Low density lipopolyprotein inhibits flavivirus acquisition in Aedes aegypti.

Aedes aegypti is the primary vector of a number of human pathogens including dengue virus (DENV) and Zika virus (ZIKV). Ae. aegypti acquires these viruses during the processing of bloodmeals obtained from an infected vertebrate host. Vertebrate blood contains a number of factors that have the potential to modify virus acquisition in the mosquito. Interestingly, low density lipopolyprotein (LDL) levels are decreased during severe DENV infection. Accordingly, we hypothesized that LDL is a modifiable factor that can influence flavivirus acquisition in the mosquito. We found that LDL is endocytosed by Ae. aegypti cells in a dynamin-dependent manner. LDL is also endocytosed by midgut epithelial cells and accumulates at the luminal midgut epithelium during bloodmeal digestion. Importantly, pretreatment with LDL, but not high density lipopolyprotein (HDL), significantly inhibited both DENV and ZIKV infection in vitro, and LDL inhibited ZIKV infection in vivo. This study identifies human LDL or 'bad cholesterol' as a modifiable factor that can inhibit flavivirus acquisition in Ae. aegypti. Identification of modifiable blood factors and critical cellular interactions that mediate pathogen acquisition may lead to novel strategies to disrupt the transmission cycle of vector-borne diseases.

Haemodynamic and hormonal responses to losartan (DuP753/MK954) infusion during cardiac catheterization in conscious salt-deplete dogs.

1. Haemodynamic and hormonal responses to infused angiotensin II were studied in conscious salt-deplete dogs during infusion of D-glucose or losartan (DuP753/MK954). 2. Mean arterial pressure (118 +/- 13 mmHg) fell rapidly after losartan (60 min 106 +/- 18 mmHg) with a rise in heart rate (107 +/- 16 beats/min) from baseline (98 +/- 17 beats/min). Pressor responses to angiotensin II during D-glucose infusion (6 ng min-1 kg-1, 99 +/- 10 mmHg; 18 ng min-1 kg-1, 140 +/- 15 mmHg; 54 ng min-1 kg-1, 157 +/- 12 mmHg; 162 ng min-1 kg-1, 178 +/- 14 mmHg) showed a parallel shift during losartan infusion with very similar pressures in response to higher rates of angiotensin II infusion (54 ng min-1 kg-1, 108 +/- 17 mmHg; 162 ng min-1 kg-1, 138 +/- 14 mmHg; 486 ng min-1 kg-1, 155 +/- 14 mmHg; 1458 ng min-1 kg-1, 177 +/- 12 mmHg). Losartan caused a fall in baseline systemic vascular resistance. Despite the similar mean arterial pressure, the rise in systemic vascular resistance after angiotensin II during D-glucose infusion (162 ng min-1 kg-1, 8065 +/- 1967 dyn s cm-5) was reduced during losartan infusion (1458 ng min-1 kg-1, 6645 +/- 1720 dyn s cm-5. Losartan caused a small rise in cardiac output related to a rise in heart rate and increased stroke volume. Pressure infusions of angiotensin II caused a fall in cardiac output during D-glucose infusion, which was blocked during losartan infusion.(ABSTRACT TRUNCATED AT 250 WORDS)

Atrial natriuretic factor and changes in the aldosterone response to angiotensin II in sodium depleted dogs.

The effects of physiological shifts in plasma atrial natriuretic factor (ANF) concentrations on angiotensin II/aldosterone relationships during changes in sodium status were assessed in 6 conscious beagle dogs. Incremental infusions of angiotensin II (3, 9 and 27ng/kg/min) were administered on three occasions. The animals were studied in sodium replete and deplete states and on a third occasion, again while sodium deplete, with a background constant low-dose infusion of ANF (1.5pmol/kg/min) sufficient to enhance the low endogenous plasma ANF values observed in sodium depletion to match those observed in the sodium replete state. Sodium depletion caused a leftward shift and steepened the slope of the relationship between achieved arterial angiotensin II concentrations and the plasma aldosterone response. This effect was significantly attenuated (approximately 50%) by the low dose ANF infusions which tended to flatten the slope of the angiotensin II/aldosterone curve (ns) and shifted it significantly to the right (p < 0.05). These data suggest subtle shifts in endogenous levels of plasma ANF, accompanying changes in sodium status, are a major contributor to the associated alterations in angiotensin II/aldosterone relationships. Low dose ANF also significantly reduced the effect of angiotensin II on arterial pressures but did not alter natriuresis.

Effects of the angiotensin II receptor antagonist Losartan (DuP 753/MK 954) on arterial blood pressure, heart rate, plasma concentrations of angiotensin II and renin and the pressor response to infused angiotensin II in the salt-deplete dog.

1. The blood pressure, heart rate, hormonal and pressor responses to constant rate infusion of various doses of the angiotensin (type 1) receptor antagonist Losartan (DuP 753/MK 954) were studied in the conscious salt-deplete dog. 2. Doses in the range 0.1-3 micrograms min-1 kg-1 caused no change in blood pressure, heart rate or pressor response to angiotensin II (54 ng min-1 kg-1), and a dose of 10 micrograms min-1 kg-1 had no effect on blood pressure, but caused a small fall in the pressor response to angiotensin II. Infusion of Losartan at 30 micrograms min-1 kg-1 for 3 h caused a fall in mean blood arterial pressure from baseline (110.9 +/- 11.2 to 95.0 +/- 12.8 mmHg) and a rise in heart rate (from 84.6 +/- 15.1 to 103 +/- 15.2 beats/min). Baseline plasma angiotensin II (42.5 +/- 11.8 pg/ml) and renin (64.5 +/- 92.7 mu-units/ml) concentrations were already elevated in response to salt depletion and rose significantly after Losartan infusion to reach a plateau by 70 min. The rise in mean arterial blood pressure after a test infusion of angiotensin II (35.3 +/- 11.6 mmHg) was reduced at 15 min (11.8 +/- 6.8 mmHg) by Losartan and fell progressively with continued infusion (3 h, 4.3 +/- 3.3 mmHg). The peak plasma angiotensin II concentration during infusion of angiotensin II was unaffected by Losartan, but the rise in plasma angiotensin II concentration during infusion was reduced because of the elevated background concentration. Noradrenaline infusion caused a dose-related rise in mean blood arterial pressure (1000 ng min-1 kg-1, +19.9 +/- 8 mmHg; 2000 ng min-1 kg-1, +52.8 +/- 13.9 mmHg) with a fall in heart rate (1000 ng min-1 kg-1, -27.9 +/- 11.5 beats/min; 2000 ng min-1 kg-1, -31.2 +/- 17.3 beats/min).(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of the renin inhibitor H77 on angiotensin II, arterial pressure and cardiac function in conscious dogs: comparison with captopril.

The renin inhibitor H77 and the angiotensin I converting enzyme (ACE) inhibitor captopril were compared in separate experiments with infusion of 5% dextrose as a control for the effects on plasma angiotensin II (Ang II) concentration, arterial pressure and cardiac function, measured by Swan-Ganz catheter, in conscious dogs. The effects of a high dose of H77 (10 mg/kg per h) were similar to those of high-dose captopril (6 mg/kg per h). Both reduced plasma Ang II concentration, systemic vascular resistance and arterial pressure; both increased the heart rate; both increased cardiac output but the change was significant only with captopril; neither affected stroke volume, pulmonary artery pressure or pulmonary vascular resistance; both reduced left and right atrial pressures. The similar pattern of effects for the two inhibitors suggests that the mechanism by which they act is the same--reduction in Ang II--and that the cardiovascular effects of H77 are not a specific action of the peptide that is unrelated to the reduction in plasma Ang II concentrations.

The role of dopamine in the control of corticosteroid secretion and metabolism.

The relation between aldosterone and its trophins is altered by electrolyte status and in some hypertensive conditions in man by a mechanism or mechanisms not understood. Dopamine has been suggested as the agent for the altered sensitivity of plasma aldosterone to angiotensin II based on the results of studies with dopamine itself, both in vivo and in vitro, and with pharmacological agonists and antagonists. The evidence derived from these studies is presented and discussed. Questionable specificity of the agents used makes interpretation difficult. Similarly, dopamine infusion rates used in man and animals have resulted in plasma concentrations far in excess of those found normally and these pharmacological concentrations have been shown to alter both the clearance rate of exogenous angiotensin II, and the pattern of steroid response to ACTH. Direct study of adrenal tissue has provided more promising results. The adrenal cortex possesses specific dopamine receptors and dopamine has been shown to modify aldosterone biosynthesis in vitro. Moreover, dopamine is present in adrenocortical tissue in concentrations in the range calculated to operate the receptors. However, there is, as yet, no evidence that dopamine concentrations change in a physiological meaningful way, for example, during changes in sodium status.

Similarity between active and trypsin-activated inactive renin in dog plasma by means of renin inhibition: the dog as an animal model for studies of inactive renin.

A method for trypsin-activation of dog plasma inactive renin is described. Liquid phase trypsin (final concentration 6.7 mg/ml) was used and the reaction was stopped after 2 min at 4 degrees C by soybean trypsin inhibitor (13 mg/ml). Renin was measured as angiotensin I (Ang I) generation in trypsin-treated and untreated plasma using the antibody-trapping method, in the presence of excess ox renin substrate. The renin-like activity after trypsin was indeed due to renin, since Ang I generation in dog plasma before and after trypsin treatment was completely inhibited by H-77 at 10(-6) mol/l, and the two IC50 values were very similar (2.7 +/- 0.7 and 2.9 +/- 0.7 at 10(-8) mol/l, respectively). Dog plasma inactive renin was effectively separated from active renin by chromatography on Affigel Blue. Like human prorenin, dog plasma inactive renin rose in response to sodium depletion (furosemide 5 mg/kg, i.v.) followed by a low-salt diet (1 mmol Na+/day) for 4 days, (from 29.6 +/- 8 to 162 +/- 22 microU/ml; P less than 0.01, n = 10). Active renin also increased as expected. Intravenous captopril (6 mg/kg per h), for 3 h, led to a sharp increase in dog plasma active renin (from 53 +/- 8 to 360 +/- 60 microU/ml; P less than 0.01, n = 6), whereas inactive renin remained unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)

Atrial natriuretic peptides and renin release.

The relationship between endogenous plasma concentrations of atrial natriuretic peptide and renin was examined in resting normal subjects and patients with cardiac impairment. To test the hypothesis that atrial natriuretic peptide inhibits renin secretion, intravenous infusions of atrial natriuretic peptide were administered to normal volunteers, patients with end-stage renal failure, and conscious dogs in both sodium-replete and sodium-depleted states. Plasma atrial natriuretic peptide and renin were inversely related in normal subjects (r = -0.52, n = 140, p less than 0.001), but a weak positive association between these two variables was observed in patients with cardiac impairment (r = 0.32, n = 60, p less than 0.02). Low doses of both 26- and 28-amino-acid human atrial natriuretic peptide (2 pmol/kg/minute for two hours) given to sodium-replete normal subjects halved plasma renin compared with time-matched placebo values (19 +/- 4 and 18 +/- 3 versus 36 +/- 8 microU/ml, p less than 0.001 for both). Incremental doses of synthetic atrial natriuretic peptide suppressed plasma renin below time-matched placebo values in both sodium-replete (maximal suppression 1.2 +/- 0.4 versus 8.6 +/- 1.4 microU/ml, p less than 0.001) and sodium-depleted (maximal suppression 18.9 +/- 4.9 versus 51 +/- 13 microU/ml, p less than 0.05) dogs. This effect was initially apparent at low doses of atrial natriuretic peptide (1 pmol/kg/minute), and renin suppression was maximal, in both states, with lesser doses of atrial natriuretic peptide than those at which maximal natriuresis was observed. Atrial natriuretic peptide administered to patients with end-stage renal failure (10 pmol/kg/minute for one hour) caused no change in plasma renin. These data confirm that atrial natriuretic peptide inhibits renin secretion in a dose-related manner and suggest that this action of the peptide is modified by both the baseline sodium status and renal function of the recipient.

A transition-state analogue inhibitor of human renin (H.261): test in vitro and a comparison with captopril in the anaesthetized baboon.

H.261, a new transition state inhibitor of human renin with an IC50 of 6.9 X 10(-10) M, was given by intravenous infusion to six anaesthetized baboons. The inhibitor was infused first at 0.1 mumol/kg/h for 15 min, then at 1.0 mumol/kg/h for a further 15 min. After a recovery period of 2 h in which the animals received 5% dextrose, they were infused with captopril, 25 mumol/kg/h for 15 min. At both rates of infusion H.261 markedly and significantly reduced the enzymatic action of renin in plasma, the blood concentration of angiotensin I, the plasma concentration of angiotensin II and mean arterial pressure. All changes reverted towards or to control values in the subsequent control period. Captopril also lowered plasma angiotensin II concentration and mean arterial pressure markedly and significantly but, as expected for an inhibitor of the angiotensin I-converting enzyme, plasma active renin concentration and blood angiotensin I concentration increased. The changes of angiotensin II and arterial pressure were similar with captopril and H.261.

Renin inhibitors: their use in understanding the role of angiotensin II as a pressor hormone.

Infusion of H.261, the inhibitor of human renin in the baboon, lowered blood angiotensin I, plasma angiotensin II, and arterial pressure suggesting that in the sodium-depleted state angiotensin II contributes to the maintenance of arterial pressure. In a second experiment dose-response infusions of angiotensin II were given in conscious sodium-depleted dogs before and during infusion of the renin inhibitor H.77. These suggested that the contribution of angiotensin II to the maintenance of arterial pressure in this state was made mainly by a circulating peptide. Preliminary results in normal humans show that infusion of H.142 intravenously lowered angiotensin I, angiotensin II, and arterial pressure.

Peptide inhibitors of renin.

Analogues of renin substrate that incorporated a non-cleavable isostere at the scissile bond are powerful inhibitors of renin both in vitro, and in animals and man.

New inhibitors of human renin tested in vitro and in vivo in the anaesthetized baboon.

A new inhibitor of human renin (H. 189) is described. It is a decapeptide analogue of human renin substrate with the amino acid, statine, substituted for leucine in the scissile bond. Its inhibitory potency as shown by IC50 is 1.0 X 10(-8) M with human plasma renin and 1.5 X 10(-8) M with baboon plasma renin. It is less effective with dog and rat renin, but its inhibitory potency with human renin is similar to that of another inhibitor of ours (H. 142) having a reduced isostere in the scissile bond. H. 189 has some inhibitory effect on cathepsin D (IC50 6.5 X 10(-5) M) but H. 142 has no discernible effect. Pepstatin, on the other hand, was highly effective against cathepsin D (IC50 1.2 X 10(-8) M). H. 142 and H. 189 were infused intravenously at 10 mg/kg/h in four anaesthetized salt-deplete baboons (Papio hamadryas). The activity of renin in plasma decreased markedly as did the circulating concentration of its products, angiotensin I and angiotensin II.

Effects of prolonged and brief infusions of noradrenaline on arterial pressure and on the plasma concentrations of active renin, angiotensin II, aldosterone and potassium.

Conscious male beagle dogs were given constant intravenous infusions of noradrenaline for 14 days, four receiving 125 ng/kg/min and four 250 ng/kg/min. Before, during and after these infusions dose-response studies were done in which additional noradrenaline was infused at 500, 1000 and 2000 ng/kg/min, each rate for 1 h. Blood samples were taken before and during infusions for measurement of haematocrit and plasma concentrations of noradrenaline, active renin, angiotensin II, aldosterone, sodium and potassium. Fourteen-day infusion of noradrenaline at 125 ng/kg/min did not raise blood pressure significantly though infusion at 250 ng/kg/min did, but for the first week of infusion only. Heart rate decreased significantly at both rates. Arterial pressure fell markedly and significantly on stopping infusion. Mean plasma concentrations of renin, angiotensin II and aldosterone tended to be lower during prolonged infusion of noradrenaline, but only the fall of renin during the second week was significant in one group of dogs. Noradrenaline at higher rates significantly raised blood pressure and increased plasma concentrations of renin and angiotensin II. Plasma aldosterone concentration did not rise significantly, perhaps because plasma potassium concentration decreased; in support of this theory changes of plasma aldosterone correlated with changes of plasma potassium but not with changes of angiotensin II. The rise in arterial pressure during dose-response studies was related to the increase of plasma noradrenaline. Prolonged infusion of noradrenaline did not alter the dose-response relation between plasma noradrenaline concentration and arterial pressure.

Peptide inhibitors of renin.

Three experiments are described using new substrate analogue inhibitors of renin. The first experiment shows that introduction of a reduced isostere in the scissile peptide bond of an analogue greatly increases its ability to inhibit renin of a particular species. However, different species of renin substrate have different amino acids in their scissile bond and variation here also greatly influences the affinity of renin and substrate and hence of renin and substrate analogues. Finally, substitution of amino acids in the C-terminal adjacent to the scissile bond influences the affinity and efficacy of substrate analogues as inhibitors. In our second experiment a peptide inhibitor of dog renin, H.77, was used in an affinity column to produce a one-stage, 2000-fold, and complete purification of human renin. In our third experiment infusion of H.77 was used to lower circulating concentrations of angiotensin I and angiotensin II in conscious sodium-deplete dogs. Captopril was then given in addition to H.77 but blood pressure did not fall further, suggesting that captopril lowers blood pressure wholly or partly by reducing angiotensin II within the circulation and in extravascular sites.

H-77: a potent new renin inhibitor. In vitro and in vivo studies.

Chemical modification of the backbone at the cleavage site in the (6-13)-octapeptide of equine angiotensinogen resulted in greatly increased binding affinity and resistance to cleavage by renin. The D-His6-Tyr13 octapeptide analog containing the reduced bond -CH2-NH-instead of a peptide bond -CO-NH- at the Leu10-Leu11 linkage (H-77) was a powerful in vitro inhibitor of canine renin (IC50 = 24nM). It gave an IC50 of 1 microM against human renin and 0.6 microM against rat renin. In sodium-depleted conscious dogs, infusion of H-77 caused dose-related falls of plasma angiotensin I plasma angiotensin II concentration and mean arterial pressure; the minimum effective dose was 0.1 mg . kg-1 hr-1. Similar infusions of H-77 in chronically catheterized rats have no effect on blood pressure or plasma angiotensin II concentration. Thus, the in vitro effect of H-77 as an inhibitor of renin in dog, human, and rat plasma was paralleled by its action in the whole animal.

Effect of infused captopril on blood pressure and the renin-angiotensin-aldosterone system in normal dogs subjected to varying sodium balance.

Infusion of captopril at 20, 200, 2,000 and 6,000 micrograms/kg/hour into sodium-depleted conscious dogs produced a rapid, dose-dependent decrease in blood pressure and plasma angiotensin II and III, maximal suppression being achieved at 200 micrograms/kg/hour (97 +/- 14 to 65 +/- 8 [standard deviation] mm Hg, 38 +/- 10.6 to 3.2 +/- 1.5 pmol/liter and 7.0 +/- 4.8 to 1 +/- 0.5 pmol/liter, respectively). Angiotensin I concentration increased with each infusion rate to a maximal 16-fold increase at 6,000 micrograms/kg/hour (26 to 416 pmol/liter). For all infusion rates the percentage decrease in blood pressure correlated with the percentage decrease in plasma angiotensin II (r = 0.65, p less than 0.001). Infusion of captopril at 6,000 micrograms/kg/hour into sodium-loaded dogs also produced a decrease in both blood pressure (117 +/- 9 to 96.6 +/- 11 mm Hg) and plasma angiotension II (11.0 +/- 3 to 1.6 +/- 1.3 pmol/liter). Plasma aldosterone concentrations decreased whereas both blood angiotensin I and renin concentration increased. In another experiment angiotensin II was infused at 2, 6, 18 and 54 ng/kg/min into sodium-depleted dogs firstly without modification and secondly combined with captopril (6,000 micrograms/kg/hour) given for 1 hour before the angiotensin dose-response study and continued throughout. Angiotensin II infusion raised mean arterial pressure and plasma angiotensin II in each animal. However, the angiotensin II blood pressure dose-response curve was shifted downwards and to the right in the captopril-treated animals. These results suggest that arterial pressure and aldosterone secretion in normal dogs are partly dependent on the renin-angiotensin system but that not all of the acute decrease in blood pressure produced by captopril can be explained by the suppression of the acute vasoconstrictor effect of circulating angiotensin II.

Effect of changes in sodium balance on potassium/aldosterone dose-response curves in the dog.

1. Potassium was infused intravenously in an incremental fashion and the plasma aldosterone response were measured in conscious beagle dogs at five different intakes of dietary sodium. 2. Potassium/aldosterone dose-response curves were constructed for each dietary sodium regimen. 3. The rate of increase of plasma potassium during graded potassium infusion became progressively greater with increasing sodium depletion. 4. Regression lines of plasma aldosterone on plasma potassium were progressively elevated and steepened with increasing sodium depletion. 5. The alteration of these dose-response curves could in part have been the result of chronic elevation of plasma potassium and angiotensin II, and depression of plasma sodium, with sodium deprivation. 6. By contrast, acute changes in plasma angiotensin II or sodium concentrations across incremental infusions of potassium did not explain the progressive changes in the potassium/aldosterone dose-response curves. 7. The steepest part of the plasma aldosterone response curve was in the plasma potassium range 4-6 mmol/1. 8. Maximum achieved aldosterone levels were similar to or greater than those attained during angiotensin II infusion in previous studies in beagle dogs. 9. Potassium, like angiotensin II and adrenocorticotropic hormone, becomes a more effective stimulus to aldosterone with sodium depletion, thereby facilitating the preservation of sodium homoeostasis.

Prolonged infusion of norepinephrine in the conscious dog: effects on blood pressure, heart rate, renin, angiotensin II, and aldosterone.

Eight conscious beagle dogs were given continuous intravenous infusions for 4 weeks: 0.9% NaCl solution was given for the first week; norepinephrine for the following 2 weeks, (at 125 ng/kg/min or at 250 ng/kg/min each in four dogs), 0.9% NaCl for the final week. Norepinephrine at the lower dose did not raise blood pressure but did reduce heart rate significantly. The higher rate of norepinephrine infusion raised blood pressure, but for the first week of infusion only, and again heart rate was reduced significantly during both weeks. Blood pressure fell on stopping infusion whether or not it had been raised previously. Plasma concentrations of renin, angiotensin II, and aldosterone were reduced, but the changes were of borderline significance only. These changes occurred when plasma concentrations of norepinephrine were increased four-sevenfold. The acute response to high infusion rates of norepinephrine (500, 1,000, and 2,000 ng/kg/min each for 1 h) was tested at weekly intervals in each dog. At each of these high rates of infusion, blood pressure, renin and angiotensin II, and haematocrit increased while plasma potassium concentration and heart rate fell. These changes occurred with increases of plasma norepinephrine greater than 14-fold. Prolonged infusion of norepinephrine did not alter the relation between plasma norepinephrine and arterial pressure as assessed by these dose-response studies.