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- Volume 64, 1995
Annual Review of Biochemistry - Volume 64, 1995
Volume 64, 1995
- Review Articles
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THE ENVELOPE OF MYCOBACTERIA
Vol. 64 (1995), pp. 29–63More LessMycobacteria, members of which cause tuberculosis and leprosy, produce cell walls of unusually low permeability, which contribute to their resistance to therapeutic agents. Their cell walls contain large amounts of C60-C90 fatty acids, mycolic acids, that are covalently linked to arabinogalactan. Recent studies clarified the unusual structures of arabinogalactan as well as of extractable cell wall lipids, such as trehalose-based lipooligosaccharides, phenolic glycolipids, and glycopeptidolipids. Most of the hydrocarbon chains of these lipids assemble to produce an asymmetric bilayer of exceptional thickness. Structural considerations suggest that the fluidity is exceptionally low in the innermost part of bilayer, gradually increasing toward the outer surface. Differences in mycolic acid structure may affect the fluidity and permeability of the bilayer, and may explain the different sensitivity levels of various mycobacterial species to lipophilic inhibitors. Hydrophilic nutrients and inhibitors, in contrast, traverse the cell wall presumably through channels of recently discovered porins.
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TRIPLEX DNA STRUCTURES
Vol. 64 (1995), pp. 65–95More LessA DNA triplex is formed when pyrimidine or purine bases occupy the major groove of the DNA double Helix forming Hoogsteen pairs with purines of the Watson-Crick basepairs. Intermolecular triplexes are formed between triplex forming oligonucleotides (TFO) and target sequences on duplex DNA. Intramolecular triplexes are the major elements of H-DNAs, unusual DNA structures, which are formed in homopurine-homopyrimidine regions of supercoiled DNAs. TFOs are promising gene-drugs, which can be used in an anti-gene strategy, that attempt to modulate gene activity in vivo. Numerous chemical modifications of TFO are known. In peptide nucleic acid (PNA), the sugarphosphate backbone is replaced with a protein-like backbone. PNAs form P-loops while interacting with duplex DNA fonning triplex with one of DNA strands leaving the other strand displaced. Very unusual recombination or parallel triplexes, or R-DNA, have been assumed to form under RecA protein in the course of homologous recombination.
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SELECTIN-CARBOHYDRATE INTERACTIONS AND THE INITIATION OF THE INFLAMMATORY RESPONSE
Vol. 64 (1995), pp. 113–140More LessThe orderly migration of various white blood cell types to inflammatory sites is a highly regulated process that involves a diversity of adhesion and signaling molecules. This cellular influx is initiated by relatively low affinity interactions that allow for leukocytes to roll along the vascular surface. This rolling phenomenon is mediated by adhesive interactions between lectin containing adhesion molecules, termed selectins, on both the vascular endothelium and leukocytes, and carbohydrate ligands immobilized on mucin-like scaffolds. This adhesion allows for a rapid recognition of various cell types under the conditions of vascular flow, with the result that inflammatory cells are specifically decelerated adjacent to sites of inflammation. This review focuses on the various biochemical aspects of the interactions between the selectins and their cognate carbohydrate ligands, with an emphasis on the importance of these adhesive events to the inflammatory response.
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DNA PROCESSING REACTIONS IN BACTERIAL CONJUGATION
Vol. 64 (1995), pp. 141–169More LessBacterial conjugation is an important source of genetic plasticity. The initiation complex for conjugative transfer of transmissible plasmids—the relaxosome—is a specific DNA-protein structure that has been isolated from cells and reconstituted from purified components in vitro. Complexes containing uncleaved DNA and DNA cleaved at the nicsite in the origin of transfer (oriT) coexist in equilibrium. Relaxase is usually loaded onto oriT by accessory DNA-binding proteins. Relaxase catalyzes cleavage of a specific phosphodiester bond at nic and becomes covalently linked through a tyrosyl residue to the 5′ terminus of the cleaved strand. Cleaved DNA may be unwound for transfer by a plasmid-encoded helicase. Single-strand transfer is thought to occur by a replicative rolling circle mechanism. Termination of a round of transfer is achieved by the cleaving-joining activity of the relaxase linked to the 5′ end of the transferring strand. Relationships between DNA processing reactions and conjugative interactions of cell envelopes are particularly obscure aspects of the conjugation cycle.
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DNA POLYMERASE III HOLOENZYME: Structure and Function of a Chromosomal Replicating Machine
Zvi Kelman, and Mike O'DonnellVol. 64 (1995), pp. 171–200More LessDNA polymerase III holoenzyme contains two DNA polymerases embedded in a particle with 9 other subunits. This multi subunit DNA polymerase is the Escherichia coli chromosomal replicase, and it has several special features that distinguish it as a replicating machine. For example, one of its subunits is a circular protein that slides along DNA while clamping the rest of the machinery to the template. Other subunits act together as a matchmaker to assemble the ring onto DNA. Overall, E. coli DNA polymerase III holoenzyme is very similar in both structure and function to the chromosomal replicases of eukaryotes, from yeast all the way up to humans. This review summarizes our present knowledge about the function of the 10 subunits of this replicating machine and how they coordinate their actions for smooth duplication of chromosomes.
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THE ROLES OF RETINOIDS IN VERTEBRATE DEVELOPMENT
Vol. 64 (1995), pp. 201–233More LessSeveral lines of experimentation suggest that endogenous retinoids, metabolites of vitamin A, play a role in the anterior/posterior development of the central body axis and the limbs of vertebrates. High levels of endogenous retinoids have been detected in proximity to these developing axes in a variety of vertebrate fetuses. Teratogenesis studies suggest that both retinoid excess and deficiency are capable of disrupting the development of these axes. Finally, retinoic acid receptors regulate many developmental control genes, including homeobox genes and growth factor genes.
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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)