Ca2+-dependent structural changes in bovine blood coagulation factor Va and its subunits

The calcium dependence of the structures of bovine blood coagulation factor Va and its subunits (Vh and Vl) has been examined spectroscopically in order to characterize the conformational changes which accompany the binding of Ca2+ to Vh and Vl to form factor Va. The far-UV CD spectra of the isolated subunits indicate that the secondary structures of both Vh and Vl are predominantly beta-sheet (greater than 45%), with little alpha-helix content (less than 15%). No change in the far-UV CD spectrum was observed when factor Va was formed by the addition of Ca2+ to an equimolar mixture of Vl and Vh. Hence, no detectable change in secondary structure occurs during the formation of factor Va. In contrast, the addition of Ca2+ to an equimolar mixture of Vh and Vl caused a small (2%) increase in the total intrinsic fluorescence intensity and a blue shift in the emission spectrum that resulted from a tertiary structural change and/or the association of nonpolar surfaces at the subunit interface. This fluorescence change correlated closely with the appearance of functional factor Va, since the rate of the spectral change was the same as the rate of recovery of cofactor activity, and since both were half-maximal near 50 microM Ca2+. This fluorescence change required both subunits, was reversed by the addition of EDTA, and was observed only with metal ions that can substitute for Ca2+ in reconstituting factor Va activity from Vh and Vl (Mn2+ and Tb3+; not Mg2+). When a sample containing ANS (8-anilino-1-naphthalenesulfonate) and an equimolar mixture of calcium-free Vh and Vl was titrated with Ca2+, the ANS emission intensity decreased by about 30%, most likely because the association of Vl and Vh caused nonpolar regions at the subunit-subunit interface to become inaccessible for ANS binding. The calcium dependence of this spectral change yielded a Kd of 51 +/- 2 microM, and the rate of the decrease in ANS fluorescence occurred at nearly the same rate as the recovery of factor Va activity. Thus, both intrinsic and extrinsic fluorescence data, as well as other data, indicate that the calcium binding site in factor Va has an apparent Kd of 50 microM under our conditions and that the calcium-mediated binding between Vl and Vh involves hydrophobic interactions between the subunits.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cardiorespiratory changes during HCl infusion unrelated to decreases in circulating blood pH

To test the hypothesis that infusion of HCl changes blood pressure and respiration independent of decreases in circulating blood pH, an extracorporeal arteriovenous shunt (20 ml/min) between the femoral artery and vein was installed in anesthetized cats. Into this loop, acid (0.25 M HCl) and, approximately 10 cm downstream, base (0.25 M NaOH) could be infused simultaneously. Likewise, either acid or base could be infused individually. Right ventricular (Prv) and arterial (Pa) blood pressure, tidal volume (VT), and respiratory frequency (fresp) were recorded as well as blood gases and pH in arterial, right ventricular, and shunt loop blood at the reentrance into the animal. When HCl and NaOH were infused simultaneously and at equimolar rates (0.2 mmol/min for 10 min), there was a large increase in Prv, with little change or decrease in Pa. Respiratory frequency was increased, but total ventilation was not elevated because of a concomitant fall in VT. The rise in Prv and increase in fresp were transient in that they could only be evoked during the first HCl-NaOH infusion in a given animal. Repetitive infusions of HCl-NaOH into the same animal failed to elicit the response. Similar transient acid effects were evoked when HCl was infused without NaOH but not when NaOH was infused without HCl. During the second and third infusion of HCl, ventilatory responses were elicited that were explainable by stimulation of known chemoreceptors. The transient rise in Prv and fresp evoked by acid infusion might be explained by release of an agent from blood elements at the tip of the HCl infusion catheter, which in turn would constrict pulmonary vessels and influence breathing.(ABSTRACT TRUNCATED AT 250 WORDS)     

Adenovirus binding to the coxsackievirus and adenovirus receptor or integrins is not required to elicit brain inflammation but is necessary to transduce specific neural cell types

Intracranial administration of adenovirus vectors elicits rapid, capsid-mediated dose-dependent brain inflammation. The mechanisms through which adenovirus capsids trigger inflammation in the brain remain unknown. We determined whether adenovirus interaction with the primary and secondary cell surface receptors for infection (CAR and alphav integrins) was necessary to trigger acute adenovirus-mediated brain inflammation, and, furthermore, whether capsid mutations that abrogated CAR and integrin binding altered vector tropism in the brain. Vectors ablated for CAR binding, but retaining integrin binding function, transduced equivalent areas of brain compared to vectors with wild-type capsids; however, vector tropsim was dramatically altered. Vectors with wild-type capsids predominantly transduced oligodendrocytes, whereas mutation of the fiber protein to ablate CAR binding resulted in a loss of oligodendrocyte transduction and a consequent redirection of transduction to neurons and other types of glial cells. Combined mutations of fiber and penton base that ablate both CAR and integrin binding almost abolished brain transduction. Thus, doubly-ablated capsids engineered to express new ligands should allow complete vector retargeting in the central nervous system. Although transduction by the doubly-ablated vectors was reduced by greater than 95%, inflammation was not reduced compared to wild-type vectors, demonstrating that brain inflammation occurs independently of adenovirus binding and infection of cells via CAR and integrin receptors.     

Elongating RNA polymerase II is disassembled through specific degradation of its largest but not other subunits in response to DNA damage in vivo

Although previous biochemical studies have demonstrated global degradation of the largest subunit, Rpb1p, of RNA polymerase II in response to DNA damage, it is still not clear whether the initiating or elongating form of Rpb1p is targeted for degradation in vivo. Further, whether other components of RNA polymerase II are degraded in response to DNA damage remains unknown. Here, we show that the Rpb1p subunit of the elongating, but not initiating, form of RNA polymerase II is degraded at the active genes in response to 4-nitroquinoline-1-oxide-induced DNA damage in Saccharomyces cerevisiae. However, other subunits of RNA polymerase II are not degraded in response to DNA damage. Further, we show that Rpb1p is essential for RNA polymerase II assembly at the active gene, and thus, the degradation of Rpb1p following DNA damage disassembles elongating RNA polymerase II. Taken together, our data demonstrate that Rpb1p but not other subunits of elongating RNA polymerase II is specifically degraded in response to DNA damage, and such a degradation of Rpb1p is critical for the disassembly of elongating RNA polymerase II at the DNA lesion in vivo.     

Control of glycogen synthase and phosphorylase by insulin in rat adipocytes which is unrelated to the concentration of cyclic AMP

Incubation of adipocytes in glucose-free medium with adrenocorticotrophic hormone, epinephrine, isoproterenol, or norepinephrine increased the concentration of cyclic AMP and the percentage of phosphorylase a activity, and decreased the percentage of glycogen synthase I activity. Glucose was essentially without effect on glycogen synthase or phosphorylase in either the presence or absence of epinephrine. Although glucose potentiated the action of insulin to activate glycogen synthase, the hexose did not enhance the effectiveness of insulin in the presence of epinephrine. Likewise, glucose did not increase the ability of insulin to oppose the activation of phosphorylase by epinephrine.The activation of glycogen synthase by insulin was not associated with a decrease in the concentration of cyclic AMP. Insulin partially blocked the rise in cyclic AMP due to isoproterenol, adrenocorticotrophic hormone, and norepinephrine. The maximum effects of isoproterenol on glycogen synthase and phosphorylase were observed when the concentration of cyclic AMP was increased twofold. However, insulin clearly opposed the changes in enzyme activity produced by isoproterenol (and also adrenocorticotrophic hormone, epinephrine and norepinephrine) even though concentrations of cyclic AMP were still increased three- to fourfold. Nicotinic acid opposed the increases in cyclic AMP due to adrenocorticotrophic hormone, isoproterenol and norepinephrine to the same extent as insulin; however, nicotinic acid was ineffective in opposing the activation of phosphorylase and inactivation of glycogen synthase produced by these agents. Thus, it is unlikely that the effects of insulin on glycogen synthase and phosphorylase result from an action of the hormone to decrease the concentration of cyclic AMP.     

Mammary gland morphogenesis is enhanced by exposure to flaxseed or its major lignan during suckling in rats

The exposure of rats to 10% flaxseed (FS) or an equivalent level of its major lignan, secoisolariciresinol diglucoside (SDG), during suckling enhances mammary gland differentiation, which protects against mammary carcinogenesis at adulthood. We determined whether this diet-induced mammary gland differentiation is mediated through the estrogenic pathway via epidermal growth factor receptor (EGFR) and estrogen receptor (ER) signaling. Rats were fed the AIN-93G basal diet (BD) from day 7 of pregnancy until delivery and then randomized to consume BD, FS, or SDG during lactation. After weaning, female offspring were fed BD throughout the experiment. At postnatal day (PND) 21 and the proestrus phase on PND 49-51, mammary glands of offspring were analyzed for morphology, cell proliferation, and expression of EGFR, epidermal growth factor (EGF), transforming growth factor-alpha, ER-alpha, and ER-beta. At PND 21, compared with the BD control, the number of terminal end buds (TEBs) and terminal ducts were increased by FS, whereas mammary epithelial cell proliferation was increased by both FS and SDG, suggesting that mammary morphogenesis was enhanced. Epithelial EGFR and stromal fibroblast EGF were increased by SDG, whereas epithelial ER-beta was decreased by FS. Conversely, at PND 49-51, a lower number of TEBs but a higher ratio of lobules to TEBs with decreased expression of EGFR or EGF was observed in both treatment groups. EGFR expression was positively associated with EGF expression and cell proliferation in TEB epithelium at PND 21. Urinary lignans of lactating dams were related to their offspring's indices of mammary gland development. In conclusion, exposure to FS or SDG during suckling enhanced mammary gland morphogenesis by modulation of EGFR and ER signaling, which led to more differentiated mammary glands at PND 49-51. The physiological outcomes of FS and SDG were similar, which suggests that SDG is partly responsible for the mammary gland differentiation effect.     

Highly diverse and spatially heterogeneous mycorrhizal symbiosis in a rare epiphyte is unrelated to broad biogeographic or environmental features

Symbiotic interactions are common in nature. In dynamic or degraded environments, the ability to associate with multiple partners (i.e. broad specificity) may enable species to persist through fluctuations in the availability of any particular partner. Understanding how species interactions vary across landscapes is necessary to anticipate direct and indirect consequences of environmental degradation on species conservation. We asked whether mycorrhizal symbiosis by populations of a rare epiphytic orchid (Epidendrum firmum) is related to geographic or environmental heterogeneity. The latter would suggest that interactions are governed by environmental conditions rather than historic isolation of populations and/or mycorrhizal fungi. We used DNA-based methods to identify mycorrhizal fungi from eleven E. firmum populations in Costa Rica. We used molecular and phylogenetic analyses to compare associations. Epidendrum firmum exhibited broad specificity, associating with diverse mycorrhizal fungi, including six Tulasnellaceae molecular operational taxonomic units (MOTUs), five Sebacinales MOTUs and others. Notably, diverse mycorrhizal symbioses formed in disturbed pasture and roadside habitats. Mycorrhizal fungi exhibited significant similarity within populations (spatial and phylogenetic autocorrelation) and significant differences among populations (phylogenetic community dissimilarity). However, mycorrhizal symbioses were not significantly associated with biogeographic or environmental features. Such unexpected heterogeneity among populations may result from complex combinations of fine-scale environmental factors and macro-evolutionary patterns of change in mycorrhizal specificity. Thus, E. firmum exhibits broad specificity and the potential for opportunistic associations with diverse fungi. We suggest that these characteristics could confer symbiotic assurance when mycorrhizal fungi are stochastically available, which may be crucial in dynamic or disturbed habitats such as tropical forest canopies.     

The lipid-mobilizing effect of atrial natriuretic peptide is unrelated to sympathetic nervous system activation or obesity in young men

We recently demonstrated that natriuretic peptides and especially the atrial natriuretic peptide (ANP) are powerful lipolytic agents on isolated human fat cells. To search for a possible influence of obesity on ANP responsiveness, we compared the lipolytic effects of human ANP (h-ANP) on isolated subcutaneous abdominal adipose tissue (SCAAT) fat cells from young healthy lean and obese men. The lipid-mobilizing effects of an intravenous infusion of h-ANP was studied, as well as various metabolic and cardiovascular parameters that were compared in the same subjects. h-ANP (50 ng/min/kg) was infused iv for 60 min. Microdialysis probes were inserted in SCAAT to measure modifications of the extracellular glycerol concentrations during h-ANP infusion. Spectral analysis of blood pressure and heart rate oscillations that were recorded using digital photoplethysmography were used to assess changes in autonomic nervous system activity. h-ANP induced a marked and similar increase in glycerol and nonesterified fatty acids, and a weak increase in insulin plasma levels in lean and obese men. Plasma norepinephrine concentrations rose similarly during h-ANP infusion in lean and obese men. The effects of h-ANP infusion on the autonomic nervous system were similar in both groups, with an increase in the spectral energy of the low-frequency band of systolic blood pressure variability and a decrease in the spectral energy of the high-frequency band of heart rate. In SCAAT, h-ANP infusion increased extracellular glycerol concentration and decreased blood flow similarly in both groups. The increase in extracellular glycerol observed during h-ANP infusion was not modified when 0.1 mM propranolol was added to the microdialysis probe perfusate to prevent beta-adrenoceptor activation. These data show that ANP is a potent lipolytic hormone independent of the activation of the sympathetic nervous system, and that obesity did not modify the lipid-mobilizing effect of ANP in young obese subjects.     

Curtailed respiration by repeated vs. isolated hypoxia in maturing piglets is unrelated to NTS ME or SP levels

Waters, Karen A., André Laferrière, JuliePaquette, Cynthia Goodyer, and Immanuela R. Moss. Curtailedrespiration by repeated vs. isolated hypoxia in maturing piglets isunrelated to NTS ME or SP levels. J. Appl.Physiol. 83(2): 522-529, 1997.In earlydevelopment, respiratory disorders can produce recurring hypoxicepisodes during sleep. To examine possible effects of daily repeatedvs. isolated hypoxic hypoxia, cardiorespiratory functions and central,respiratory-related neuromodulator levels in 21- to 32-day-old,chronically instrumented, unsedated piglets were compared between afifth sequential daily hypoxia and an isolated hypoxia (10%O₂-90%N₂ for 30 min). Diaphragmaticelectromyographic activity, heart rate and arterial pressure, and pHand gas tensions were measured. In vivo microdialysis, via chronicallyimplanted guides, served to sample interstitial substance P (SP) andmethionine-enkephalin (ME) at the level of the respiratory-relatednucleus tractus solitarii (NTS). Compared with an isolated hypoxia,repeated hypoxia resulted in 1)lower respiratory frequency (f), ventilation equivalent, and arterialpH, higher arterial PO₂during hypoxia, and lower f in recovery from hypoxia; and2) increased SP concentrations butno change in ME concentrations. We conclude that, in these maturingswine, repeated vs. isolated hypoxic exposure curtails respiratoryresponses to hypoxia by a mechanism(s) unrelated to SP or ME levels atthe NTS.

     

Histidine-272 of isopenicillin N synthase of Cephalosporium acremonium, which is possibly involved in iron binding, is essential for its catalytic activity

Abstract Amino acid sequence alignment of the Cephalosporium acremonium isopenicillin N synthase (cIPNS) to similar non-heme Fe²⁺-containing enzymes from 28 different sources (bacterial, fungal, plant and animals) revealed a homologous region of high sequence conservation containing an invariant histidine residue at position 272 in cIPNS. The importance of this histidine residue in cIPNS was investigated through site-directed mutagenesis by replacing the histidine residue with leucine. The mutated gene was verified by DNA sequence analysis and expressed in Escherichia coli . When analyzed by denaturing gel electrophoresis and immunoblotting, the mutant cIPNS had identical mobility as that of the wild-type enzyme. Enzyme studies on the mutant enzyme showed loss of enzymatic activity indicating that His272 is essential for the catalytic function of cIPNS, possibly as a ligand for iron binding.     

CD38 signaling in B lymphocytes is controlled by its ectodomain but occurs independently of enzymatically generated ADP-ribose or cyclic ADP-ribose

CD38 is a type II transmembrane glycoprotein that is expressed by many cell types including lymphocytes. Signaling through CD38 on B lymphocytes can mediate B cell activation, proliferation, and cytokine secretion. Additionally, coligation of CD38 and the B cell Ag receptor can greatly augment B cell Ag receptor responses. Interestingly, the extracellular domain of CD38 catalyzes the conversion of NAD+ into nicotinamide, ADP-ribose (ADPR), and cyclic ADPR (cADPR). cADPR can induce intracellular calcium release in an inositol trisphosphate-independent manner and has been hypothesized to regulate CD38-mediated signaling. We demonstrate that replacement of the cytoplasmic tail and the transmembrane domains of CD38 did not impair CD38 signaling, coreceptor activity, or enzyme activity. In contrast, independent point mutations in the extracellular domain of CD38 dramatically impaired signal transduction. However, no correlation could be found between CD38-mediated signaling and the capacity of CD38 to catalyze an enzyme reaction and produce cADPR, ADPR, and/or nicotinamide. Instead, we propose that CD38 signaling and coreceptor activity in vitro are regulated by conformational changes induced in the extracellular domain upon ligand/substrate binding, rather than on actual turnover or generation of products.     

Menarcheal timing is accelerated by favorable nutrition but unrelated to developmental cues of mortality or familial instability in Cebu,Philippines

Understanding the determinants of pubertal timing, particularly menarche in girls, is an important area of investigation owing to the many health, psychosocial, and demographic outcomes related to reproductive maturation. Traditional explanations emphasized the role of favorable nutrition in maturational acceleration. More recently, work has documented early maturity in relation to markers of familial and environmental instability (e.g. paternal absence), which are hypothesized to serve as cues triggering adaptive adjustment of life history scheduling. While these studies hint at an ability of human females to accelerate maturity in stressful environments, most have focused on populations characterized by energetic excess. The present study investigates the role of developmental nutrition alongside cues of environmental risk and instability (maternal absence, paternal absence, and sibling death) as predictors of menarcheal age in a well-characterized birth cohort born in 1983 in metropolitan Cebu, the Philippines. In this sample, which was marked by a near-absence of childhood overweight and obesity, we find that menarcheal age is not predicted by cues of risk and instability measured at birth and during childhood and early adolescence, but that infancy weight gain and measures of favorable childhood nutrition are strong predictors of maturational acceleration. These findings contrast with studies of populations in which psychosocial stress and instability co-occur with excess weight. The present findings suggest that infancy and childhood nutrition may exert greater influence on age at menarche than psychosocial cues in environments characterized by marginal nutrition, and that puberty is often delayed, rather than accelerated, in the context of stressful environments.