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- Volume 77, 2008
Annual Review of Biochemistry - Volume 77, 2008
Volume 77, 2008
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Biochemistry and Physiology of Mammalian Secreted Phospholipases A2
Vol. 77 (2008), pp. 495–520More LessPhospholipases A2 (PLA2s) are esterases that hydrolyze the sn-2 ester of glycerophospholipids and constitute one of the largest families of lipid hydrolyzing enzymes. The mammalian genome contains 10 enzymatically active secreted PLA2s (sPLA2s) and two sPLA2-related proteins devoid of lipolytic enzymatic activity. In addition to the well-established functions of one of these enzymes in digestion of dietary phospholipids and another in host defense against bacterial infections, accumulating evidence shows that some of these sPLA2s are involved in arachidonic acid release from cellular phospholipids for the biosynthesis of eicosanoids, especially during inflammation. More speculative results suggest the involvement of one or more sPLA2s in promoting atherosclerosis and cancer. In addition, the mammalian genome encodes several types of sPLA2-binding proteins, and mounting evidence shows that sPLA2s may have functions related to binding to cellular target proteins in a manner independent of their lipolytic enzymatic activity.
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Glycosyltransferases: Structures, Functions, and Mechanisms
Vol. 77 (2008), pp. 521–555More LessGlycosyltransferases catalyze glycosidic bond formation using sugar donors containing a nucleoside phosphate or a lipid phosphate leaving group. Only two structural folds, GT-A and GT-B, have been identified for the nucleotide sugar-dependent enzymes, but other folds are now appearing for the soluble domains of lipid phosphosugar-dependent glycosyl transferases. Structural and kinetic studies have provided new insights. Inverting glycosyltransferases utilize a direct displacement SN2-like mechanism involving an enzymatic base catalyst. Leaving group departure in GT-A fold enzymes is typically facilitated via a coordinated divalent cation, whereas GT-B fold enzymes instead use positively charged side chains and/or hydroxyls and helix dipoles. The mechanism of retaining glycosyltransferases is less clear. The expected two-step double-displacement mechanism is rendered less likely by the lack of conserved architecture in the region where a catalytic nucleophile would be expected. A mechanism involving a short-lived oxocarbenium ion intermediate now seems the most likely, with the leaving phosphate serving as the base.
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Structural Biology of the Tumor Suppressor p53
Vol. 77 (2008), pp. 557–582More LessThe tumor suppressor protein p53 induces or represses the expression of a variety of target genes involved in cell cycle control, senescence, and apoptosis in response to oncogenic or other cellular stress signals. It exerts its function as guardian of the genome through an intricate interplay of independently folded and intrinsically disordered functional domains. In this review, we provide insights into the structural complexity of p53, the molecular mechanisms of its inactivation in cancer, and therapeutic strategies for the pharmacological rescue of p53 function in tumors. p53 emerges as a paradigm for a more general understanding of the structural organization of modular proteins and the effects of disease-causing mutations.
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Toward a Biomechanical Understanding of Whole Bacterial Cells
Vol. 77 (2008), pp. 583–613More LessFollowing decades of research in genetics and biochemistry, the basic metabolism of bacteria is now well understood. In addition to core metabolism, however, bacterial cells also perform a number of mechanical tasks such as maintaining a characteristic shape, moving within their environment, segregating their genome, and dividing. Major advances in imaging technologies including fluorescence light microscopy (fLM) and electron cryotomography (ECT) have provided new insight into the bacterial ultrastructures that accomplish these tasks. It is now clear, for instance, that bacteria are highly organized, possessing cytoskeletons, specifically arranged genomes, internal compartments, and carefully positioned macromolecular machines. These structures and their functions are reviewed here in the form of a progress report toward a complete biomechanical understanding of a generalized bacterial cell. The goal of eventually integrating genetic, biochemical, imaging, and biophysical data into spatially explicit, mechanically predictive models of whole cells is highlighted.
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How Does Synaptotagmin Trigger Neurotransmitter Release?
Vol. 77 (2008), pp. 615–641More LessNeurotransmitter release at synapses involves a highly specialized form of membrane fusion that is triggered by Ca2+ ions and is optimized for speed. These observations were established decades ago, but only recently have the molecular mechanisms that underlie this process begun to come into view. Here, we summarize findings obtained from genetically modified neurons and neuroendocrine cells, as well as from reconstituted systems, which are beginning to reveal the molecular mechanism by which Ca2+—acting on the synaptic vesicle (SV) protein synaptotagmin I (syt)—triggers rapid exocytosis. This work sheds light not only on presynaptic aspects of synaptic transmission, but also on the fundamental problem of membrane fusion, which has remained a puzzle that has yet to be solved in any biological system.
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Protein Translocation Across the Bacterial Cytoplasmic Membrane
Vol. 77 (2008), pp. 643–667More LessAbout 25% to 30% of the bacterial proteins function in the cell envelope or outside of the cell. These proteins are synthesized in the cytosol, and the vast majority is recognized as a ribosome-bound nascent chain by the signal recognition particle (SRP) or by the secretion-dedicated chaperone SecB. Subsequently, they are targeted to the Sec translocase in the cytoplasmic membrane, a multimeric membrane protein complex composed of a highly conserved protein-conducting channel, SecYEG, and a peripherally bound ribosome or ATP-dependent motor protein SecA. The Sec translocase mediates the translocation of proteins across the membrane and the insertion of membrane proteins into the cytoplasmic membrane. Translocation requires the energy sources of ATP and the proton motive force (PMF) while the membrane protein insertion is coupled to polypeptide chain elongation at the ribosome. This review summarizes the present knowledge of the mechanism and structure of the Sec translocase, with a special emphasis on unresolved questions and topics of current research.
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Maturation of Iron-Sulfur Proteins in Eukaryotes: Mechanisms, Connected Processes, and Diseases
Vol. 77 (2008), pp. 669–700More LessIron-sulfur (Fe/S) proteins are involved in a wide variety of cellular processes such as enzymatic reactions, respiration, cofactor biosynthesis, ribosome biogenesis, regulation of gene expression, and DNA-RNA metabolism. Assembly of Fe/S clusters, small inorganic cofactors, is assisted by complex proteinaceous machineries, which use cysteine as a source of sulfur, combine it with iron to synthesize an Fe/S cluster on scaffold proteins, and finally incorporate the cluster into recipient apoproteins. In eukaryotes, such as yeast and human cells, more than 20 components are known that facilitate the maturation of Fe/S proteins in mitochondria, cytosol, and nucleus. These biogenesis components also perform crucial roles in other cellular pathways, e.g., in the regulation of iron homeostasis or the modification of tRNA. Numerous diseases including several neurodegenerative and hematological disorders have been associated with defects in Fe/S protein biogenesis, underlining the central importance of this process for life.
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CFTR Function and Prospects for Therapy
Vol. 77 (2008), pp. 701–726More LessMutations in the gene coding for the cystic fibrosis transmembrane conductance regulator (CFTR) epithelial anion channel cause cystic fibrosis (CF). The multidomain integral membrane glycoprotein, a member of the adenine nucleotide-binding cassette (ABC) transporter family, conserved in metazoan salt-transporting tissues, is required to control ion and fluid homeostasis on epithelial surfaces. This review considers different therapeutic strategies that have arisen from knowledge of CFTR structure and function as well as its biosynthetic processing, intracellular trafficking, and turnover.
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Aging and Survival: The Genetics of Life Span Extension by Dietary Restriction
Vol. 77 (2008), pp. 727–754More LessReducing food intake to induce undernutrition but not malnutrition extends the life spans of multiple species, ranging from single-celled organisms to mammals. This increase in longevity by dietary restriction (DR) is coupled to profound beneficial effects on age-related pathology. Historically, much of the work on DR has been undertaken using rodent models, and 70 years of research has revealed much about the physiological changes DR induces. However, little is known about the genetic pathways that regulate the DR response and whether or not they are conserved between species. Elucidating these pathways may facilitate the design of targeted pharmaceutical treatments for a range of age-related pathologies. Here, we discuss how recent work in nonmammalian model organisms has revealed new insight into the genetics of DR and how the discovery of DR-specific transcription factors will advance our understanding of this phenomenon.
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Cellular Defenses against Superoxide and Hydrogen Peroxide
Vol. 77 (2008), pp. 755–776More LessLife evolved in an anaerobic world; therefore, fundamental enzymatic mechanisms and biochemical pathways were refined and integrated into metabolism in the absence of any selective pressure to avoid reactivity with oxygen. After photosystem II appeared, environmental oxygen levels rose very slowly. During this time, microorganisms acquired oxygen tolerance by jettisoning enzymes that use glycyl radicals and exposed low-potential iron-sulfur clusters, which can be directly poisoned by oxygen. They also developed mechanisms to defend themselves against superoxide (O2−) and hydrogen peroxide, partially reduced oxygen species that are generated as inadvertent by-products of aerobic metabolism. Contemporary organisms have inherited both the vulnerabilities and the defenses of these ancestral microbes. Current research seeks to identify these, and bacteria comprise an exceptionally accessible experimental system that has provided many of the answers. This manuscript reviews recent developments and identifies remaining puzzles.
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Toward a Control Theory Analysis of Aging
Vol. 77 (2008), pp. 777–798More LessAging is due to the accumulation of damage over time that affects the function and survival of the organism; however, it has proven difficult to infer the relative importance of the many processes that contribute to aging. To address this, here we outline an approach that may prove useful in analyzing aging. In this approach, the function of the organism is described as a set of interacting physiological systems. Degradation of their outputs leads to functional decline and death as a result of aging. In turn, degradation of the system outputs is attributable to changes at the next hierarchical level down, the cell, through changes in cell number or function, which are in turn a consequence of the metabolic history of the cell. Within this framework, we then adapt the methods of metabolic control analysis (MCA) to determine which modifications are important for aging. This combination of a hierarchical framework and the methodologies of MCA may prove useful both for thinking about aging and for analyzing it experimentally.
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Previous Volumes
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Volume 92 (2023)
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Volume 91 (2022)
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Volume 90 (2021)
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Volume 89 (2020)
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Volume 88 (2019)
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Volume 87 (2018)
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Volume 86 (2017)
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Volume 85 (2016)
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Volume 84 (2015)
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Volume 83 (2014)
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Volume 82 (2013)
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Volume 81 (2012)
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Volume 80 (2011)
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Volume 79 (2010)
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Volume 78 (2009)
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Volume 77 (2008)
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Volume 76 (2007)
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Volume 75 (2006)
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Volume 74 (2005)
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Volume 73 (2004)
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Volume 72 (2003)
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Volume 71 (2002)
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Volume 70 (2001)
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Volume 69 (2000)
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Volume 68 (1999)
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Volume 67 (1998)
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Volume 66 (1997)
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Volume 65 (1996)
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Volume 64 (1995)
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Volume 63 (1994)
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Volume 62 (1993)
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Volume 61 (1992)
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Volume 60 (1991)
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Volume 59 (1990)
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Volume 58 (1989)
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Volume 57 (1988)
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Volume 56 (1987)
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Volume 55 (1986)
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Volume 54 (1985)
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Volume 53 (1984)
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Volume 52 (1983)
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Volume 51 (1982)
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Volume 50 (1981)
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Volume 49 (1980)
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Volume 48 (1979)
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Volume 47 (1978)
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Volume 46 (1977)
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Volume 45 (1976)
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Volume 44 (1975)
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Volume 43 (1974)
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Volume 42 (1973)
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Volume 41 (1972)
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Volume 40 (1971)
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Volume 39 (1970)
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Volume 38 (1969)
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Volume 37 (1968)
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Volume 36 (1967)
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Volume 35 (1966)
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Volume 34 (1965)
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Volume 33 (1964)
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Volume 32 (1963)
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Volume 31 (1962)
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Volume 30 (1961)
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Volume 29 (1960)
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Volume 28 (1959)
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Volume 27 (1958)
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Volume 26 (1957)
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Volume 25 (1956)
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Volume 24 (1955)
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Volume 23 (1954)
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Volume 22 (1953)
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Volume 21 (1952)
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Volume 20 (1951)
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Volume 19 (1950)
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Volume 18 (1949)
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Volume 17 (1948)
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Volume 16 (1947)
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Volume 15 (1946)
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Volume 14 (1945)
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Volume 13 (1944)
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Volume 12 (1943)
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Volume 11 (1942)
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Volume 10 (1941)
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Volume 9 (1940)
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Volume 8 (1939)
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Volume 7 (1938)
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Volume 6 (1937)
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Volume 5 (1936)
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Volume 4 (1935)
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Volume 3 (1934)
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Volume 2 (1933)
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Volume 1 (1932)
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Volume 0 (1932)