Crystallization of a covalently-linked complex of adrenodoxin and adrenodoxin reductase

Two forms of mitochondrial adrenodoxin reductase from bovine adrenals and recombinant bovine adrenodoxin and adrenodoxin reductase expressed in Escherichia coli were isolated, purified to homogeneity and biochemically characterized. Recombinant adrenodoxin reductase was expressed as a single polypeptide; its retention time on DEAE-Fractogel coincides with the second form (F2) of the mitochondrial reductase. Two enzyme forms have similar adrenodoxin reductase activities in two types of systems comprising either cytochrome c or cytochrome P-450 (11 beta) as the terminal electron acceptor. Adrenodoxin and each of two reductase forms were cross-linked using 1-ethyl-3-(dimethyl-amino-propyl)carbodiimide. An effective two-step method for the purification of the active heterologous cross-linked complexes is suggested that enables purification of the functional complexes to homogeneity. The cross-linked bimolecular complex of adrenodoxin and adrenodoxin reductase was crystallized for the first time.     

Contribution of human hepatic cytochrome P450 isoforms to regioselective hydroxylation of steroid hormones

Biopsy specimens of the skin and oral mucosa from twenty-five patients bearing the disseminated form of histoplasmosis (H. capsulatum) associated with AIDS (acquired immunodeficiency syndrome) were studied by histologic and immunohistochemistry techniques. Histologically, the skin lesions showed four different patterns: diffuse macrophage, granulomatous, vasculitic with leukocytoclastic and scarce inflammatory reaction. The cell markers for macrophages, lymphocytes B and T and H. capsulatum revealed CD68, UCHL-1 and L26 associated with variable amounts of fungi.     

Effect of replacing a conserved proline residue on the function and stability of bovine adrenodoxin

A proline residue in the C-terminal part of the polypeptide chain is highly conserved among many [2Fe-2S] ferredoxins. To investigate the requirement for proline at this position, we constructed steric (4-108W), charged (4-108K), polar (4-108S) and non-polar (4-108A) truncated mutants of adrenodoxin and studied them for biological function and stability. Although the variants were expressed in Escherichia coli with a significantly lower yield compared with wild-type adrenodoxin, successful incorporation of the iron-sulfur cluster suggested their proper folding. Similar absorption, CD and EPR spectra indicated that the cluster environment was not affected by the mutations. No evidence for an essential role of Pro108 in determining the redox potential of adrenodoxin or its interactions with the redox partners was found. However, replacement of this residue results in a dramatic decrease in the overall protein stability. The differences in the Gibbs energy of unfolding at 37 degrees C, delta[delta(d)G(37 degrees C)], are -5.0, -7.8, -10.1 and -10.7 kJ/mol for 4-108A, 4-108S, 4-108W and 4-108K mutants, respectively, compared with 4-108P as a control. We conclude that the principle function of Pro108 is to stabilize adrenodoxin threefold: (i) through limitation of the conformation of the polypeptide chain in this region, (ii) through a hydrogen bond to Arg14 and (iii) favorable hydrophobic contacts.     

Effect of total gamma-irradiation on the rate of steroid hormone hydroxylation by rat liver microsomes

gamma-irradiation in doses of over 600 r proved to decrease the rate of androgen hydroxylation significantly; the rate of hydroxylation of the estrogens under study altered but little. Under the mentioned irradiation conditions the content of cytochrome P-450 in rat hepatic microsomes diminished. A reduction of the hydroxylation rate of steroid hormones by rat hepatic microsomes under the effect of total gamma-irradiation apparently depended on the qualitative changes of cytochrome P-450.     

Structure and mechanism of action and inhibition of steroid dehydrogenase enzymes involved in hypertension

Members of the NADPH-dependent short chain dehydrogenase/reductase (SDR) family control blood pressure, fertility, and natural and neoplastic growth. Despite the fact that only one amino acid residue is strictly conserved in the 100 known members of the family, all appear to have a dinucleotide-binding Rossmann fold and homologous catalytic residues including the conserved tyrosine. Variation in the binding pocket creates specificity for steroids, prostaglandins, sugars and alcohols. The critically important tyrosine appears to maintain a fixed position relative to the scaffolding of the Rossmann fold and the cofactor position, while the substrate-binding pocket alters in such a way that the dehydrogenation/reduction reaction site is brought into bonding distance of the tyrosine hydroxyl group. Licorice induces high blood pressure by inhibiting an SDR in the kidney. The crystal structure of the complex of 3alpha,20beta-hydroxysteroid dehydrogenase and carbenoxolone reveals the mechanism of enzyme inhibition by licorice. The most potent dehydrogenase enzyme inhibitors are those that displace substrate and cofactor and form strong hydrogen bonds to one or more amino acid residues involved in catalysis.     

Structure and function of fibronectin modules

Fibronectin is an important component of the extracellular matrix and is involved in a diverse range of physiological processes. It is a mosaic protein composed almost entirely of three types of module, F1, F2 and F3. Although the structures of single F1, F2 and F3 modules have been available for a number of years, in many cases the key to understanding the structure-function relationships in fibronectin and other proteins containing these modules lies in studies of module pairs and larger domains. This review focuses on recent advances in the understanding of the structure and function of fibronectin modules.     

Mutational analysis of Mdm1p function in nuclear and mitochondrial inheritance

Nuclear and mitochondrial transmission to daughter buds of Saccharomyces cerevisiae depends on Mdm1p, an intermediate filament-like protein localized to numerous punctate structures distributed throughout the yeast cell cytoplasm. These structures disappear and organelle inheritance is disrupted when mdm1 mutant cells are incubated at the restrictive temperature. To characterize further the function of Mdm1p, new mutant mdm1 alleles that confer temperature-sensitive growth and defects in organelle inheritance but produce stable Mdm1p structures were isolated. Microscopic analysis of the new mdm1 mutants revealed three phenotypic classes: Class I mutants showed defects in both mitochondrial and nuclear transmission; Class II alleles displayed defective mitochondrial inheritance but had no effect on nuclear movement; and Class III mutants showed aberrant nuclear inheritance but normal mitochondrial distribution. Class I and II mutants also exhibited altered mitochondrial morphology, possessing primarily small, round mitochondria instead of the extended tubular structures found in wild-type cells. Mutant mdm1 alleles affecting nuclear transmission were of two types: Class Ia and IIIa mutants were deficient for nuclear movement into daughter buds, while Class Ib and IIIb mutants displayed a complete transfer of all nuclear DNA into buds. The mutations defining all three allelic classes mapped to two distinct domains within the Mdm1p protein. Genetic crosses of yeast strains containing different mdm1 alleles revealed complex genetic interactions including intragenic suppression, synthetic phenotypes, and intragenic complementation. These results support a model of Mdm1p function in which a network comprised of multimeric assemblies of the protein mediates two distinct cellular processes.     

Structure and function of symporter and antiporter

Structure and function of symporters and antiporters which utilize Na+ as the coupling cation are briefly reviewed. The SGLT is an Na+/glucose symporter present in animal cell membranes. So far, five isoforms of the SGLT (1 to 5) have been found in various tissues. The Me1B is an Na+/galactoside symporter present in membranes of enteric bacteria. Regions or amino acid residues of these symporters which are important for substrate recognition or cation recognition have been identified. Furthermore amino acid substitutions in the SGLT1 of glucose-galactose malabsortion families have been identified. Regions and amino acid residues which are important for the function of the Na+/H+ antiporters (or exchangers) which extrude H+ (in animal cells) or Na+ (in bacterial cells) have been also identified.     

Synaptic physiology and mitochondrial function in crayfish tonic and phasic motor neurons

Phasic and tonic motor neurons of crustaceans differ strikingly in their junctional synaptic physiology. Tonic neurons generally produce small excitatory postsynaptic potentials (EPSPs) that facilitate strongly as stimulation frequency is increased, and normally show no synaptic depression. In contrast, phasic neurons produce relatively large EPSPs with weak frequency facilitation and pronounced depression. We addressed the hypothesis that mitochondrial function is an important determinant of the features of synaptic transmission in these neurons. Mitochondrial fluorescence was measured with confocal microscopy in phasic and tonic axons and terminals of abdominal and leg muscles after exposure to supravital mitochondrial fluorochromes, rhodamine-123 (Rh123) and 4-diethylaminostyryl-N-methylpyridinium iodide (4-Di-2-Asp). Mitochondria of tonic axons and neuromuscular junctions had significantly higher mean Rh123 and 4-Di-2-Asp fluorescence than in phasic neurons, indicating more accumulation of the fluorochromes. Mitochondrial membrane potential, which is responsible for Rh123 uptake and is related to mitochondrial oxidative activity (the production of ATP by oxidation of metabolic substrates), is likely higher in tonic axons. Electron microscopy showed that tonic axons contain approximately fivefold more mitochondria per microm2 cross-sectional area than phasic axons. Neuromuscular junctions of tonic axons also have a much higher mitochondrial content than those of phasic axons. We tested the hypothesis that synaptic fatigue resistance is dependent on mitochondrial function in crayfish motor axons. Impairment of mitochondrial function by uncouplers of oxidative phosphorylation, dinitrophenol or carbonyl cyanide m-chlorophenylhydrazone, or by the electron transport inhibitor sodium azide, led to marked synaptic depression of a tonic axon and accelerated depression of a phasic axon during maintained stimulation. Iodoacetate, an inhibitor of glycolysis, and chloramphenicol, a mitochondrial protein synthesis inhibitor, had no significant effects on either mitochondrial fluorescence or synaptic depression in tonic or phasic axons. Collectively, the results provide evidence that mitochondrial oxidative metabolism is important for sustaining synaptic transmission during maintained stimulation of tonic and phasic motor neurons. Tonic neurons have a higher mitochondrial content and greater oxidative activity; these features are correlated with their greater resistance to synaptic depression. Conversely, phasic neurons have a lower mitochondrial content, less oxidative activity, and greater synaptic fatigability.     

Regulation and function of steroid production by mid gestation ovine fetal adrenal cortex in vivo

By mid-gestation (75-85 days, term=150 days), the ovine fetal adrenal gland is zoned into cortex and medulla. The cortex has an outer layer of cells which have the morphological characteristics of zona glomerulosa cells, containing mitochondria with lamellar cristae. It has been reported that cultured adrenal cells from mid-gestation bovine and ovine fetuses can be stimulated to increase aldosterone production, ten fold, by angiotensin II, and that this can be maintained for at least 3 days. However, the situation in vivo is unknown. In the current report we show that in chronically cannulated ovine fetuses at mid-gestation, angiotensin II (1 microg/h) does not increase aldosterone either in the short term (3 hours) or long term (3 days). However, ACTH (450 ng/h) can increase plasma aldosterone in the short but not long term. ACTH at this dose produces progressive and large increases in cortisol production. Angiotensin II is pressor and produces a modest diuresis without stimulating cortisol.     

Heated humidifiers. Structure and function

Humidity in the form of molecular water vapor is an essential requirement for intubated patients, and can be beneficial to nonintubated patients receiving CPAP or oxygen therapy. There are many different types of humidification devices but they generally consist of a humidity generator (or water reservoir) and humidity delivery system (or breathing circuit). Humidifiers that generate aerosols may provide adequate humidity, but they also provide a transport mechanism for contaminants and may deliver excess water to the airways. An ideal system generates the required amount of humidity, in the form of water vapor, at the correct temperature, and transports it to the patient without the loss of either heat or moisture. The most effective way to achieve this is to use a large heated water surface for the generator, and heating elements within the delivery system to prevent condensation. This system can be configured to provide optimal humidity for both intubated and nonintubated patients from the neonatal to the adult intensive care unit. Heated humidifiers have no contraindications and can be used on any patient requiring ventilatory assistance or supplemental oxygen.     

Structure and function of phosphoinositide 3-kinases

Phosphoinositide kinases (PI3Ks) play an important role in mitogenic signaling and cell survival, cytoskeletal remodeling, metabolic control and vesicular trafficking. Here we summarize the structure-function relationships delineating the activation process of class I PI3Ks involving various domains of adapter subunits, Ras, and interacting proteins. The resulting product, PtdIns(3,4,5)P3, targets Akt/protein kinase B (PKB), Bruton's tyrosine kinase (Btk), phosphoinositide-dependent kinases (PDK), integrin-linked kinase (ILK), atypical protein kinases C (PKC), phospholipase Cgamma and more. Surface receptor-activated PI3Ks function in mammals, insects, nematodes and slime mold, but not yeast. While many members of the class II family have been identified and characterized biochemically, it is presently unknown how these C2-domain containing PI3Ks are activated, and which PI substrate they phosphorylate in vivo. PtdIns 3-P is produced by Vps34p/class III PI3Ks and operates via the PtdIns 3-P-binding proteins early endosomal antigen (EEA1), yeast Vac1p, Vps27p, Pip1p in lysosomal protein targeting. Besides the production of D3 phosphorylated lipids, PI3Ks have an intrinsic protein kinase activity. For trimeric GTP-binding protein-activated PI3Kgamma, protein kinase activity seems to be sufficient to trigger mitogen-activated protein kinase (MAPK). Recent disruption of PI3K genes in slime mold, Caenorhabditis elegans, Drosophila melanogaster and mice further underlines the importance of PI3K signaling systems and elucidates the role of PI3K signaling in multicellular organisms.     

Structure and function of 6,7-dicarboxyheme-substituted myoglobin

Myoglobin was reconstituted with 6,7-dicarboxy-1,2,3,4,5, 8-hexamethylheme, a compact synthetic heme with the shortest acid side chains, to pursue the structural and functional consequences after intensive disruption of the heme propionate-apoglobin linkages in the native protein. The electron-withdrawing carboxylate groups directly attached to the porphyrin ring lowered the oxygen affinity by 3-fold as compared with native myoglobin. Autoxidation of the oxy derivative to the ferric protein proceeded with 1.6 x 10(-)2 min-1 at pH 7.0 and 30 degrees C. The crystallographic structure of the cyanomet myoglobin with 1.9 A resolution shows that the heme adopts a unique orientation in the protein pocket to extend the two carboxylates toward solvent sphere. The native globin fold is conserved, and the conformations of globin side chains are almost intact except for those located nearby the heme 6,7-carboxylates. The 7-carboxylate only weakly interacts with Ser92 and His97 through two mediating water molecules. The 6-carboxylate, on the other hand, forms a novel salt bridge with Arg45 owing to conformational flexibility of the guanidinium side chain. The proton NMR shows that the small heme does not fluctuate about the iron-histidine bond even at 55 degreesC, suggesting that the salt bridge between Arg45 and heme 6-carboxylate is of critical importance to recognize and fix the heme in myoglobin.