. 187–205More LessIn bacteria, transcription and translation take place in the same cellular compartment. Therefore, a messenger RNA can be translated as it is being transcribed, a process known as transcription-translation coupling. This process was already recognized at the dawn of molecular biology, yet the interplay between the two key players, the RNA polymerase and ribosome, remains elusive. Genetic data indicate that an RNA sequence can be translated shortly after it has been transcribed. The closer both processes are in time, the less accessible the RNA sequence is between the RNA polymerase and ribosome. This temporal coupling has important consequences for gene regulation. Biochemical and structural studies have detailed several complexes between the RNA polymerase and ribosome. The in vivo relevance of this physical coupling has not been formally demonstrated. We discuss how both temporal and physical coupling may mesh to produce the phenomenon we know as transcription-translation coupling.
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Genome Protection by DNA Polymerase θ
Vol. 56 (2022), pp. 207–228More LessDNA polymerase θ (Pol θ) is a DNA repair enzyme widely conserved in animals and plants. Pol θ uses short DNA sequence homologies to initiate repair of double-strand breaks by theta-mediated end joining. The DNA polymerase domain of Pol θ is at the C terminus and is connected to an N-terminal DNA helicase–like domain by a central linker. Pol θ is crucial for maintenance of damaged genomes during development, protects DNA against extensive deletions, and limits loss of heterozygosity. The cost of using Pol θ for genome protection is that a few nucleotides are usually deleted or added at the repair site. Inactivation of Pol θ often enhances the sensitivity of cells to DNA strand–breaking chemicals and radiation. Since some homologous recombination–defective cancers depend on Pol θ for growth, inhibitors of Pol θ may be useful in treating such tumors.
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APOBEC-Induced Mutagenesis in Cancer
Vol. 56 (2022), pp. 229–252More LessThe initiation, progression, and relapse of cancers often result from mutations occurring within somatic cells. Consequently, processes that elevate mutation rates accelerate carcinogenesis and hinder the development of long-lasting therapeutics. Recent sequencing of human cancer genomes has identified patterns of mutations, termed mutation signatures, many of which correspond to specific environmentally induced and endogenous mutation processes. Some of the most frequently observed mutation signatures are caused by dysregulated activity of APOBECs, which deaminate cytidines in single-stranded DNA at specific sequence motifs causing C-to-T and C-to-G substitutions. In humans, APOBEC-generated genetic heterogeneity in tumor cells contributes to carcinogenesis, metastasis, and resistance to therapeutics. Here, we review the current understanding of APOBECs’ role in cancer mutagenesis and impact on disease and the biological processes that influence APOBEC mutagenic capacity.
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Quiescence in Saccharomyces cerevisiae
Vol. 56 (2022), pp. 253–278More LessMost cells live in environments that are permissive for proliferation only a small fraction of the time. Entering quiescence enables cells to survive long periods of nondivision and reenter the cell cycle when signaled to do so. Here, we describe what is known about the molecular basis for quiescence in Saccharomyces cerevisiae, with emphasis on the progress made in the last decade. Quiescence is triggered by depletion of an essential nutrient. It begins well before nutrient exhaustion, and there is extensive crosstalk between signaling pathways to ensure that all proliferation-specific activities are stopped when any one essential nutrient is limiting. Every aspect of gene expression is modified to redirect and conserve resources. Chromatin structure and composition change on a global scale, from histone modifications to three-dimensional chromatin structure. Thousands of proteins and RNAs aggregate, forming unique structures with unique fates, and the cytoplasm transitions to a glass-like state.
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The Four Causes: The Functional Architecture of Centromeres and Kinetochores
Vol. 56 (2022), pp. 279–314More LessKinetochores are molecular machines that power chromosome segregation during the mitotic and meiotic cell divisions of all eukaryotes. Aristotle explains how we think we have knowledge of a thing only when we have grasped its cause. In our case, to gain understanding of the kinetochore, the four causes correspond to questions that we must ask: (a) What are the constituent parts, (b) how does it assemble, (c) what is the structure and arrangement, and (d) what is the function? Here we outline the current blueprint for the assembly of a kinetochore, how functions are mapped onto this architecture, and how this is shaped by the underlying pericentromeric chromatin. The view of the kinetochore that we present is possible because an almost complete parts list of the kinetochore is now available alongside recent advances using in vitro reconstitution, structural biology, and genomics. In many organisms, each kinetochore binds to multiple microtubules, and we propose a model for how this ensemble-level architecture is organized, drawing on key insights from the simple one microtubule–one kinetochore setup in budding yeast and innovations that enable meiotic chromosome segregation.
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The 3D-Evo Space: Evolution of Gene Expression and Alternative Splicing Regulation
Vol. 56 (2022), pp. 315–337More LessAnimal species present relatively high levels of gene conservation, and yet they display a great variety of cell type and tissue phenotypes. These diverse phenotypes are mainly specified through differential gene usage, which relies on several mechanisms. Two of the most relevant mechanisms are regulated gene transcription, usually referred to as gene expression (rGE), and regulated alternative splicing (rAS). Several works have addressed how either rGE or rAS contributes to phenotypic diversity throughout evolution, but a back-to-back comparison between the two molecular mechanisms, specifically highlighting both their common regulatory principles and unique properties, is still missing. In this review, we propose an innovative framework for the unified comparison between rGE and rAS from different perspectives: the three-dimensional (3D)-evo space. We use the 3D-evo space to comprehensively (a) review the molecular basis of rGE and rAS (i.e., the molecular axis), (b) depict the tissue-specific phenotypes they contribute to (i.e., the tissue axis), and (c) describe the determinants that drive the evolution of rGE and rAS programs (i.e., the evolution axis). Finally, we unify the perspectives emerging from the three axes by discussing general trends and specific examples of rGE and rAS tissue program evolution.
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Decoding the Spermatogenesis Program: New Insights from Transcriptomic Analyses
Vol. 56 (2022), pp. 339–368More LessSpermatogenesis is a complex differentiation process coordinated spatiotemporally across and along seminiferous tubules. Cellular heterogeneity has made it challenging to obtain stage-specific molecular profiles of germ and somatic cells using bulk transcriptomic analyses. This has limited our ability to understand regulation of spermatogenesis and to integrate knowledge from model organisms to humans. The recent advancement of single-cell RNA-sequencing (scRNA-seq) technologies provides insights into the cell type diversity and molecular signatures in the testis. Fine-grained cell atlases of the testis contain both known and novel cell types and define the functional states along the germ cell developmental trajectory in many species. These atlases provide a reference system for integrated interspecies comparisons to discover mechanistic parallels and to enable future studies. Despite recent advances, we currently lack high-resolution data to probe germ cell–somatic cell interactions in the tissue environment, but the use of highly multiplexed spatial analysis technologies has begun to resolve this problem. Taken together, recent single-cell studies provide an improvedunderstanding of gametogenesis to examine underlying causes of infertility and enable the development of new therapeutic interventions.
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Errors of the Egg: The Establishment and Progression of Human Aneuploidy Research in the Maternal Germline
Vol. 56 (2022), pp. 369–390More LessMeiosis, a key process in the creation of haploid gametes, is a complex cellular division incorporating unique timing and intricate chromosome dynamics. Abnormalities in this elaborate dance can lead to the production of aneuploid gametes, i.e., eggs containing an incorrect number of chromosomes, many of which cannot generate a viable pregnancy. For many decades, research has been attempting to address why this process is notoriously error prone in humans compared to many other organisms. Rapidly developing technologies, access to new clinical material, and a mounting public infertility crisis have kept the field both active and quickly evolving. In this review, we discuss the history of aneuploidy in humans with a focus on its origins in maternal meiosis. We also gather current working mechanistic hypotheses, as well as up-and-coming areas of interest that point to future scientific avenues and their potential clinical applications.
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Mechanisms Underlying Circuit Dysfunction in Neurodevelopmental Disorders
Vol. 56 (2022), pp. 391–422More LessRecent advances in genomics have revealed a wide spectrum of genetic variants associated with neurodevelopmental disorders at an unprecedented scale. An increasing number of studies have consistently identified mutations—both inherited and de novo—impacting the function of specific brain circuits. This suggests that, during brain development, alterations in distinct neural circuits, cell types, or broad regulatory pathways ultimately shaping synapses might be a dysfunctional process underlying these disorders. Here, we review findings from human studies and animal model research to provide a comprehensive description of synaptic and circuit mechanisms implicated in neurodevelopmental disorders. We discuss how specific synaptic connections might be commonly disrupted in different disorders and the alterations in cognition and behaviors emerging from imbalances in neuronal circuits. Moreover, we review new approaches that have been shown to restore or mitigate dysfunctional processes during specific critical windows of brain development. Considering the heterogeneity of neurodevelopmental disorders, we also highlight the recent progress in developing improved clinical biomarkers and strategies that will help to identify novel therapeutic compounds and opportunities for early intervention.
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Enhancer Function and Evolutionary Roles of Human Accelerated Regions
Vol. 56 (2022), pp. 423–439More LessHuman accelerated regions (HARs) are the fastest-evolving sequences in the human genome. When HARs were discovered in 2006, their function was mysterious due to scant annotation of the noncoding genome. Diverse technologies, from transgenic animals to machine learning, have consistently shown that HARs function as gene regulatory enhancers with significant enrichment in neurodevelopment. It is now possible to quantitatively measure the enhancer activity of thousands of HARs in parallel and model how each nucleotide contributes to gene expression. These strategies have revealed that many human HAR sequences function differently than their chimpanzee orthologs, though individual nucleotide changes in the same HAR may have opposite effects, consistent with compensatory substitutions. To fully evaluate the role of HARs in human evolution, it will be necessary to experimentally and computationally dissect them across more cell types and developmental stages.
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Scalable Functional Assays for the Interpretation of Human Genetic Variation
Vol. 56 (2022), pp. 441–465More LessScalable sequence–function studies have enabled the systematic analysis and cataloging of hundreds of thousands of coding and noncoding genetic variants in the human genome. This has improved clinical variant interpretation and provided insights into the molecular, biophysical, and cellular effects of genetic variants at an astonishing scale and resolution across the spectrum of allele frequencies. In this review, we explore current applications and prospects for the field and outline the principles underlying scalable functional assay design, with a focus on the study of single-nucleotide coding and noncoding variants.
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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)