Putting the pH into phosphatidic acid signaling

Background

Camouflage patterns that hinder detection and/or recognition by antagonists are widely studied in both human and animal contexts. Patterns of contrasting stripes that purportedly degrade an observer's ability to judge the speed and direction of moving prey ('motion dazzle') are, however, rarely investigated. This is despite motion dazzle having been fundamental to the appearance of warships in both world wars and often postulated as the selective agent leading to repeated patterns on many animals (such as zebra and many fish, snake, and invertebrate species). Such patterns often appear conspicuous, suggesting that protection while moving by motion dazzle might impair camouflage when stationary. However, the relationship between motion dazzle and camouflage is unclear because disruptive camouflage relies on high-contrast markings. In this study, we used a computer game with human subjects detecting and capturing either moving or stationary targets with different patterns, in order to provide the first empirical exploration of the interaction of these two protective coloration mechanisms.

Results

Moving targets with stripes were caught significantly less often and missed more often than targets with camouflage patterns. However, when stationary, targets with camouflage markings were captured less often and caused more false detections than those with striped patterns, which were readily detected.

Conclusions

Our study provides the clearest evidence to date that some patterns inhibit the capture of moving targets, but that camouflage and motion dazzle are not complementary strategies. Therefore, the specific coloration that evolves in animals will depend on how the life history and ontogeny of each species influence the trade-off between the costs and benefits of motion dazzle and camouflage.     

Regulation of rat ovarian cell growth and steroid secretion

A cultured rat ovarian cell line (31 A-F(2)) was used to study the effect of growth factors (epidermal growth factor [EGF] and fibroblast growth factor [FGF]), a survival factor (ovarian growth factor [OGF]), a hormone (insulin), and an iron-binding protein (transferring) on cell proliferation and steroid production under defined culture conditions. EGF and insulin were shown to be mitogenic (half-maximal response at 0.12 nM and 0.11 muM, respectively) for 31A-F(2) cells incubated in serum-free medium. EGF induced up to three doublings in the cell population, whereas insulin induced an average of one cell population doubling. FGF, OGF, and transferrin were found not to have any prominent effect on cell division when incubated individually with 31A-F(2) cells in serum-free medium. However, a combination of EGF, OGF, insulin, and transferrin stimulated cell division to the same approximate extent as cells incubated in the presence of 5 percent fetal calf serum. EGF or insulin did not significantly affect total cell cholesterol levels (relative to cells incubated in serum-free medium) when incubated individually with 31A-F(2) cells. However, cell cholesterol levels were increased by the addition of OGF (250 percent), FGF (370 percent), or a combination of insulin and EGF (320 percent). Progesterone secretion from 31A-F(2) cells was enhanced by EGF (25 percent), FGF (80 percent), and insulin (115 percent). However, the addition of a mitogenic mixture of EGF, OGF, insulin, and transferrin suppressed progesterone secretion 150 percent) below that of control cultures. These studies have permitted us to determine that EGF and insulin are mitogenic factors that are required for the growth of 31A-F(2) cells and that OGF and transferrin are positive cofactors that enhance growth. Also, additional data suggest that cholesterol and progesterone production in 31A-F(2) cells can be regulated by peptide growth factors and the hormone insulin.     

Simulation of stent deployment in a realistic human coronary artery

Background  

The process of restenosis after a stenting procedure is related to local biomechanical environment. Arterial wall stresses caused by the interaction of the stent with the vascular wall and possibly stress induced stent strut fracture are two important parameters. The knowledge of these parameters after stent deployment in a patient derived 3D reconstruction of a diseased coronary artery might give insights in the understanding of the process of restenosis.     

Evidence for contractile protein translocation in macrophage spreading, phagocytosis, and phagolysosome formation

Macrophage pseudopodia that surround objects during phagocytosis contain a meshwork of actin filaments and exclude organelles. Between these pseudopodia at the base of developing phagosomes, the organelle exclusion ceases, and lysosomes enter the cell periphery to fuse with the phagosomes. Macrophages also extend hyaline pseudopodia on the surface of nylon wool fibers and secrete lysosomal enzymes into the extracellular medium instead of into phagosomes. To analyze biochemically these concurrent alterations in cytoplasmic architecture, we allowed rabbit lung macrophages to spread on nylon wool fibers and then subjected the adherent cells to shear. This procedure caused the selective release of β-glucoronidase into the extracellular medium and yielded two fractions, cell bodies and isolated pseudopod blebs resembling podosomes, which are plasma-lemma-bounded sacs of cortical cytoplasm. Cytoplasmic extracts of the cell bodies eluted from nylon fibers contained two-thirds less actin-binding protein and myosin, and approximately 20 percent less actin and two-thirds of the other two proteins were accounted for in podosomes. The alterations in protein composition correlated with assays of myosin-associated EDTA-activated adenosine triphosphatase activity, and with a diminution in the capacity of extracts of nylon wool fiber-treated cell bodies to gel, a property dependent on the interaction between actin-binding protein and F-actin. However, the capacity of the remaining actin in cell bodies to polymerize did not change. We propose that actin-binding protein and myosin are concentrated in the cell cortex and particularly in pseudopodia where prominent gelation and syneresis of actin occur. Actin in the regions from which actin-binding protein and myosin are displaced disaggregates without depolymerizing, permitting lysosomes to gain access to the plasmalemma. Translocation of contractile proteins could therefore account for the concomitant differences in organelle exclusion that characterize phagocytosis.     

The pH dependence of intramolecular electron transfer rates in sulfite oxidase at high and low anion concentrations

 The individual rate constants for intramolecular electron transfer (IET) between the Mo^VIFe^II and Mo^VFe^III forms of chicken liver sulfite oxidase (SO) have been determined at a variety of pH values, and at high and low anion concentrations. Large anions such as EDTA do not inhibit IET as dramatically as do small anions such as SO₄ ^2– and Cl^–, which suggests that specific anion binding at the sterically constrained Mo active site is necessary for IET inhibition to occur.IET may require that SO adopt a conformation in which the Mo and Fe centers are held in close proximity by electrostatic interactions between the predominantly positively charged Mo active site, and the negatively charged heme edge. Thus, small anions which can fit into the Mo active site will weaken this electrostatic attraction and disfavor IET. The rate constant for IET from Fe^II to Mo^VI decreases with increasing pH, both in the presence and absence of 50 mM SO₄ ^2–. However, the rate constant for the reverse process exhibits no significant pH dependence in the absence of SO₄ ^2–, and increases with pH in the presence of 50 mM SO₄ ^2–. This behavior is consistent with a mechanism in which IET from Mo^V to Fe^III is coupled to proton transfer from Mo^V–OH to OH^–, and the reverse IET process is coupled to proton transfer from H₂O to Mo^VI=O. At high concentrations of small anions, direct access of H₂O or OH^–to the Mo-OH will be blocked, which provides a second possible mechanism for inhibition of IET by such anions. Inhibition by anions is not strictly competitive, however, and Tyr322 may play an important intermediary role in transferring the proton when an anion blocks direct access of H₂O or OH^– to the Mo-OH. Competing H-bonding interactions of the Mo-OH moiety with Tyr322 and with the anion occupying the active site may also be responsible for the well-known equilibrium between two EPR-distinct forms of SO that is observed for the two-electron reduced enzyme. Received: 21 December 1998 / Accepted: 6 April 1999     

Higher‐order assemblies of oligomeric cargo receptor complexes form the membrane scaffold of the Cvt vesicle

Selective autophagy is the mechanism by which large cargos are specifically sequestered for degradation. The structural details of cargo and receptor assembly giving rise to autophagic vesicles remain to be elucidated. We utilize the yeast cytoplasm‐to‐vacuole targeting (Cvt) pathway, a prototype of selective autophagy, together with a multi‐scale analysis approach to study the molecular structure of Cvt vesicles. We report the oligomeric nature of the major Cvt cargo Ape1 with a combined 2.8 Å X‐ray and negative stain EM structure, as well as the secondary cargo Ams1 with a 6.3 Å cryo‐EM structure. We show that the major dodecameric cargo prApe1 exhibits a tendency to form higher‐order chain structures that are broken upon interaction with the receptor Atg19 in vitro. The stoichiometry of these cargo–receptor complexes is key to maintaining the size of the Cvt aggregate in vivo. Using correlative light and electron microscopy, we further visualize key stages of Cvt vesicle biogenesis. Our findings suggest that Atg19 interaction limits Ape1 aggregate size while serving as a vehicle for vacuolar delivery of tetrameric Ams1.     

Intramolecular electron transfer in sulfite-oxidizing enzymes: probing the role of aromatic amino acids

Sulfite oxidase (SO) is a molybdoheme enzyme that is important in sulfur catabolism, and mutations in the active site region are known to cause SO deficiency disorder in humans. This investigation probes the effects that mutating aromatic residues (Y273, W338, and H337) in the molybdenum-containing domain of human SO have on both the intramolecular electron transfer (IET) rate between the molybdenum and iron centers using laser flash photolysis and on catalytic turnover via steady-state kinetic analysis. The W338 and H337 mutants show large decreases in their IET rate constants (k _ET) relative to the wild-type values, suggesting the importance of these residues for rapid IET. In contrast, these mutants are catalytically competent and exhibit higher k _cat values than their corresponding k _ET, implying that these two processes involve different conformational states of the protein. Redox potential investigations using spectroelectrochemistry revealed that these aromatic residues close to the molybdenum center affect the potential of the presumably distant heme center in the resting state (as shown by the crystal structure of chicken SO), suggesting that the heme may be interacting with these residues during IET and/or catalytic turnover. These combined results suggest that in solution human SO may adopt different conformations for IET and for catalysis in the presence of the substrate. For IET the H337/W338 surface residues may serve as an alternative-docking site for the heme domain. The similarities between the mutant and wild-type EPR spectra indicate that the active site geometry around the Mo(V) center is not changed by the mutations studied here.     

Cryptosporidium suis n. sp. (Apicomplexa: Cryptosporidiidae) in pigs (Sus scrofa)

Molecular and biological characteristics of a new species of Cryptosporidium from the feces of pigs (Sus scrofa) is described. Oocysts are structurally indistinguishable from those of Cryptosporidium parvum; they are passed fully sporulated, lack sporocysts, and measure 4.9-4.4 microm (mean = 4.6 microm) x 4.0-4.3 microm (mean = 4.2 microm); length to width ratio 1.1 (n = 50). Cryptosporidium suis is not transmissible to nude mice and is poorly infectious for cattle. Molecular and phylogenetic analyses at the 18S ribosomal RNA, heat shock protein 70, and actin gene loci demonstrate C. suis to be genetically distinct from all known species and genotypes of Cryptosporidium, and thus is named as Cryptosporidium suis.     

The coordination chemistry and function of the molybdenum centres of the oxomolybdoenzymes

 The nature of the catalytic centres of the oxomolybdoenzymes is considered with particular reference to the results of recent protein crystallographic studies. The different nature of these centres, with one or two molecules of a special pyranopterin (molybdopterin) ligating the metal through a dithiolene group, the presence or absence of a nucleotide appended to the phosphate of the molybdopterin AND the variation in the coordination chemistry at the metal render the term "THE molybdenum cofactor" meaningless and confusing. Rather, there is a series of such cofactors, related by the common denominators of a single molybdenum atom bound to the dithiolene group of the molybdopterin and, at some stage in the catalytic cycle, at least one terminal oxo group. This Mo(O)(molybdopterin) moiety is considered to be the metal-centred functional unit (McFU) of the oxomolybdoenzymes. Variations in the coordination chemistry and, therefore, the properties of the metal centre occur with the binding of other ligands, which can include: a terminal oxo or sulfido group, OH^– and/or H₂O group(s), a second pterin, and/or a serine, a cysteine or selenocysteine group from the polypeptide backbone of the protein. The role of molybdopterin is considered with particular reference to its potential involvement in the various redox processes necessary for the operation of the catalytic cycles of these enzymes; special attention is given to the possible cooperativity between formally metal-based and pterin-based redox processes. Received: 17 June 1997 / Accepted: 20 August 1997