Showing papers in "The FASEB Journal in 1995"

The MAPK signaling cascade.

Abstract: The transmission of extracellular signals into their intracellular targets is mediated by a network of interacting proteins that regulate a large number of cellular processes. Cumulative efforts from many laboratories over the past decade have allowed the elucidation of one such signaling mechanism, which involves activations of several membranal signaling molecules followed by a sequential stimulation of several cytoplasmic protein kinases collectively known as mitogen-activated protein kinase (MAPK) signaling cascade. Up to six tiers in this cascade contribute to the amplification and specificity of the transmitted signals that eventually activate several regulatory molecules in the cytoplasm and in the nucleus to initiate cellular processes such as proliferation, differentiation, and development. Moreover, because many oncogenes have been shown to encode proteins that transmit mitogenic signals upstream of this cascade, the MAPK pathway provides a simple unifying explanation for the mechanism of action...

Protein kinases 6. The eukaryotic protein kinase superfamily: kinase (catalytic) domain structure and classification.

Abstract: The eukaryotic protein kinases make up a large superfamily of homologous proteins. They are related by virtue of their kinase domains (also known as catalytic domains), which consist of approximately 250-300 amino acid residues. The kinase domains that define this group of enzymes contain 12 conserved subdomains that fold into a common catalytic core structure, as revealed by the 3-dimensional structures of several protein-serine kinases. There are two main subdivisions within the superfamily: the protein-serine/threonine kinases and the protein-tyrosine kinases. A classification scheme can be founded on a kinase domain phylogeny, which reveals families of enzymes that have related substrate specificities and modes of regulation.

Protein kinase C and lipid signaling for sustained cellular responses.

Abstract: Since the second messenger role was proposed for the products of inositol phospholipid hydrolysis, considerable progress has been made in our understanding of the biochemical mechanism of the intracellular signaling network It is now becoming evident that stimulation of a cell surface receptor initiates a degradation cascade of various membrane lipid constituents Many of their metabolites have potential to induce, intensify, and prolong the activation of protein kinase C that is needed for sustained cellular responses

Transcriptional regulation of endothelial cell adhesion molecules: NF-kappa B and cytokine-inducible enhancers.

Abstract: Transcription of endothelial-leukocyte adhesion molecule-1 (E-selectin or ELAM-1), vascular cell adhesion molecule-1 (VCAM-1), and intercellular adhesion molecule-1 (ICAM-1) is induced by the inflammatory cytokines interleukin-1 beta (IL-1 beta) and tumor necrosis factor-alpha (TNF alpha). The positive regulatory domains required for maximal levels of cytokine induction have been defined in the promoters of all three genes. DNA binding studies reveal a requirement for nuclear factor-kappa B (NF-kappa B) and a small group of other transcriptional activators. The organization of the cytokine-inducible element in the E-selectin promoter is remarkably similar to that of the virus-inducible promoter of the human interferon-beta gene in that both promoters require NF-kappa B, activating transcription factor-2 (ATF-2), and high mobility group protein I(Y) for induction. Based on this structural similarity, a model has been proposed for the cytokine-induced E-selectin enhancer that is similar to the stereospecific complex proposed for the interferon-beta gene promoter. In these models, multiple DNA bending proteins facilitate the assembly of higher order complexes of transcriptional activators that interact as a unit with the basal transcriptional machinery. The assembly of unique enhancer complexes from similar sets of transcriptional factors may provide the specificity required to regulate complex patterns of gene expression and correlate with the distinct patterns of expression of the leukocyte adhesion molecules.

Structure and properties of carotenoids in relation to function.

Abstract: The basic principles of structure, stereochemistry, and nomenclature of carotenoids are described and the relationships between structure and the chemical and physical properties on which all the varied biological functions and actions of carotenoids depend are discussed. The conjugated polyene chromophore determines not only the light absorption properties, and hence color, but also the photochemical properties of the molecule and consequent light-harvesting and photoprotective action. The polyene chain is also the feature mainly responsible for the chemical reactivity of carotenoids toward oxidizing agents and free radicals, and hence for any antioxidant role. In vivo, carotenoids are found in precise locations and orientations in subcellular structures, and their chemical and physical properties are strongly influenced by other molecules in their vicinity, especially proteins and membrane lipids. In turn, the carotenoids influence the properties of these subcellular structures. Structural features such as size, shape, and polarity are essential determinants of the ability of a carotenoid to fit correctly into its molecular environment to allow it to function. A role for carotenoids in modifying structure, properties, and stability of cell membranes, and thus affecting molecular processes associated with these membranes, may be an important aspect of their possible beneficial effects on human health.--Britton, G. Structure and properties of carotenoids in relation to function.

The biochemistry of programmed cell death.

Abstract: Programmed cell death (PCD) is involved in the removal of superfluous and damaged cells in most organ systems. The induction phase of PCD or apoptosis is characterized by an extreme heterogeneity of potential PCD-triggering signal transduction pathways. During the subsequent effector phase, the numerous PCD-inducing stimuli converge into a few stereotypical pathways and cells pass a point of no return, thus becoming irreversibly committed to death. It is only during the successive degradation phase that vital structures and functions are destroyed, giving rise to the full-blown phenotype of PCD. Evidence is accumulating that cytoplasmic structures, including mitochondria, participate in the critical effector stage and that alterations commonly considered to define PCD (apoptotic morphology of the nucleus and regular, oligonucleosomal chromatin fragmentation) have to be ascribed to the late degradation phase. The decision as to whether a cell will undergo PCD or not may be expected to be regulated by "switches" that, once activated, trigger self-amplificatory metabolic pathways. One of these switches may reside in a perturbation of mitochondrial function. Thus, a decrease in mitochondrial transmembrane potential, followed by mitochondrial uncoupling and generation of reactive oxygen species, precedes nuclear alterations. It appears that molecules that participate in apoptotic decision-making also exert functions that are vital for normal cell proliferation and intermediate metabolism.

The selectins: vascular adhesion molecules.

Abstract: The selectin family of adhesion molecules mediates the initial attachment of leukocytes to venular endothelial cells before their firm adhesion and diapedesis at sites of tissue injury and inflammation. The selectin family consists of three closely related cell-surface molecules with differential expression by leukocytes (L-selectin), platelets (P-selectin), and vascular endothelium (E- and P-selectin). The selectins have characteristic extracellular regions composed of an amino-terminal lectin domain that binds a carbohydrate ligand, an epidermal growth factor-like domain, and two to nine short repeat units homologous to domains found in complement binding proteins. In contrast to most other adhesion molecules, selectin function is restricted to leukocyte interactions with vascular endothelium. Multiple studies indicate that the selectins mediate neutrophil, monocyte, and lymphocyte rolling along the venular wall. The generation of selectin-deficient mice has confirmed these findings and provided further insight into how the overlapping functions of these receptors regulate inflammatory processes. Selectin-directed therapeutic agents are now proven to be effective in blocking many of the pathological effects resulting from leukocyte entry into sites of inflammation. Future studies are focused on how the selectins interact with the increasing array of other adhesion molecules and inflammatory mediators.

Oxidative stress-induced cataract: mechanism of action.

Abstract: This review examines the hypothesis that oxidative stress is an initiating factor for the development of maturity onset cataract and describes the events leading to lens opacification. Data are reviewed that indicate that extensive oxidation of lens protein and lipid is associated with human cataract found in older individuals whereas little oxidation (and only in membrane components) is found in control subjects of similar age. A significant proportion of lenses and aqueous humor taken from cataract patients have elevated H2O2 levels. Because H2O2, at concentrations found in cataract, can cause lens opacification and produces a pattern of oxidation similar to that found in cataract, it is concluded that H2O2 is the major oxidant involved in cataract formation. This viewpoint is further supported by experiments showing that cataract formation in organ culture caused by photochemically generated superoxide radical, H2O2, and hydroxyl radical is completely prevented by the addition of a GSH peroxidase mimic. The damage caused by oxidative stress does not appear to be reversible and there is an inverse relationship between the stress period and the time required for loss of transparency and degeneration of biochemical parameters such as ATP, GPD, nonprotein thiol, and hydration. After exposure to oxidative stress, the redox set point of the single layer of the lens epithelial cells (but not the remainder of the lens) quickly changes, going from a strongly reducing to an oxidizing environment. Almost concurrent with this change is extensive damage to DNA and membrane pump systems, followed by loss of epithelial cell viability and death by necrotic and apoptotic mechanisms. The data suggest that the epithelial cell layer is the initial site of attack by oxidative stress and that involvement of the lens fibers follows, leading to cortical cataract.

Oxidative processes and antioxidative defense mechanisms in the aging brain.

Abstract: The debilitating consequences of age-related brain deterioration are widespread and extremely costly in terms of quality of life and longevity. One of the potential major causes of age-related destruction of neuronal tissue is toxic free radicals that are a natural result of aerobic metabolism. The brain is particularly susceptible to free radical attack because it generates more of these toxicants per gram of tissue than does any other organ. The major defense mechanisms the brain uses to combat reducing equivalents is via their enzymatic metabolism. The vitamin antioxidants, vitamin E (alpha-tocopherol in particular) and vitamin C (ascorbate), also aid in protecting the brain from oxidative stress by directly scavenging toxic radicals. A newly discovered, potentially highly important antioxidant in the brain is the indole melatonin. The pineal hormone melatonin is rapidly taken up by the brain. In vitro melatonin is more effective than glutathione in scavenging the highly toxic hydroxyl radical and also...

Molecular mechanisms and therapeutic strategies related to nitric oxide.

Abstract: The formation of nitric oxide (NO) from L-arginine is now recognized as a ubiquitous biochemical pathway involved in the regulation of the cardiovascular, central, and peripheral nervous systems, as well as in other homeostatic mechanisms. The L-arginine:NO pathway comprises a substrate, L-arginine, a family of enzymes, the NO synthases, and at least one physiological effector system, the soluble guanylate cyclase. NO also inhibits enzymes in target cells and can interact with oxygen-derived radicals to produce other toxic substances. Thus, NO also plays a role in immunological host defense and in the pathophysiology of certain clinical conditions. Several steps in the L-arginine:NO pathway are amenable to manipulation. Some substances will change the concentration and/or actions of NO with consequences that, in certain cases, may be therapeutic. In addition, other agents themselves generate NO and thus mimic the actions of the endogenous mediator. This brief overview will discuss some possible interventi...

Sensitivity of osteocytes to biomechanical stress in vitro.

Abstract: It has been known for more than a century that bone tissue adapts to functional stress by changes in structure and mass. However, the mechanism by which stress is translated into cellular activities of bone formation and resorption is unknown. We studied the response of isolated osteocytes derived from embryonic chicken calvariae to intermittent hydrostatic compression as well as pulsating fluid flow, and compared their response to osteoblasts and periosteal fibroblasts. Osteocytes, but not osteoblasts or periosteal fibroblasts, reacted to 1 h pulsating fluid flow with a sustained release of prostaglandin E2. Intermittent hydrostatic compression stimulated prostaglandin production to a lesser extent: after 6 and 24 h in osteocytes and after 6 h in osteoblasts. These data provide evidence that osteocytes are the most mechanosensitive cells in bone involved in the transduction of mechanical stress into a biological response. The results support the hypothesis that stress on bone causes fluid flow in the lac...

Differentiation of endothelium.

Abstract: Vascular endothelial cells cover the entire inner surface of blood vessels in the body. They play an important role in tissue homeostasis, fibrinolysis and coagulation, blood-tissue exchange, vasotonus regulation, the vascularization of normal and neoplastic tissues, and blood cell activation and migration during physiological and pathological processes. It is therefore important to define the basic determinants of the endothelial phenotype and its modulation in response to different signals. Signal recognition, transduction, and processing are likely to be complex events dependent on the status of the target endothelial cell in a given organ or tissue. This status is a consequence of inductive and permissive interactions of a pluripotent cell with soluble and insoluble signaling molecules of the environment during embryonic and postnatal development. This review will focus on the biological mechanisms involved in the differentiation of endothelial cells from the mesoderm and their subsequent functional h...

Protein kinases. 4. Protein kinase CK2: an enzyme with multiple substrates and a puzzling regulation.

Abstract: Protein kinase CK2 (also known as casein kinase II) is a ubiquitous eukaryotic ser/thr protein kinase present in the nucleus and cytoplasm. CK2 is known to phosphorylate more than 100 substrates, many of which are involved in the control of cell division and in signal transduction. The review centers on the structure and function of CK2 alpha and beta subunits and on the regulation of its activity, a topic that remains to be elucidated. An analogy is drawn between CK2 and the cyclin-dependent kinases (cdks); both types of protein kinases share many substrates and are activated by regulatory subunits.

Calcium-mediated cell injury and cell death.

Abstract: The effect of intracellular ion deregulation, particularly of [Ca2+], on the events following acute cell injury and the progression of change from initiation (reversible) to maintenance (reversible-irreversible) phases and finally to cell death has been the major thrust of experimentation in our laboratory for over 20 years. Cell death, which plays an important role in both normal and pathological phenomena, has been classified into two principal types, accidental and programmed. Recent exploration of programmed cell death (or apoptosis) has revealed extensive data showing it is an important mechanism for the normal maintenance and also differentiation of a variety of cell types and organs. From the results from our laboratory and those of others, we continue to expand and refine our working hypothesis: deregulation of [Ca2+] results in a number of phenomena from activation of signaling mechanisms and alterations in cellular structure to alterations in gene expression, all of which contribute to or play a critical role in cellular toxicity, including carcinogenesis and cell death. Therefore, although much more experimentation is needed to clarify some of these phenomena, the implications of such data for understanding the mechanisms and processes involved in carcinogenesis and the chemotherapeutic killing of cancer cells are extremely exciting. These relationships between [Ca2+], cell injury, and cell death are briefly reviewed here within the framework of our hypothesis.

Liver regeneration. 2. Role of growth factors and cytokines in hepatic regeneration.

Abstract: During liver regeneration quiescent hepatocytes undergo one or two rounds of replication and then return to a nonproliferative state. Growth factors regulate this process by providing both stimulatory and inhibitory signals for cell proliferation. EGF, TGF alpha, and HGF stimulate DNA synthesis in hepatocytes in vivo and in culture but the sensitivity of cultured hepatocytes to the mitogenic effects of these factors is much higher than that of quiescent hepatocytes in intact livers. We have proposed that after partial hepatectomy, hepatocytes enter a state of replicative competence ("priming") before they can fully respond to growth factors. The priming step is an initiating event in liver regeneration that involves the activation and DNA binding of NF-kappa B and other transcription factors, which could be induced by TNF or other cytokines. EGF, TGF alpha, and HGF have major effects on liver growth. TGF alpha expression correlates with hepatocyte DNA synthesis during liver development and growth and the constitutive expression of the factor confers proliferative activity to adult hepatocytes in vivo and in culture. The data indicate that the activity of stimulatory and inhibitory growth factors such as TGF beta 1 and activin is low in normal livers but that the expression of both types of factors increase during liver regeneration.

Protein motifs 5. Zinc fingers.

Abstract: The term zinc finger was first used to describe a 30-residue, repeated sequence motif found in an unusually abundant Xenopus transcription factor. It was proposed that each motif is folded around a central zinc ion to form an independent minidomain and that adjacent zinc fingers are combined as modules to make up a DNA-binding domain with the modules "gripping" the DNA (hence the term finger). We now know that these proposals were correct and that these DNA-binding motifs are found in many eukaryotic DNA-binding proteins. More recently, crystal structures of three different complexes between zinc finger domains and their target DNA binding sites have revealed a remarkably simple mode of interaction with DNA. The simplicity of the zinc finger structure, and of its interaction with DNA, is a very striking feature of this protein domain. After the discovery of the zinc finger motif, patterns of potential zinc ligands have been found in several other proteins, some of which also bind to DNA. Structural studies of these domains have revealed how zinc can stabilize quite diverse protein architectures. In total, 10 such small zinc-binding domains have been studied structurally. These form a diverse collection, but each in turn has been termed a zinc finger motif-although clearly what they have in common is only their zinc-binding property, which stabilizes an apparently autonomously folded unit.

The troponin complex and regulation of muscle contraction.

Abstract: In a wide variety of cellular settings, from organelle transport to muscle contraction, Ca2+ binding to members of the EF hand family of proteins controls the interaction between actin and different myosins that are responsible for generating movement. In vertebrate skeletal and cardiac muscle the Ca(2+)-binding protein troponin C (TnC) is one subunit of the ternary troponin complex which, through its association with actin and tropomyosin on the thin filament, inhibits the actomyosin interaction at submicromolar Ca2+ concentrations and stimulates the interaction at micromolar Ca2+ concentrations. Because TnC does not interact directly with actin or tropomyosin, the Ca(2+)-binding signal must be transmitted to the thin filament via the other two troponin subunits: troponin I (TnI), the inhibitory subunit, and troponin T (TnT), the tropomyosin-binding subunit. Thus, the troponin complex is a Ca(2+)-sensitive molecular switch and the structures of and interactions between its components have been of great i...

Hemodynamic forces are complex regulators of endothelial gene expression.

Abstract: Vascular endothelial cells, by virtue of their unique anatomical position, are constantly exposed to the fluid mechanical forces generated by flowing blood. In vitro studies with model flow systems have demonstrated that wall shear stresses can modulate various aspects of endothelial structure and function. Certain of these effects appear to result from the regulation of expression of endothelial genes at the transcriptional level. Recent molecular biological studies have defined a "shear stress response element" (SSRE) in the promoter of the human platelet-derived growth factor (PDGF)-B chain gene that interacts with DNA binding proteins in the nuclei of shear-stressed endothelial cells to up-regulate transcriptional activity. Insertion of this element into reporter genes also renders them shear-inducible. Further characterization of this and other positive (and negative) shear-responsive genetic regulatory elements, as well as their transactivating factors, should enhance our understanding of vascular e...

Membrane estrogen receptors identified by multiple antibody labeling and impeded-ligand binding.

Abstract: GH3/B6 rat pituitary tumor cells exhibit rapid prolactin release (within 5 min) when treated with nanomolar amounts of estrogen. However, the putative protein mediator of this nongenomic action has not been described. Using antibodies directed against a peptide representing the hinge region of the intracellular estrogen receptor (iER), we have demonstrated that these cells contain a membrane ER (mER). We now report that confocal scanning laser microscopy of cells labeled live with the anti-peptide antibody further supports a membrane localization of ER. The monoclonal antibodies H226 and H222 and a polyclonal antibody, ER21, each recognizing a unique epitope on iER (NH2 terminal to the DNA-binding region, within the steroid binding region, and the NH2-terminal end, respectively), also immunohistochemically label membrane proteins of immuno-selected GH3/B6 cells. These cells also specifically bind a fluorescent estrogen-BSA conjugate. Coincubation of cells with anti-ER antibody and the fluorescent estrogen...

Protein kinases that phosphorylate activated G protein-coupled receptors.

Abstract: G protein-coupled receptor kinases (GRKs) are a family of serine/threonine protein kinases that specifically recognize agonist-occupied, activated G protein-coupled receptor proteins as substrates. Phosphorylation of an activated receptor by a GRK terminates signaling by that receptor, by initiating the uncoupling of the receptor from heterotrimeric G proteins. Six distinct mammalian GRKs are known, which differ in tissue distribution and in regulatory properties. The intracellular localization of GRKs to membrane-bound receptor substrates is the most important known regulatory feature of these enzymes. Rhodopsin kinase (GRK1) requires a post-translationally added farnesyl isoprenoid to bind to light-activated rhodopsin. The beta-adrenergic receptor kinases (GRK2 and GRK3) associate with heterotrimeric G protein beta gamma-subunits, released upon receptor activation of G proteins, for membrane anchorage. The recently-described GRKs 4, 5, and 6 comprise a distinct subgroup of GRKs. These kinases utilize di...

Endothelial cell-to-cell junctions.

Abstract: The endothelium forms the main barrier to the passage of macromolecules and circulating cells from blood to tissues. Endothelial permeability is in large part regulated by intercellular junctions. These are complex structures formed by transmembrane adhesive molecules linked to a network of cytoplasmic/cytoskeletal proteins. At least four different types of endothelial junctions have been described: tight junctions, gap junctions, adherence junctions and syndesmos. These organelles have some features and components in common with epithelial cells but there are also some that are specific for the endothelium. The mechanisms that regulate the opening and closing of endothelial junctions are still obscure. It is conceivable that inflammatory agents increase permeability by binding to specific receptors generating intracellular signals, which in turn cause cytoskeletal reorganization and opening of interendothelial cell gaps. Endothelial junctions also control leukocyte extravasation. Once leukocytes have adhered to the endothelium, a coordinated opening of interendothelial cell junctions occurs. The mechanism by which this takes place is unknown, but it might present characteristics similar to that triggered by soluble mediators.

Muscarinic acetylcholine receptors: signal transduction through multiple effectors.

Abstract: Muscarinic receptors regulate a number of important basic physiologic functions including heart rate and motor and sensory control as well as more complex behaviors including arousal, memory, and learning. Loss of muscarinic receptor number or function has been implicated in the etiology of several neurological disorders including Alzheimer's dementia, Down's syndrome, and Parkinson's disease. Muscarinic receptors transduce their signals by coupling with G-proteins, which then modulate the activity of a number of effector enzymes and ion channels. Five subtypes of muscarinic receptors (m1-m5) have been identified by molecular cloning and much has been learned about their distribution, pharmacology, and structure. Less is known about the molecular mechanisms of receptor-effector coupling and the biological role of each receptor subtype. The ectopic expression of genes encoding a single muscarinic receptor subtype in mammalian cell lines has provided an important model system in which to investigate receptor subtype-specific pharmacology and signal transduction. Expression models have revealed that single muscarinic receptor m1, m3, or m5 subtypes can activate multiple signaling effectors simultaneously including phospholipases A2, C, and D, as well as tyrosine kinase and a novel class of voltage-insensitive calcium channels. The m2 or m4 receptors have been shown to augment phospholipase A2 in addition to their established role as inhibitory receptors acting through the attenuation of adenylate cyclase. In addition to allowing investigations of the regulatory mechanisms of muscarinic receptors, expression models provide an excellent tool to investigate receptor-subtype specific physiology and pharmacology.

Free radicals and phagocytic cells

Abstract: Phagocytes mediate their innate immunological response by releasing products that damage invading microorganisms. These products include proteins such as lysozyme, peroxidases, and elastase as well as reactive oxygen species such as superoxide, hydrogen peroxide, hypohalous acid, and hydroxyl radical. Although it is clear that many phagocytic secretory products have direct cytotoxic potential, understanding is limited of how multiple products interact to generate and modulate the cytotoxic response. This review focuses on recent findings that elucidate the biochemical nature of secretory product interaction in the formation of free radicals, particularly the highly reactive hydroxyl radical. The possible role of these reactions in phagocyte microbicidal activity and inflammatory tissue injury is discussed.

Molecular mechanisms of angiogenesis: fibroblast growth factor signal transduction.

Abstract: The fibroblast growth factors are a family of structurally related polypeptides that are mitogenic for a broad range of cell types as well as mediators of a wide spectrum of developmental and pathophysiological processes in vivo and in vitro. The fibroblast growth factor family presently consists of nine distinct members. Indeed, the FGF prototypes FGF-1 (acidic) and FGF-2 (basic) are well described as modifiers of angiogenesis. The absence of a signal sequence to direct their secretion and their ability to traffic to the nucleus are unique structural features that may be relevant to the regulation of their activities. The FGF receptor family consists of four transmembrane receptor tyrosine kinases. Each of these receptors give rise to multiple isoforms as a result of alternative splicing of their mRNAs. The significance of these multiple isoforms is not fully understood; however it is known that alternative splicing in the extracellular domain of these receptors results in altered ligand binding specificities. In addition, alternative splicing in the cytoplasmic domain results in isoforms with increased oncogenic potential. This review will describe recent insights into the pathways used for the regulation of FGF secretion and cellular trafficking as well as signaling by FGFRs.

The mechanism of acute hypoxic pulmonary vasoconstriction: the tale of two channels.

Abstract: Hypoxia causes constriction in small pulmonary arteries and dilatation in systemic arteries. Hypoxic pulmonary vasoconstriction (HPV) is an important mechanism by which pulmonary blood flow is controlled in the fetus and by which local lung perfusion is matched to ventilation in the adult. HPV reduces the flow of desaturated blood through underventilated areas of lung. Even though many vasoactive substances have been examined as possible mediators of HPV, these appear more likely to be modulators than mediators. Hypoxic contraction has been demonstrated in single pulmonary vascular smooth muscle cells (PVSMC). The ability to sense changes in oxygen tension is observed in PVSMC and type 1 cells of the carotid body. In both cells, hypoxia has been shown to inhibit an outward potassium current, thus causing membrane depolarization and calcium entry through the voltage-dependent calcium channels. In both cells there is evidence to suggest that changes in the redox status of the oxygen-sensitive potassium channel or channels may control current flow, so that the channel is open when oxidized and closed when reduced. The redox status may be determined by the effects of hypoxia on mitochondrial/peroxisomal function or on the activity of an oxidase similar to NAD(P)H oxidase. More studies are needed to precisely define the individual potassium channels responsive to hypoxia and to confirm the gating mechanism. In systemic arteries hypoxia causes an increased current through ATP-dependent potassium channels and vasodilatation, whereas in the pulmonary arteries hypoxia inhibits potassium current and causes vasoconstriction.

Proline motifs in peptides and their biological processing.

Abstract: Many biologically important peptide sequences contain proline. It confers unique conformational constraints on the peptide chain in that the side-chain is cyclized back onto the backbone amide position. Inside an alpha-helix the possibility of making hydrogen bonds to the preceding turn is lost and a kink will be introduced. The conformational restrictions imposed by proline motifs in a peptide chain appear to imply important structural or biological functions as can be deduced from their often remarkably high degree of conservation as found in many proteins and peptides, especially cytokines, growth factors, G-protein-coupled receptors, V3 loops of the HIV envelope glycoprotein gp 120, and neuro- and vasoactive peptides. Only a limited number of peptidases are known to be able to hydrolyze proline adjacent bonds. Their activity is influenced by the isomeric state (cis-trans) as well as the position of proline in the peptide chain. The three proline specific metallo-peptidases (aminopeptidase P, carboxype...

The cell biology of the plasminogen system.

Abstract: The plasminogen system plays a pivotal role in maintaining vascular patency and in cell migration. Binding of plasminogen to surfaces (i.e., fibrin or cells) is of crucial importance in regulating the function of this system. Plasmin(ogen) binds to cells with low affinity and high capacity via its lysine binding sites, which are associated with its kringle domains and recognize carboxy-terminal lysines of cell surface proteins. Upon binding to cellular receptors, plasminogen is more readily activated; bound plasmin has increased enzymatic activity and is protected from inactivation by inhibitors. Plasminogen receptors are modulated by numerous factors, including proteases, steroid hormones, cytokines and the adhesive state of the cells. The apoprotein(a) moiety of lipoprotein(a) is remarkably similar in amino acid sequence to plasminogen. Shared binding sites for lipoprotein(a) and plasmin(ogen) on cell surfaces and in the subendothelial matrix may contribute to the pathogenetic risks associated with elevated levels of lipoprotein(a).

Transcriptional regulation in the yeast GAL gene family: a complex genetic network.

Abstract: Regulation of the GAL structural genes in the yeast Saccharomyces cerevisiae is implemented by the products of GAL-specific (GAL4, GAL80, GAL3) and general (GAL11, SWI1, 2, 3, SNF5, 6, numerous glucose repression) genes. Recent work has 1) yielded significant new insights on the DNA binding and transcription activation/Gal80 protein binding functions of the Gal4 activator protein, 2) described the characterization of purified Gal4 protein-Gal80 protein complexes, 3) deconvoluted the multiple and complex glucose repression pathways acting on GAL genes, 4) suggested a new mechanism for the Gal3 protein-mediated induction of GAL structural gene expression, 5) introduced Gal1 protein, a structural gene product, into the regulation scheme, and 6) extended our already substantial understanding of GAL regulatory gene control. The mechanisms which control structural and regulatory gene expression in the GAL family are compared and GAL structural/regulatory gene chromatin structure is discussed.

Targeted vectors for gene therapy.

Abstract: Successful gene therapy requires not only the identification of an appropriate therapeutic gene for treatment of the disease, but also a delivery system by which that gene can be delivered to the desired cell type both efficiently and accurately. Reductions in accuracy will inevitably also reduce efficiency since fewer particles will be available for delivery to the correct cells if many are sequestered into nontarget cells. In addition, the therapy will have net benefit to the patient only if gene delivery is sufficiently restricted such that normal cells are left unaffected by any detrimental affects of bystander cell transduction. Here we review how currently available delivery systems, both plasmid and viral, can be manipulated to improve their targeting to specific cell types. Currently, targeting is achieved by engineering of the surface components of viruses and liposomes to achieve discrimination at the level of target cell recognition and/or by incorporating transcriptional elements into plasmid or viral genomes such that the therapeutic gene is expressed only in certain target cell types. In addition, we discuss emerging vectors and suggest how gene therapy delivery systems of the future will be composites of the best features of diverse vectors already in use.

Thrombomodulin as a model of molecular mechanisms that modulate protease specificity and function at the vessel surface.

Abstract: The protein C anticoagulant system generates an "on demand" physiologic anticoagulant response. The pathway is initiated when thrombin binds to the endothelial cell thrombin binding protein, thrombomodulin. The complex exhibits dramatically altered macromolecular specificity. It rapidly cleaves the protein C zymogen to form the anticoagulant, activated protein C. Complex formation between thrombin and thrombomodulin also prevents thrombin, the enzyme responsible for clot formation and a potent platelet activator, from being able to clot fibrinogen or to activate platelets. Structural, kinetic, and competition studies suggest that thrombomodulin blocks these clotting reactions by masking the binding sites for fibrinogen and the platelet thrombin receptor. Stimulation of protein C activation appears to occur through conformational changes in the extended binding pocket of thrombin. This prevents repulsive interactions with protein C that exist when the free enzyme attempts to dock with this substrate. In ad...