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- Volume 74, 2012
Annual Review of Physiology - Volume 74, 2012
Volume 74, 2012
- Preface
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A Conversation with Elwood Jensen
Vol. 74 (2012), pp. 1–11More LessVIDEOPlease visit http://www.youtube.com/watch?v=OT7HoDpJopA for a video of this interview.
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Epigenetic Control of Smooth Muscle Cell Differentiation and Phenotypic Switching in Vascular Development and Disease
Vol. 74 (2012), pp. 13–40More LessThe vascular smooth muscle cell (SMC) in adult animals is a highly specialized cell whose principal function is contraction. However, this cell displays remarkable plasticity and can undergo profound changes in phenotype during repair of vascular injury, during remodeling in response to altered blood flow, or in various disease states. There has been extensive progress in recent years in our understanding of the complex mechanisms that control SMC differentiation and phenotypic plasticity, including the demonstration that epigenetic mechanisms play a critical role. In addition, recent evidence indicates that SMC phenotypic switching in adult animals involves the reactivation of embryonic stem cell pluripotency genes and that mesenchymal stem cells may be derived from SMC and/or pericytes. This review summarizes the current state of our knowledge in this field and identifies some of the key unresolved challenges and questions that we feel require further study.
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Epigenetics and Cardiovascular Development
Vol. 74 (2012), pp. 41–68More LessThe cardiovascular system is broadly composed of the heart, which pumps blood, and the blood vessels, which carry blood to and from tissues of the body. Heart malformations are the most serious common birth defect, affecting at least 2% of newborns and leading to significant morbidity and mortality. Severe heart malformations cause heart failure in fetuses, infants, and children, whereas milder heart defects may not trigger significant heart dysfunction until early or midadulthood. Severe vasculogenesis or angiogenesis defects in embryos are incompatible with life, and anomalous arterial patterning may cause vascular aberrancies that often require surgical treatment. It is therefore important to understand the underlying mechanisms that control cardiovascular development. Understanding developmental mechanisms will also help us design better strategies to regenerate cardiovascular tissues for therapeutic purposes. An important mechanism regulating genes involves the modification of chromatin, the higher-order structure in which DNA is packaged. Recent studies have greatly expanded our understanding of the regulation of cardiovascular development at the chromatin level, including the remodeling of chromatin and the modification of histones. Chromatin-level regulation integrates multiple inputs and coordinates broad gene expression programs. Thus, understanding chromatin-level regulation will allow for a better appreciation of gene regulation as a whole and may set a fundamental basis for cardiovascular disease. This review focuses on how chromatin-remodeling and histone-modifying factors regulate gene expression to control cardiovascular development.
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Lysosomal Acidification Mechanisms*
Vol. 74 (2012), pp. 69–86More LessLysosomes, the terminal organelles on the endocytic pathway, digest macromolecules and make their components available to the cell as nutrients. Hydrolytic enzymes specific to a wide range of targets reside within the lysosome; these enzymes are activated by the highly acidic pH (between 4.5 and 5.0) in the organelles' interior. Lysosomes generate and maintain their pH gradients by using the activity of a proton-pumping V-type ATPase, which uses metabolic energy in the form of ATP to pump protons into the lysosome lumen. Because this activity separates electric charge and generates a transmembrane voltage, another ion must move to dissipate this voltage for net pumping to occur. This so-called counterion may be either a cation (moving out of the lysosome) or an anion (moving into the lysosome). Recent data support the involvement of ClC-7, a Cl−/H+ antiporter, in this process, although many open questions remain as to this transporter's involvement. Although functional results also point to a cation transporter, its molecular identity remains uncertain. Both the V-ATPase and the counterion transporter are likely to be important players in the mechanisms determining the steady-state pH of the lysosome interior. Exciting new results suggest that lysosomal pH may be dynamically regulated in some cell types.
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Biology Without Walls: The Novel Endocrinology of Bone
Vol. 74 (2012), pp. 87–105More LessClassical studies of vertebrate physiology have usually been confined to a given organ or cell type. The use of mouse genetics has changed this approach and has rejuvenated the concept of a whole-body study of physiology. One physiological system that has been profoundly influenced by mouse genetics is skeletal physiology. Indeed, genetic approaches have identified several unexpected organs that affect bone physiology. These new links have begun to provide a plausible explanation for the evolutionary involvement of hormones such as leptin with bone physiology. These genetic approaches have also revealed bone as a true endocrine organ capable of regulating energy metabolism and reproduction. Collectively, the body of work discussed below illustrates a new and unconventional role for bone in mammalian physiology.
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Fetal Programming and Metabolic Syndrome
Paolo Rinaudo, and Erica WangVol. 74 (2012), pp. 107–130More LessMetabolic syndrome is reaching epidemic proportions, particularly in developing countries. In this review, we explore the concept—based on the developmental-origin-of-health-and-disease hypothesis—that reprogramming during critical times of fetal life can lead to metabolic syndrome in adulthood. Specifically, we summarize the epidemiological evidence linking prenatal stress, manifested by low birth weight, to metabolic syndrome and its individual components. We also review animal studies that suggest potential mechanisms for the long-term effects of fetal reprogramming, including the cellular response to stress and both organ- and hormone-specific alterations induced by stress. Although metabolic syndrome in adulthood is undoubtedly caused by multiple factors, including modifiable behavior, fetal life may provide a critical window in which individuals are predisposed to metabolic syndrome later in life.
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Nuclear Sphingolipid Metabolism
Vol. 74 (2012), pp. 131–151More LessNuclear lipid metabolism is implicated in various processes, including transcription, splicing, and DNA repair. Sphingolipids play roles in numerous cellular functions, and an emerging body of literature has identified roles for these lipid mediators in distinct nuclear processes. Different sphingolipid species are localized in various subnuclear domains, including chromatin, the nuclear matrix, and the nuclear envelope, where sphingolipids exert specific regulatory and structural functions. Sphingomyelin, the most abundant nuclear sphingolipid, plays both structural and regulatory roles in chromatin assembly and dynamics in addition to being an integral component of the nuclear matrix. Sphingosine-1-phosphate modulates histone acetylation, sphingosine is a ligand for steroidogenic factor 1, and nuclear accumulation of ceramide has been implicated in apoptosis. Finally, nuclear membrane–associated ganglioside GM1 plays a pivotal role in Ca2+ homeostasis. This review highlights research on the factors that control nuclear sphingolipid metabolism and summarizes the roles of these lipids in various nuclear processes.
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Adenosine and Hypoxia-Inducible Factor Signaling in Intestinal Injury and Recovery
Vol. 74 (2012), pp. 153–175More LessThe gastrointestinal mucosa has proven to be an interesting tissue in which to investigate disease-related metabolism. In this review, we outline some of the evidence that implicates hypoxia-mediated adenosine signaling as an important signature within both healthy and diseased mucosa. Studies derived from cultured cell systems, animal models, and human patients have revealed that hypoxia is a significant component of the inflammatory microenvironment. These studies have revealed a prominent role for hypoxia-induced factor (HIF) and hypoxia signaling at several steps along the adenine nucleotide metabolism and adenosine receptor signaling pathways. Likewise, studies to date in animal models of intestinal inflammation have demonstrated an almost uniformly beneficial influence of HIF stabilization on disease outcomes. Ongoing studies to define potential similarities with and differences between innate and adaptive immune responses will continue to teach us important lessons about the complexity of the gastrointestinal tract. Such information has provided new insights into disease pathogenesis and, importantly, will provide insights into new therapeutic targets.
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Toll-Like Receptor–Gut Microbiota Interactions: Perturb at Your Own Risk!
Vol. 74 (2012), pp. 177–198More LessThe well-being of the intestine and its host requires that this organ execute its complex function amid colonization by a large and diverse microbial community referred to as the gut microbiota. A myriad of interacting mechanisms of mucosal immunity permit the gut to corral the microbiota in such a way as to maximize the benefits and to minimize the danger of living in close proximity to this large microbial biomass. Toll-like receptors and Nod-like receptors, collectively referred to as pattern recognition receptors (PRRs), recognize a variety of microbial components and, hence, play a central role in governing the interface between host and microbiota. This review examines mechanisms by which PRR-microbiota interactions are regulated so as to allow activation of host defense when necessary while preventing excessive inflammation, which can have a myriad of negative consequences for the host. Analysis of published studies performed in human subjects and a variety of murine disease models reveals the central theme that PRRs play a key role in maintaining a healthful stable relationship between the intestine and its microbiota. In contrast, although select genetic ablations of PRR signaling may protect against some chronic diseases, the overriding theme of studies performed to date is that perturbations of PRR-microbiota interactions are more likely to promote disease states associated with inflammation.
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The Calyx of Held Synapse: From Model Synapse to Auditory Relay
Vol. 74 (2012), pp. 199–224More LessThe calyx of Held is an axosomatic terminal in the auditory brainstem that has attracted anatomists because of its giant size and physiologists because of its accessibility to patch-clamp recordings. The calyx allows the principal neurons in the medial nucleus of the trapezoid body (MNTB) to provide inhibition that is both well timed and sustained to many other auditory nuclei. The special adaptations that allow the calyx to drive its principal neuron even when frequencies are high include a large number of release sites with low release probability, a large readily releasable pool, fast presynaptic calcium clearance and little delayed release, a large quantal size, and fast AMPA-type glutamate receptors. The transformation from a synapse that is unremarkable except for its giant size into a fast and reliable auditory relay happens in just a few days. In rodents this transformation is essentially ready when hearing starts.
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Neurotransmitter Corelease: Mechanism and Physiological Role
Vol. 74 (2012), pp. 225–243More LessNeurotransmitter identity is a defining feature of all neurons because it constrains the type of information they convey, but many neurons release multiple transmitters. Although the physiological role for corelease has remained poorly understood, the vesicular uptake of one transmitter can regulate filling with the other by influencing expression of the H+ electrochemical driving force. In addition, the sorting of vesicular neurotransmitter transporters and other synaptic vesicle proteins into different vesicle pools suggests the potential for distinct modes of release. Corelease thus serves multiple roles in synaptic transmission.
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Small-Conductance Ca2+-Activated K+ Channels: Form and Function
Vol. 74 (2012), pp. 245–269More LessSmall-conductance Ca2+-activated K+ channels (SK channels) are widely expressed throughout the central nervous system. These channels are activated solely by increases in intracellular Ca2+. SK channels are stable macromolecular complexes of the ion pore–forming subunits with calmodulin, which serves as the intrinsic Ca2+ gating subunit, as well as with protein kinase CK2 and protein phosphatase 2A, which modulate Ca2+ sensitivity. Well-known for their roles in regulating somatic excitability in central neurons, SK channels are also expressed in the postsynaptic membrane of glutamatergic synapses, where their activation and regulated trafficking modulate synaptic transmission and the induction and expression of synaptic plasticity, thereby affecting learning and memory. In this review we discuss the molecular and functional properties of SK channels and their physiological roles in central neurons.
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The Calcium-Sensing Receptor Beyond Extracellular Calcium Homeostasis: Conception, Development, Adult Physiology, and Disease
Vol. 74 (2012), pp. 271–297More LessThe extracellular calcium-sensing receptor (CaSR) is the first identified G protein–coupled receptor to be activated by an ion, extracellular calcium (Ca2+). Since the identification of the CaSR in 1993, genetic mutations in the CaSR gene, and murine models in which CaSR expression has been manipulated, have clearly demonstrated the importance of this receptor in the maintenance of stable, free, ionized Ca2+ concentration in the extracellular fluids. These functions have been extensively reviewed elsewhere. However, the distribution pattern and expression of the CaSR in lower vertebrates strongly suggest that the CaSR must play a role that is independent of mineral cation metabolism. This review addresses the involvement of the CaSR in nutrient sensing; its putative and demonstrated functions during conception, embryonic development, and birth; and its contributions to adult physiology and disease, with reference to CaSR-based therapeutics. Recent ongoing developments concerning the role of the CaSR in stem cell differentiation are also reviewed.
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Cell Biology and Pathology of Podocytes
Anna Greka, and Peter MundelVol. 74 (2012), pp. 299–323More LessAs an integral member of the filtration barrier in the kidney glomerulus, the podocyte is in a unique geographical position: It is exposed to chemical signals from the urinary space (Bowman's capsule), it receives and transmits chemical and mechanical signals to/from the glomerular basement membrane upon which it elaborates, and it receives chemical and mechanical signals from the vascular space with which it also communicates. As with every cell, the ability of the podocyte to receive signals from the surrounding environment and to translate them to the intracellular milieu is dependent largely on molecules residing on the cell membrane. These molecules are the first-line soldiers in the ongoing battle to sense the environment, to respond to friendly signals, and to defend against injurious foes. In this review, we take a membrane biologist's view of the podocyte, examining the many membrane receptors, channels, and other signaling molecules that have been implicated in podocyte biology. Although we attempt to be comprehensive, our goal is not to capture every membrane-mediated pathway but rather to emphasize that this approach may be fruitful in understanding the podocyte and its unique properties.
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A New Look at Electrolyte Transport in the Distal Tubule
Vol. 74 (2012), pp. 325–349More LessThe distal nephron plays a critical role in the renal control of homeostasis. Until very recently most studies focused on the control of Na+, K+, and water balance by principal cells of the collecting duct and the regulation of solute and water by hormones from the renin-angiotensin-aldosterone system and by antidiuretic hormone. However, recent studies have revealed the unexpected importance of renal intercalated cells, a subtype of cells present in the connecting tubule and collecting ducts. Such cells were thought initially to be involved exclusively in acid-base regulation. However, it is clear now that intercalated cells absorb NaCl and K+ and hence may participate in the regulation of blood pressure and potassium balance. The second paradigm-challenging concept we highlight is the emerging importance of local paracrine factors that play a critical role in the renal control of water and electrolyte balance.
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Renal Function in Diabetic Disease Models: The Tubular System in the Pathophysiology of the Diabetic Kidney
Vol. 74 (2012), pp. 351–375More LessDiabetes mellitus affects the kidney in stages. At the onset of diabetes mellitus, in a subset of diabetic patients the kidneys grow large, and glomerular filtration rate (GFR) becomes supranormal, which are risk factors for developing diabetic nephropathy later in life. This review outlines a pathophysiological concept that focuses on the tubular system to explain these changes. The concept includes the tubular hypothesis of glomerular filtration, which states that early tubular growth and sodium-glucose cotransport enhance proximal tubule reabsorption and make the GFR supranormal through the physiology of tubuloglomerular feedback. The diabetic milieu triggers early tubular cell proliferation, but the induction of TGF-β and cyclin-dependent kinase inhibitors causes a cell cycle arrest and a switch to tubular hypertrophy and a senescence-like phenotype. Although this growth phenotype explains unusual responses like the salt paradox of the early diabetic kidney, the activated molecular pathways may set the stage for tubulointerstitial injury and diabetic nephropathy.
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Autophagy in Pulmonary Diseases
Vol. 74 (2012), pp. 377–401More Less(Macro)autophagy provides a membrane-dependent mechanism for the sequestration, transport, and lysosomal turnover of subcellular components, including proteins and organelles. In this capacity, autophagy maintains basal cellular homeostasis and healthy organelle populations such as mitochondria. During starvation, autophagy prolongs cell survival by recycling metabolic precursors from intracellular macromolecules. Furthermore, autophagy represents an inducible response to chemical and physical cellular stress. Increasing evidence suggests that autophagy, and its regulatory proteins, may critically influence vital cellular processes such as programmed cell death, cell proliferation, inflammation, and innate immune functions and thereby may play a critical role in the pathogenesis of human disease. The function of autophagy in disease pathogenesis remains unclear and may involve either impaired or accelerated autophagic activity or imbalances in the activation of autophagic proteins. This review examines the roles of autophagy in the pathogenesis of pulmonary diseases, with emphasis on pulmonary vascular disease and acute and chronic lung diseases.
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Stop the Flow: A Paradigm for Cell Signaling Mediated by Reactive Oxygen Species in the Pulmonary Endothelium
Vol. 74 (2012), pp. 403–424More LessThe lung endothelium is exposed to mechanical stimuli through shear stress arising from blood flow and responds to altered shear by activation of NADPH (NOX2) to generate reactive oxygen species (ROS). This review describes the pathway for NOX2 activation and the downstream ROS-mediated signaling events on the basis of studies of isolated lungs and flow-adapted endothelial cells in vitro that are subjected to acute flow cessation (ischemia). Altered mechanical stress is detected by a cell-associated complex involving caveolae and other membrane proteins that results in endothelial cell membrane depolarization and then the activation of specific kinases that lead to the assembly of NOX2 components. ROS generated by this enzyme amplify the mechanosignal within the endothelial cell to regulate activation and/or synthesis of proteins that participate in cell growth, proliferation, differentiation, apoptosis, and vascular remodeling. These responses indicate an important role for NOX2-derived ROS associated with mechanotransduction in promoting vascular homeostasis.
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The Molecular Control of Meiotic Chromosomal Behavior: Events in Early Meiotic Prophase in Drosophila Oocytes
Vol. 74 (2012), pp. 425–451More LessWe review the critical events in early meiotic prophase in Drosophila melanogaster oocytes. We focus on four aspects of this process: the formation of the synaptonemal complex (SC) and its role in maintaining homologous chromosome pairings, the critical roles of the meiosis-specific process of centromere clustering in the formation of a full-length SC, the mechanisms by which preprogrammed double-strand breaks initiate meiotic recombination, and the checkpoints that govern the progression and coordination of these processes. Central to this discussion are the roles that somatic pairing events play in establishing the necessary conditions for proper SC formation, the roles of centromere pairing in synapsis initiation, and the mechanisms by which oocytes detect failures in SC formation and/or recombination. Finally, we correlate what is known in Drosophila oocytes with our understanding of these processes in other systems.
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Previous Volumes
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Volume 87 (2025)
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Volume 86 (2024)
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Volume 85 (2023)
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Volume 84 (2022)
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Volume 83 (2021)
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Volume 82 (2020)
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Volume 81 (2019)
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Volume 80 (2018)
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Volume 79 (2017)
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Volume 78 (2016)
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Volume 77 (2015)
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Volume 76 (2014)
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Volume 75 (2013)
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Volume 74 (2012)
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Volume 73 (2011)
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Volume 72 (2010)
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Volume 71 (2009)
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Volume 70 (2008)
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Volume 69 (2007)
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Volume 68 (2006)
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Volume 67 (2005)
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Volume 66 (2004)
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Volume 65 (2003)
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Volume 64 (2002)
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Volume 63 (2001)
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Volume 62 (2000)
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Volume 61 (1999)
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Volume 60 (1998)
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Volume 59 (1997)
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Volume 58 (1996)
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Volume 57 (1995)
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Volume 56 (1994)
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Volume 55 (1993)
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Volume 54 (1992)
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Volume 53 (1991)
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Volume 52 (1990)
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Volume 51 (1989)
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Volume 50 (1988)
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Volume 49 (1987)
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Volume 48 (1986)
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Volume 47 (1985)
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Volume 46 (1984)
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Volume 45 (1983)
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Volume 44 (1982)
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Volume 43 (1981)
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Volume 42 (1980)
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Volume 41 (1979)
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Volume 40 (1978)
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Volume 39 (1977)
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Volume 38 (1976)
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Volume 37 (1975)
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Volume 36 (1974)
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Volume 35 (1973)
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Volume 34 (1972)
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Volume 33 (1971)
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Volume 32 (1970)
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Volume 31 (1969)
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Volume 30 (1968)
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Volume 29 (1967)
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Volume 28 (1966)
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Volume 27 (1965)
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Volume 26 (1964)
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Volume 25 (1963)
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Volume 24 (1962)
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Volume 23 (1961)
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Volume 22 (1960)
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Volume 21 (1959)
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Volume 20 (1958)
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Volume 19 (1957)
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Volume 18 (1956)
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Volume 17 (1955)
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Volume 16 (1954)
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Volume 15 (1953)
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Volume 14 (1952)
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Volume 13 (1951)
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Volume 12 (1950)
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Volume 11 (1949)
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Volume 10 (1948)
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Volume 9 (1947)
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Volume 8 (1946)
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Volume 7 (1945)
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Volume 6 (1944)
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Volume 5 (1943)
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Volume 4 (1942)
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Volume 3 (1941)
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Volume 2 (1940)
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Volume 1 (1939)
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Volume 0 (1932)