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- Volume 60, 1998
Annual Review of Physiology - Volume 60, 1998
Volume 60, 1998
- Preface
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- Review Articles
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THE PHYSIOLOGICAL BASIS OF DIVING TO DEPTH: Birds and Mammals
Vol. 60 (1998), pp. 19–32More Less▪ AbstractThere is wide diversity in the animals that dive to depth and in the distribution of their body oxygen stores. A hallmark of animals diving to depth is a substantial elevation of muscle myoglobin concentration. In deep divers, more than 80% of the oxygen store is in the blood and muscles. How these oxygen stores are managed, particularly within muscle, is unclear. The aerobic endurance of four species has now been measured. These measurements provide a standard for other species in which the limits cannot be measured. Diving to depth requires several adaptations to the effects of pressure. In mammals, one adaptation is lung collapse at shallow depths, which limits absorption of nitrogen. Blood N2 levels remain below the threshold for decompression sickness. No such adaptive model is known for birds. There appear to be two diving strategies used by animals that dive to depth. Seals, for example, seldom rely on anaerobic metabolism. Birds, on the other hand, frequently rely on anaerobic metabolism to exploit prey-rich depths otherwise unavailable to them.
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ANIMAL ADAPTATIONS FOR TOLERANCE AND EXPLOITATION OF POISONOUS SULFIDE
Vol. 60 (1998), pp. 33–53More Less▪ AbstractMany aquatic animal species can survive sulfide exposure to some extent through oxidation of the sulfide, which results mainly in thiosulfate. In several species, sulfide oxidation is localized in the mitochondria and is accompanied by ATP synthesis. In addition, blood-based and intracellular compounds can augment sulfide oxidation. The formation of thiosulfate requires oxygen, which results in an increase in oxygen consumption of some species. If not all sulfide is detoxified, cytochrome c oxidase is inhibited. Under these conditions, a sulfide-dependent anaerobic energy metabolism commences.
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BIOLOGICAL ICE NUCLEATION AND ICE DISTRIBUTION IN COLD-HARDY ECTOTHERMIC ANIMALS
Vol. 60 (1998), pp. 55–72More Less▪ AbstractFor many ectotherms, overwintering survival depends on the avoidance or regulation of ice nucleation and growth within their body fluids. Freeze avoidance via supercooling plays an important role in the cold hardiness of many small species, particularly terrestrial arthropods, that do not survive the freezing of their body fluids. In contrast, mechanisms that limit supercooling and initiate freezing at relatively high temperatures promote survival of the few invertebrates and vertebrates that tolerate freezing. These mechanisms include inoculative freezing, which results from contact with ice in the environment, and various ice nucleating proteins, microbes, and crystalloid compounds. In freeze-tolerant ectotherms, cold hardiness is influenced by complex, seasonally changing interactions among physiological factors, ice nucleators, and the physical microenvironment. Extraorgan sequestration of ice is a major adaptation of freeze tolerance. For most freeze-tolerant species, ice growth is primarily restricted to extracellular compartments; however, intracellular freezing also occurs in some species.
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THE ROLE OF VITRIFICATION IN ANHYDROBIOSIS
Vol. 60 (1998), pp. 73–103More Less▪ AbstractNumerous organisms are capable of surviving more or less complete dehydration. A common feature in their biochemistry is that they accumulate large amounts of disaccharides, the most common of which are sucrose and trehalose. Over the past 20 years, we have provided evidence that these sugars stabilize membranes and proteins in the dry state, most likely by hydrogen bonding to polar residues in the dry macromolecular assemblages. This direct interaction results in maintenance of dry proteins and membranes in a physical state similar to that seen in the presence of excess water. An alternative viewpoint has been proposed, based on the fact that both sucrose and trehalose form glasses in the dry state. It has been suggested that glass formation (vitrification) is in itself sufficient to stabilize dry biomaterials. In this review we present evidence that, although vitrification is indeed required, it is not in itself sufficient. Instead, both direct interaction and vitrification are required. Special properties have often been claimed for trehalose in this regard. In fact, trehalose has been shown by many workers to be remarkably (and sometimes uniquely) effective in stabilizing dry or frozen biomolecules, cells, and tissues. Others have not observed any such special properties. We review evidence here showing that trehalose has a remarkably high glass-transition temperature (Tg). It is not anomalous in this regard because it lies at the end of a continuum of sugars with increasing Tg. However, it is unusual in that addition of small amounts of water does not depress Tg, as in other sugars. Instead, a dihydrate crystal of trehalose forms, thereby shielding the remaining glassy trehalose from effects of the added water. Thus under less than ideal conditions such as high humidity and temperature, trehalose does indeed have special properties, which may explain the stability and longevity of anhydrobiotes that contain it. Further, it makes this sugar useful in stabilization of biomolecules of use in human welfare.
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ROUTES AND MECHANISM OF FLUID TRANSPORT BY EPITHELIA1
Vol. 60 (1998), pp. 105–119More Less▪ AbstractThe mechanism of fluid transport by leaky epithelia and the route taken by the transported fluid are in dispute. A consideration of current mathematical models for coupling of solutes and water, as well as the methodologies for the study of fluid transport, shows that local osmosis best accounts for water movement. Although it seems virtually certain that the tight junctions are water permeable, the fraction of absorbed fluid that crosses the tight junction cannot yet be determined with confidence.
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MOLECULAR ARCHITECTURE OF TIGHT JUNCTIONS
Vol. 60 (1998), pp. 121–142More Less▪ AbstractThe tight junction creates a regulated barrier in the paracellular pathway and, together with the actin-rich adherens junction, forms a functional unit called the apical junction complex. A growing number of tight junction–associated proteins have been identified, but functions are defined for only a few. The intercellular barrier is formed by rows of the transmembrane protein occludin, which is bound on the cytoplasmic surface to ZO-1 and ZO-2. These proteins are members of the membrane-associated guanylate kinase (MAGUK) protein family and are likely to have both structural and signaling roles. Junctional plaque proteins without known functions include cingulin, p130, and 7H6; single reports describe ZA-1TJ and symplekin. Many cellular signaling pathways affect assembly and sealing of junctions. Transducing proteins, which localize within the junction, include both heterotrimeric and rho-related GTP-binding proteins, PKC-ζ and nonreceptor tyrosine kinases. Control of perijunctional actin may be the unifying mechanism for regulating paracellular permeability.
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REGULATION OF THE MOVEMENT OF SOLUTES ACROSS TIGHT JUNCTIONS
Vol. 60 (1998), pp. 143–159More Less▪ AbstractThe intercellular tight junction is the rate-limiting barrier in the paracellular pathway for permeation by ions and larger solutes. A variety of widely used electrical and flux approaches are used in the analyses of solute permeation through this pathway; however, each has limitations in practice. It is now clear that solute permeation across tight junctions is dynamically regulated by intracellular events with a common effector mechanism apparently tied to the cytoskeleton. These pathways, which regulate tight junction solute permeability, are targets that produce epithelial barrier dysfunction in a variety of disease states. However, regulation of solute permeation across the junctional barrier may also represent a potential means to improve bioavailability of orally administered bioactive solutes.
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ROLE OF TIGHT JUNCTIONS IN ESTABLISHING AND MAINTAINING CELL POLARITY
Vol. 60 (1998), pp. 161–177More Less▪ AbstractThe tight junction (TJ) is not randomly located on the cell membrane, but occupies a precise position at the outermost edge of the intercellular space and, therefore, is itself considered a polarized structure. This article reviews the most common experimental approaches for studying this relationship. We then discuss three main topics. (a) The mechanisms of polarization that operate regardless of the presence of TJs: We explore a variety of polarization mechanisms that operate at stages of the cell cycle in which TJs may be already established. (b) TJs and polarity as partners in highly dynamic processes: Polarity and TJs are steady state situations that may be drastically changed by a variety of signaling events. (c) Polarized distribution of membrane molecules that depend on TJs: This refers to molecules (mainly lipids) whose polarized distribution, although not the direct result of TJs, depends on these structures to maintain such distribution.
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CODEPENDENCE OF RENAL CALCIUM AND SODIUM TRANSPORT
Vol. 60 (1998), pp. 179–197More Less▪ AbstractCalcium and sodium absorption by the kidney normally proceed in parallel. However, a number of physiological, pharmacological, pathological, and genetic conditions dissociate this relation. In each instance, the dissociation can be traced to the distal convoluted tubule, where calcium and sodium transport are inversely related. Based on the identification of the relevant sodium transporters in these cells and on analysis of the mechanism of calcium transport, an explanation for this inverse relation can be developed. Apical membrane calcium entry is mediated by voltage-sensitive calcium channels that are activated upon membrane hyperpolarization. Basolateral calcium efflux is effected primarily by Na+/Ca2+ exchange. According to the model, inhibition of sodium entry through either the Na-Cl cotransporter or the Na+ channel hyperpolarizes the cell, as does parathyroid hormone, thereby activating the calcium entry channel and increasing the driving force for diffusional entry. Membrane hyperpolarization also increases the driving force of calcium efflux through the Na+/Ca2+ exchanger. Thus sodium-dependent changes of calcium transport are indirect and occur secondarily through effects on membrane voltage.
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AQUAPORIN-2 AND -3: Representatives of Two Subgroups of the Aquaporin Family Colocalized in the Kidney Collecting Duct
S. Sasaki, K. Ishibashi, and F. MarumoVol. 60 (1998), pp. 199–220More Less▪ AbstractSince the molecular identification of the first aquaporin in 1992, the number of proteins known to belong to this family has been rapidly increasing. These members may be separated into two subgroups based on gene structure, sequence homology, and function. Regulation of the water permeability of the collecting ducts of the kidney is essential for urinary concentration. Aquaporin-2 and -3, which are representative of these subgroups, are colocalized in the collecting ducts. Understanding these subgroups will elucidate the differences between aquaporin-2 and -3. Aquaporin-2 is a vasopressin-regulated water channel located in the apical membrane, and aquaporin-3 is a constitutive water channel located in the basolateral membrane. In contrast to aquaporin-3, which appears to be less well regulated, many studies have now identified multiple regulational mechanisms at the gene, protein, and cell levels for aquaporin-2, thus reflecting its physiological importance. Evidence of the participation of aquaporin-2 in the pathophysiology of water-balance disorders is accumulating.
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MOLECULAR MECHANISMS OF PROSTAGLANDIN TRANSPORT
Vol. 60 (1998), pp. 221–242More Less▪ AbstractDespite the fact that prostaglandins (PGs) have low intrinsic permeabilities across the plasma membrane, they must cross it twice: first upon release from the cytosol into the blood, and again upon cellular uptake prior to oxidation. Until recently, there were no cloned carriers that transported PGs. PGT is a broadly-expressed, 12-membrane-spanning domain integral membrane protein. When heterologously expressed in HeLa cells or Xenopus oocytes, it catalyzes the rapid, specific, and high-affinity uptake of PGE2, PGF2α, PGD2, 8-iso-PGF2α, and thromboxane B2. Functional studies indicate that PGT transports its substrate as the charged anion. The PGT substrate specificity and inhibitor profile match remarkably well with earlier in situ studies on the metabolic clearance of PGs by rat lung. Because PGT expression is especially high in this tissue, it is likely that PGT mediates the membrane step in PG clearance by the pulmonary circulation. Evidence is presented that PGT may play additional roles in other tissues and that there may be additional PG transporters yet to be identified molecularly.
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ORGANIC CATION TRANSPORTERS IN INTESTINE, KIDNEY, LIVER, AND BRAIN
Vol. 60 (1998), pp. 243–266More Less▪ AbstractThis review focuses on sodium-independent transport systems for organic cations in small intestine, liver, kidney, and brain. The roles of P-glycoproteins (MDR) and anion transporters (OATP) in organic cation transport are reported, and two members of the new transporter family OCT are described. The OCT transporters belong to a superfamily that includes multidrug-resistance proteins, facilitative diffusion systems, and proton antiporters. They mediate electrogenic transport of small organic cations with different molecular structures, independently of sodium and proton gradients. The current knowledge of the distribution and functional properties of cloned cation transport systems and of cation transport measured in intact plasma membranes is used to postulate identical or homologous transporters in intestine, liver, kidney, and brain.
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ROLE OF CARDIAC NEURAL CREST CELLS IN CARDIOVASCULAR DEVELOPMENT
Vol. 60 (1998), pp. 267–286More Less▪ AbstractThe discovery in the chick embryo that a specific region of the neural crest, termed the cardiac neural crest, is essential for septation of the cardiac outflow tract and for aortic arch artery development has led to the classification of a whole series of human cardiac defects as neural crest-associated. Recently, several mouse genetic models have been effectively employed to yield new insights into the relationship between cardiac neural crest and structural heart development. In all the animal models of neural crest-related heart defects, prenatal mortality is too high to be attributed to structural defects of the heart alone, and there are obvious signs of severe cardiac dysfunction. The evidence indicates that poor viability is from impaired cardiac excitation-contraction coupling and contractile function at the myocyte level. The continued study of experimental and genetically defined models with neural crest-associated heart defects will prove useful in identifying the common pathways by which the neural crest contributes to normal heart development.
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MOLECULAR INSIGHTS INTO CARDIAC DEVELOPMENT
Vol. 60 (1998), pp. 287–308More Less▪ AbstractRecent discoveries have led to a greater appreciation of the diverse mechanisms that underlie cardiac morphogenesis. Genetic strategies (primarily gene targeting approaches in mice) have significantly broadened research in cardiovascular developmental biology by illuminating new pathways involved in heart development and by allowing the genetic evaluation of pathways that have previously been implicated in these events. Advances have also been made using biochemical and cell- and tissue-based approaches. This review summarizes the author's interpretation of current trends in the effort to understand the molecular basis of cardiac development, with an emphasis on insights obtained from genetic models.
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NORMAL AND ABNORMAL CONSEQUENCES OF APOPTOSIS IN THE HUMAN HEART
Vol. 60 (1998), pp. 309–325More Less▪ AbstractKnowledge about apoptosis has become essential for understanding many aspects of cardiac structure and function. In the human heart there are major periods of morphogenesis that begin only after birth, and some of these processes recur intermittently for many years. Although the exact mechanisms by which these events are initiated or terminated remain poorly understood, it is clear that their benefits may be mirrored in destructive effects. In this review, selected examples include normal morphogenesis of the cardiac conduction system and the normal postnatal involution of the right ventricle, both of which are mediated by apoptosis. Destructive counterparts include familial heart block ending in fatal arrhythmias, similar results in the long QT syndrome, and the pathogenesis of both Uhl's anomaly and arrhythmogenic right ventricular dysplasia; in each apoptosis is an important factor.
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ELECTRICAL AND CALCIUM SIGNALING IN DENDRITES OF HIPPOCAMPAL PYRAMIDAL NEURONS
Vol. 60 (1998), pp. 327–346More Less▪ AbstractThis review discusses recent data regarding the different types of voltage-gated Na+, Ca2+, and K+ channels in dendrites of CA1 pyramidal neurons and their function for synaptic integration and plasticity. Na+ and Ca2+ channels are uniformly distributed throughout the dendrites, although Na+ channels in the soma and proximal dendrites differ in their inactivation properties from Na+ channels in more distal regions. Also, different regions of the neuron express different subtypes of Ca2+ channels. K+ channels are unevenly distributed, with the distal dendrites expressing a more than fivefold greater density of a transient A-type K+ channel than proximal regions. These K+ channels exert profound control over the excitability of the pyramidal neurons and the spread of synaptic potentials throughout the dendrites. The ways in which the active properties of dendrites may contribute toward the induction and maintenance of long-term synaptic plasticity are discussed.
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THE SYNAPTIC VESICLE CYCLE
W. J. Betz, and J. K. AnglesonVol. 60 (1998), pp. 347–363More Less▪ AbstractThe ins and outs of the synaptic vesicle cycle are being examined in increasing detail with diverse investigative tools in a variety of cell types, particularly those with large granules. The cycle begins with the opening of a fusion pore that connects the vesicle lumen to the extracellular fluid. Sensitive electrophysiological techniques reveal the often-stuttering behavior of single pores in non-neuronal cells, through which small molecules trickle until the fusion pore expands and the remaining contents erupt from the vesicle. The granule membranes are then retrieved by multiple processes that appear to act in parallel and that are distinguished from each other kinetically and ultrastructurally. Following endocytosis, synaptic vesicles are then shuttled back into the vesicle pool, where they briefly mix with other vesicles, become immobilized, and remain gelled with their neighbors, even while moving en masse again to the presynaptic membrane as a prelude for another round of exocytosis.
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SURFACTANT PROTEINS: Molecular Genetics of Neonatal Pulmonary Diseases
Joanna Floros, and Padma KalaVol. 60 (1998), pp. 365–384More Less▪ AbstractGenetic and phenotypic complexity has been described for diseases of varied etiology. Groups of patients with varied phenotype can be used in association studies as an initial approach to identify contributing loci. Although association studies have limitations, their value is enhanced by using candidate genes with functions related to disease. Surfactant proteins have been studied in the etiopathogenesis of neonatal pulmonary diseases. SP-A and SP-B polymorphisms are found at a higher frequency in certain groups of patients with respiratory distress syndrome (RDS), and SP-B mutations are linked to the pathogenesis of congenital alveolar proteinosis (CAP). Phenotypic heterogeneity is observed for both CAP and RDS. The available data suggest that a number of factors contribute to the etiology of CAP and RDS and, therefore, a multidisciplinary approach of clinical, genetic, epidemiologic, and statistical considerations is necessary for an in-depth understanding of the pathophysiology of these and other pulmonary diseases.
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Previous Volumes
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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)