Mechanisms of COVID-19-induced kidney injury and current pharmacotherapies

The COVID-19 pandemic created a worldwide debilitating health crisis with the entire humanity suffering from the deleterious effects associated with the high infectivity and mortality rates. While significant evidence is currently available online and targets various aspects of the disease, both inflammatory and noninflammatory kidney manifestations secondary to COVID-19 infection are still largely underrepresented. In this review, we summarized current knowledge about COVID-19-related kidney manifestations, their pathologic mechanisms as well as various pharmacotherapies used to treat patients with COVID-19. We also shed light on the effect of these medications on kidney functions that can further enhance renal damage secondary to the illness.

Review: Angiotensin Peptides and their Pleiotropic Actions

The concept of tissue renin-angiotensin systems (RAS) is now well established and it is now usual to think in terms of renal and tissue systems. At the same time it has emerged that angiotensin II (Ang II) is not the only biologically active peptide generated by the RAS. At least three others have been identified: the heptapeptide Ang III, the hexapeptide Ang IV and Ang 1-7. Specific receptors exits for the last two peptides. In addition, the range of possible physiological and pathophysiological properties for Ang II„ has been expanding. The current perception of the RAS is therefore that of a much more complex system than previously believed, with autocrine, paracrine and endocrine properties extending beyond the cardiovascular system. This mini-review focuses on the synthetic pathways of the Ang peptides and describes some of their pleiotropic actions.

Laser-induced dissociation of singly protonated peptides at 193 and 266 nm within a hybrid linear ion trap mass spectrometer

RATIONALE

We implemented, for the first time, laser-induced dissociation (LID) within a modified hybrid linear ion trap mass spectrometer, QTrap, while preserving the original scanning capabilities and routine performance of the instrument.

METHODS

Precursor ions of interest were mass-selected in the first quadrupole (Q1), trapped in the radiofrequency-only quadrupole (q2), photodissociated under irradiation with a 193- or 266-nm laser beam in the third quadrupole (q3), and mass-analyzed using the linear ion trap.

RESULTS

LID of singly charged protonated peptides revealed, in addition to conventional amide-bond cleavages, preferential fragmentation at Cα -C/N-Cα bonds of the backbone as well as at the Cα -Cβ /Cβ -Cγ bonds of the side-chains. The LID spectra of [M+H](+) featured product ions that were very similar to the observed radical-induced fragmentations in the CID spectra of analogous odd-electron radical cations generated through dissociative electron-transfer in metal-ligand-peptide complexes or through laser photolysis of iodopeptides.

CONCLUSIONS

LID of [M+H](+) ions results in fragmentation channels that are comparable with those observed upon the CID of M(•+) ions, with a range of fascinating radical-induced fragmentations.

The effects of angiotensin peptides and angiotensin receptor antagonists on the cell growth and angiogenic activity of GH3 lactosomatotroph cells in vitro

The local renin-angiotensin system (RAS) is present in the pituitary gland, and inhibitory effects of angiotensins on the lactosomatotroph (GH3) cell growth have been revealed. The aim of this study was to examine the influence of various angiotensin peptides and angiotensin AT1, AT2, and AT4 receptors antagonists on the cell proliferation, viability, and VEGF secretion in pituitary lactosomatotroph GH3 cell culture in order to identify receptors involved in antiproliferative effects of angiotensins on GH3 tumor cells. Cell viability and proliferation using Mosmann method and BrdU incorporation during DNA synthesis, and VEGF secretion using ELISA assay were estimated. The inhibitory effects of ang II, ang IV, and ang 5-8 on the cell viability and BrdU incorporation in GH3 culture were not abolished by AT1, AT2, and AT4 receptors antagonists. Ang II, as well as ang III and ang IV at lower concentrations stimulated the secretion of VEGF in GH3 cell culture. The secretion of VEGF was inhibited by ang III and ang IV at higher concentrations. AT1 and AT2 receptors antagonists prevented the proangiogenic effects of ang II. Ang II, ang IV, and ang 5-8 decrease the cell number and proliferation in GH3 cell culture independently of the AT1, AT2, and AT4 receptors. These peptides affect also secretion of VEGF in culture examined. Both the AT1 and AT2 receptors appear to mediate the proangiogenic effects of ang II.

Gold ion-angiotensin peptide interaction by mass spectrometry

Stimulated by the interest in developing gold compounds for treating cancer, gold ion-angiotensin peptide interactions are investigated by mass spectrometry. Under the experimental conditions used, the majority of gold ion-angiotensin peptide complexes contain gold in the oxidation states I and III. Both ESI-MS and MALDI-TOF MS detect singly/multiply charged ions for mononuclear/multinuclear gold-attached peptides, which are represented as [peptide + a Au(I) + b Au(III) + (e - a -3b) H](e+), where a,b ≥ 0 and e is charge. ESI-MS data shows singly/multiply charged ions of Au(I)-peptide and Au(III)-peptide complexes. This study reveals that MALDI-TOF MS mainly detects singly charged Au(I)-peptide complexes, presumably due to the ionization process. The electrons in the MALDI plume seem to efficiently reduce Au(III) to Au(I). MALDI also tends to enhance the higher polymeric forms of gold-peptide complexes regardless of the laser power used. Collision-induced dissociation experiments of the mononuclear and dinuclear gold-attached peptide ions for angiotensin peptides show that the gold ion (a soft acid) binding sites are in the vicinity of Cys (a soft ligand), His (a major anchor of peptide for metal ion chelation), and the basic residue Arg. Data also suggests that the abundance of gold-attached peptides increases with higher gold concentration until saturation, after which an increase in gold ion concentration leads to the aggregation and/or precipitation of gold-bound peptides.

Mass spectrometry for the molecular imaging of angiotensin metabolism in kidney

To better understand the tissue distribution and activity of enzymes involved in angiotensin II (Ang II) processing, we developed a novel molecular imaging method using matrix-assisted laser desorption ionization-time-of-flight (MALDI-TOF) mass spectrometry. Mouse kidney sections (12 μm) were incubated with 10-1,000 μmol/l Ang II for 5-15 min at 37°C. The formed peptides Ang III and Ang-(1-7) were identified by MALDI-TOF/TOF. A third metabolite, Ang-(1-4), was generated from further degradation of Ang-(1-7). Enzymatic processing of Ang II was dose and time dependent and absent in heat-treated kidney sections. Distinct spatial distribution patterns (pseudocolor images) were observed for the peptides. Ang III was localized in renal medulla, whereas Ang-(1-7)/Ang-(1-4) was present in cortex. Regional specific peptide formation was confirmed using microdissected cortical and medullary biopsies. In vitro studies with recombinant enzymes confirmed activity of peptidases known to generate Ang III or Ang-(1-7) from Ang II: aminopeptidase A (APA), Ang-converting enzyme 2 (ACE2), prolyl carboxypeptidase (PCP), and prolyl endopeptidase (PEP). Renal medullary Ang III generation was blocked by APA inhibitor glutamate phosphonate. The ACE2 inhibitor MLN-4760 and PCP/PEP inhibitor Z-pro-prolinal reduced cortical Ang-(1-7) formation. Our results establish the power of MALDI imaging as a highly specific and information-rich analytical technique that will further aid our understanding of the role and site of Ang II processing in cardiovascular and renal pathologies.

Influence of charge state and amino acid composition on hydrogen transfer in electron capture dissociation of peptides

Although conventional N-Cα bond cleavage in electron capture dissociation (ECD) of multiply-charged peptides generates a complementary c' and z(·) fragment pair, the N-Cα cleavage followed by hydrogen transfer from c' to z(·) fragments produces other fragments, namely c(·) and z'. In this study, the influence of charge state and amino acid composition on hydrogen transfer in ECD is described using sets of peptides. Hydrogen transferred ionic species such as c(·) and z' were observed in ECD spectra of doubly-protonated peptides, while the triply-protonated form did not demonstrate hydrogen transfer. The extent of hydrogen transfer in ECD of doubly-protonated peptides was dependent on constituent amino acids. The ECD of doubly-protonated peptides possessing numerous basic sites showed extensive hydrogen transfer compared with ECD of less basic peptides. The extent of hydrogen transfer is discussed from the viewpoints of the structure of peptide ions, the possibility of internal hydrogen bonding and intermediate lifetime of complex [c' + z(·)].

Ultrasound ionization of biomolecules

To date, mass spectrometric analysis of biomolecules has been primarily performed with either matrix-assisted laser desorption/ionization (MALDI) or electrospray ionization (ESI). In this work, ultrasound produced by a simple piezoelectric device is shown as an alternative method for soft ionization of biomolecules. Precursor ions of proteins, saccharides and fatty acids showed little fragmentation. Cavitation is considered as a primary mechanism for the ionization of biomolecules.

A new biomarker of protein oxidation degree and site using angiotensin as the target by MS

Hydroxyl radicals generated from Fenton reaction were used to damage the angiotensin. The oxidative damage degree and sites of peptides were measured by HPLC-MS and MS/MS. Experimental results proved that the oxidative damage degree increased with longer reaction time. The results also showed that the side chains of phenylalanine and tyrosine in angiotension can be attacked by hydroxyl radicals to form the oxidative products. A new strategy was established to monitor the oxidative degree and sites of peptides and laid the foundation for protein oxidation. This method can be used to investigate the mechanism of protein oxidative damage caused by oxidative stress which is induced by environmental pollutants and physiological activities. There will also be a wide application in the research of pathogenesis of some disease related to oxidative stress.

A novel, simple and sensitive ligand affinity capture method for detecting molecular interactions by MALDI mass spectrometry

A simple and sensitive ligand affinity capture method (LAC) was developed to detect biotinylated biomolecules bound to a biotin-avidin base by matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI ToF MS). Glass slides covered with a metal film for MALDI MS applications were treated with amino-silane and derivatized with biotin followed by binding of avidin. Washing buffers with high ionic strength increased the specificity of the subsequent binding of biotinylated biomolecules to the avidin layer. A combined thin layer-dried droplet method using alpha-cyano-4-hydroxycinnamic acid (CHCA) in acetone or ethyl acetate resulted in the most intense ions of biotinylated polymyxin B, whereas the matrix conditions did not influence the detection of angiotensin II. Addition of biotinylated biomolecules in the low femtomole to low picomole range resulted in sufficient ion intensity for detection by the LAC method. The LAC concept was extended by binding of biotinylated lipopolysaccharide to the biotin-avidin base followed by preferential capture and specific detection of the binding antagonist polymyxin B.

Dissociation lifetime studies of doubly deprotonated angiotensin peptides

The doubly deprotonated [Asn,Val5] angiopeptide, in the gas phase, was irradiated with 266 nm photons. The time of flight (TOF) of the products formed following photoabsorption, namely, the monoanion and neutral fragments, was recorded with submicrosecond time resolution. Monte Carlo simulations of the TOF of the neutral fragments indicate that the dissociation occurs faster than 100 ns. A similar experiment performed on the Val5 angiopeptide also yielded a dissociation time shorter than 100 ns. We suggest dissociation mechanisms that account for the different number of photons required for the release of CO2.

Investigations with O-linked protein glycosylations by matrix-assisted laser desorption/ionization Fourier transform ion cyclotron resonance mass spectrometry

Posttranslational modifications such as glycosylation can play a fundamental role in signaling pathways that transform an ordinary cell into a malignant one. The development of a protocol to detect these changes in the preliminary stages of disease can lead to a sensitive and specific diagnostic for the early detection of malignancies such as ovarian cancer in which differential glycan patterns are linked to etiology and progression. Small variations in instrument parameters and sample preparation techniques are known to have significant influence on the outcome of an experiment. For an experiment to be effective and reproducible, these parameters must be optimized for the analyte(s) under study. We present a detailed examination of sample preparation and matrix-assisted laser desorption/ionization Fourier transform ion cyclotron resonance mass spectrometry (MALDI-FT-ICR-MS) analysis of O-linked glycans globally cleaved from mucin glycoproteins. Experiments with stable isotope-labeled biomolecules allowed for the establishment of appropriate acquisition times and excitation voltages for MALDI-FT-ICR-MS of oligosaccharides. Quadrupole ion guide optimization studies with mucin glycans identified conditions for the comprehensive analysis of the entire mass range of O-linked carbohydrates in this glycoprotein. Separately optimized experimental parameters were integrated in a method that allowed for the effective study of O-linked glycans.

Trapped-ion cell with improved DC potential harmonicity for FT-ICR MS

The trapped-ion cell is a key component critical for optimal performance in Fourier transform ion cyclotron resonance (FT-ICR) mass spectrometry (MS). To extend the performance of FT-ICR MS, we have developed a new cell design that is capable of generating a DC trapping potential which closely approaches that of an ideal Penning trap, i.e., a 3D axial quadrupolar potential distribution. The new cell design was built upon an open cylindrical geometry, supplemented with two pairs of cylindrical compensation segments. Electric potential calculations for trial cell geometries were aimed at minimizing spatial variations of the radial electric field divided by radius. The resulting cell proportions and compensation voltages delivered practically constant effective ion cyclotron frequency that was independent of ion radial and axial positions. Our customized 12 tesla FT-ICR instrument was upgraded with the new cell, and the performance was characterized for a range of ion excitation power and ion populations. Operating the compensated cell at increased postexcitation radii, approximately 0.7 of the cell inner radius, resulted in improved mass measurement accuracy together with increased signal intensity. Under these same operating conditions the noncompensated open cell configuration exhibited peak splitting and reduced signal life time. Mass accuracy tests using 11 calibrants covering a wide m/z range reproducibly produced under 0.05 ppm RMS precision of the internal calibration for reduced ion populations and the optimal excitation radius. Conditions of increased ion population resulted in a twofold improvement in mass accuracy compared with the noncompensated cell, due to the larger achievable excitation radii and correspondingly lower space charge related perturbations of the calibration law.

On-line electrogeneration of copper-peptide complexes in microspray mass spectrometry

The interaction of copper ions with peptides was investigated by electrospray mass spectrometry. Two electrospray micro-emitters were compared, the first one with a platinum electrode using a copper(II) electrolyte solution containing a peptide sample, and the second one with a sacrificial copper anode in a water/methanol solution containing only a peptide (i.e., angiotensin III, bradykinin, or Leu-enkephalin). The former yielded mainly Cu(2+) complexes either with histidine residues or with the peptide backbone (Cu(+) complexes can be also formed due to gas-phase reactions), whereas the latter can generate a mixture of both Cu(+) and Cu(2+) aqueous complexes that yield different complexation patterns. This study shows that electrospray emitters with soluble copper anodes enable the study of Cu(I)-peptide complexes in solution.

Are differences in calcium antagonists relevant across all stages of nephropathy or only proteinuric nephropathy?

PURPOSE OF REVIEW

The main effects of classic calcium antagonists are mediated by the inhibition of L-type calcium channels broadly distributed within the renal vascular bed. Calcium antagonists act predominantly on the afferent arterioles, and dihydropyridines can favour the increase in glomerular hypertension and progression of kidney diseases, in particular when systemic blood pressure remains uncontrolled.

RECENT FINDINGS

Calcium antagonists have been widely used in clinical practice because of their antihypertensive capacity. The prevention of renal damage is a very important aim of antihypertensive therapy. This is particularly so taking into account the high prevalence of chronic kidney disease in the general population. Non-dihydropyridines such as verapamil have been shown to possess an antiproteinuric effect that could be particularly relevant.

SUMMARY

Recent data from clinical trials have confirmed that, in hypertensive patients with preserved renal function or with chronic kidney disease, calcium antagonists are effective antihypertensive drugs to be considered alone or in combination with an angiotensin-converting enzyme inhibitor or an angiotensin receptor blocker. In those patients presenting with proteinuric kidney disease, non-dihydropyridines could reduce proteinuria to a greater degree than dihydropyridines.

Isoproterenol-induced impairment of heart function and remodeling are attenuated by the nonpeptide angiotensin-(1-7) analogue AVE 0991

The aim of this study was to evaluate the effects of AVE 0991 (AVE), a nonpeptide compound that mimics Ang-(1-7) actions, on cardiac remodeling. Heart hypertrophy and heart dysfunction were induced by isoproterenol (ISO) (2 mg/kg i.p./day for 7 days) in male Wistar rats. At the end of the 7-day period, the hearts were perfused according to the Langendorff method to evaluate cardiac function. The hearts, atria, and right and left ventricles wet weights were recorded, normalized for body weight and then expressed as muscle mass index (mg/g). In addition, serial sections from left ventricle were stained with hematoxylin-eosin for cell morphometry and with collagen-specific Masson's trichrome for detection of fibrosis. Immunofluorescence-labeling and confocal microscopy were used to investigate the distribution and deposition of collagen types I, III, VI, and fibronectin. AVE reduced the ISO-induced hypertrophy as quantified by myocyte diameter measurements (Control: 10.60+/-0.08 microm; ISO: 14.60+/-0.11 mum; ISO+AVE: 11.22+/-0.08 microm, n = 5). In addition, AVE markedly attenuated the increase of extracellular matrix proteins induced by ISO. AVE treatment also attenuated the decrease in systolic tension and +/-dT/dt and exacerbated the vasodilatation induced by ISO. These results show that AVE has a cardioprotective effect on ISO-induced cardiac remodeling.

Improved Whitten−Rabinovitch Approximation for the Rice−Ramsperger−Kassel−Marcus Calculation of Unimolecular Reaction Rate Constants for Proteins

The Whitten-Rabinovitch (WR) approximation used in the semi-classical calculation of the Rice-Ramsperger-Kassel-Marcus (RRKM) unimolecular reaction rate constant was improved for reliable application to protein reactions. The state sum data for the 10-mer of each amino acid calculated by the accurate Beyer-Swinehart (BS) algorithm were used to obtain the residue-specific correction functions (w). The correction functions were obtained down to a much lower internal energy range than reported in the original work, and the cubic, rather than quadratic, polynomial was used for data fitting. For a specified sequence of amino acid residues in a protein, an average was made over these functions to obtain the sequence-specific correction function to be used in the rate constant calculation. Reliability of the improved method was tested for dissociation of various peptides and proteins. Even at low internal energies corresponding to the RRKM rate constant as small as 0.1 s-1, the rate constant calculated by the present method differed from the accurate BS result by 60% only. In contrast, the result from the original WR calculation differed from the accurate result by a factor of 3000. Compared to the BS method, which is difficult to use for proteins, the main advantage of the present method is that the RRKM rate constant can be calculated instantly regardless of the protein mass.

LC/MS characterization of undesired products formed during iodoacetamide derivatization of sulfhydryl groups of peptides

Many undesired by-products have been noticed during alkylation with iodoacetamide, a widely used derivatization reaction in proteomics for the determination of sulfhydryl groups in peptides and proteins. We report here that iodoacetamide reacts with the N-terminal NH2 and the C-terminal carboxylic acid groups, in addition to the peripheral residues bearing protic functional groups. If sufficient reaction time is given, the N-terminal NH2 group is readily dialkylated by iodoacetamide. In fact, the N-terminal NH2 group reacts even faster than the reactive sites present in residues, such as tyrosine or histidine. LC/MS investigations with certain reactive peptides show that by-products are formed in a relatively short reaction time, even at room temperature. Interestingly, derivatives formed in this way are useful for sequence determination of peptides by MS since the intensities of y'' ions are highly suppressed in the spectra of N-terminus mono- and dialkylated peptides, whereas those of b-ions are significantly enhanced. For example, in the spectrum of N,N-dicarboxamidomethyl derivative of Val-Ala-Ala-Phe (VAAF), the y-series ions are virtually absent. On the other hand, when the derivatization takes place at the carboxylic group, the y-series ions are markedly observed in the spectra of these undesired O-carboxamidomethyl derivatives.

Mass-spectrometric identification of a novel angiotensin peptide in human plasma

OBJECTIVE

Angiotensin peptides play a central role in cardiovascular physiology and pathology. Among these peptides, angiotensin II (Ang II) has been investigated most intensively. However, further angiotensin peptides such as Ang 1-7, Ang III, and Ang IV also contribute to vascular regulation, and may elicit additional, different, or even opposite effects to Ang II. Here, we describe a novel Ang II-related, strong vasoconstrictive substance in plasma from healthy humans and end-stage renal failure patients.

METHODS AND RESULTS

Chromatographic purification and structural analysis by matrix-assisted laser desorption/ionisation time-of-flight/time-of-flight (MALDI-TOF/TOF) revealed an angiotensin octapeptide with the sequence Ala-Arg-Val-Tyr-Ile-His-Pro-Phe, which differs from Ang II in Ala1 instead of Asp1. Des[Asp1]-[Ala1]-Ang II, in the following named Angiotensin A (Ang A), is most likely generated enzymatically. In the presence of mononuclear leukocytes, Ang II is converted to Ang A by decarboxylation of Asp1. Ang A has the same affinity to the AT1 receptor as Ang II, but a higher affinity to the AT2 receptor. In the isolated perfused rat kidney, Ang A revealed a smaller vasoconstrictive effect than Ang II, which was not modified in the presence of the AT2 receptor antagonist PD 123319, suggesting a lower intrinsic activity at the AT1 receptor. Ang II and Ang A concentrations in plasma of healthy subjects and end-stage renal failure patients were determined by matrix-assisted laser desorption/ionisation mass-analysis, because conventional enzyme immunoassay for Ang II quantification did not distinguish between Ang II and Ang A. In healthy subjects, Ang A concentrations were less than 20% of the Ang II concentrations, but the ratio Ang A/Ang II was higher in end-stage renal failure patients.

CONCLUSIONS

Ang A is a novel human strong vasoconstrictive angiotensin-derived peptide, most likely generated by enzymatic transformation through mononuclear leukocyte-derived aspartate decarboxylase. Plasma Ang A concentration is increased in end-stage renal failure. Because of its stronger agonism at the AT2 receptor, Ang A may modulate the harmful effects of Ang II.

Cooperative effect of factors governing molecular ion yields in desorption/ionization mass spectrometry

Factors governing the molecular ion yields of amino acids and peptides have been studied using fast atom bombardment (FAB) and matrix-assisted laser desorption/ionization (MALDI) mass spectrometry (MS) in positive-ion mode. The ion yields of protonated amino acids under FAB conditions are dependent on proton affinity (PA), hydrophobicity, and aromaticity of amino acids. Both PA and hydrophobicity contribute to an increase in the ion yields, while aromaticity contributes to a decrease. In MALDI, the ion yields increase linearly with the increase of PA of amino acids with the exception of lysine. In both FAB and MALDI experiments with peptides, the presence of arginine residues is essential for producing abundant protonated peptides. In FAB, the presence of aliphatic and hydrophobic amino acids (leucine and isoleucine) increases the ion yields of protonated peptides, while some hydrophilic amino acids (aspartic acid and asparagines) decrease the ion yields. The presence of two or more arginine residues does not give higher ion yields in FAB. In MALDI, the presence of aromatic amino acids (phenylalanine and tyrosine) enhances the signals for protonated peptides. Thus, physicochemical factors of individual amino acids cooperatively affect the ion yields of protonated amino acids and peptides. These factors governing the ion yields in FAB and MALDI affect two processes, desorption and ionization, that can be considered independently.

Generation of peptide radical dications via low-energy collision-induced dissociation of [CuII(terpy)(M + H)].3+

The first example of the formation of hydrogen-deficient radical cations of the type [M + H](.2+) is demonstrated to occur through a one-electron-transfer mechanism upon low-energy collision-induced dissociation (CID) of gas-phase triply charged [Cu(II)(terpy)(M + H)](.3+) complex ions (where M is an angiotensin III or enkephalin derivative; terpy = 2,2':6',2''-terpyridine). The collision-induced dissociation of doubly charged [M + H](.2+) radical cations generates similar product ions to those prepared through hot electron capture dissociation (HECD). Isomeric isoleucine and leucine residues were distinguished by observing the mass differences between [z(n) + H](.+) and w(n)(+) ions (having the same residue number, n) of the Xle residues. The product ion spectrum of [z(n) + H](.+) reveals that the w(n)(+) ions are formed possibly from consecutive fragmentations of [z(n) + H](.+) ions. Although only the first few [M + H](.2+) species have been observed using this approach, these hydrogen-deficient radical cations produce fragment ions that have more structure-informative patterns and are very different from those formed during the low-energy tandem mass spectrometry of protonated peptides.

Titanium dioxide nanoparticles-coated column for capillary electrochromatographic separation of oligopeptides

A novel column made through the condensation reaction of TiO2 nanoparticles (TiO2 NPs) with silanol groups of the fused-silica capillary is described. EOF measurements under various buffer constitutions were used to monitor the completion of reactions. The results indicated that the EOF was dependent on the interactions between buffers and the bonded TiO2 NPs. With formate/Tris buffer, EOF reversal at pH below 5 and cathodic EOF at pH above 5 were indicated. The pI of the bonded TiO2 NPs was found at approximately ph 5. Only cathodic EOF was illustrated by substituting the mobile phase with either glutamate or phosphate buffer. It was elucidated that both glutamate and phosphate buffer yield a negative charge layer on the surface of TiO2 NPs attributable to the formation of a titanium complex. The CEC performance of the column was tested with angiotensin-type oligopeptides. Some parameters that would affect the retention behavior were investigated. The interactions between the bonded phases and the analytes were explicated by epitomized acid-base functional groups of the oligopepetides and the speciation of the surface oxide in different pH ranges. The average separation efficiencies of 3.1 x 10(4) plates/m is readily achieved with a column of 70 cm (50 cm) x 50 mum ID under an applied voltage of 15 kV, phosphate buffer (pH 6.0, 40 mM), and UV detection at 214 nm.

Enhanced erythropoiesis mediated by activation of the renin‐angiotensin system via angiotensin II type 1a receptor

Although clinical and experimental studies have long suggested a role for the renin-angiotensin system (RAS) in the regulation of erythropoiesis, the molecular basis of this role has not been well understood. We report here that transgenic mice carrying both the human renin and human angiotensinogen genes displayed persistent erythrocytosis as well as hypertension. To identify the receptor molecule responsible for this phenotype, we introduced both transgenes into the AT1a receptor null background and found that the hematocrit level in the compound mice was restored to the normal level. Angiotensin II has been shown to influence erythropoiesis by two means, up-regulation of erythropoietin levels and direct stimulation of erythroid progenitor cells. Thus, we conducted bone marrow transplantation experiments and clarified that AT1a receptors on bone marrow-derived cells were dispensable for RAS-dependent erythrocytosis. Plasma erythropoietin levels and kidney erythropoietin mRNA expression in the double transgenic mice were significantly increased compared with those of the wild-type control, while the elevated plasma erythropoietin levels were significantly attenuated in the compound mice. These results provide clear genetic evidence that activated RAS enhances erythropoiesis through the AT1a receptor of kidney cells and that this effect is mediated by the elevation of plasma erythropoietin levels in vivo.

The use of a hybrid linear trap/FT-ICR mass spectrometer for on-line high resolution/high mass accuracy bottom-up sequencing

In this work we present a hybrid linear trap/Fourier transform ion cyclotron resonance (ICR) mass spectrometer to perform protein sequencing using the bottom-up approach. We demonstrate that incorporation of the linear trap greatly enhances the overall performance of the hybrid system for the study of complex peptide mixtures separated by fast high-performance liquid chromatography gradients. The ability to detect in the linear trap enables employment of automatic gain control to greatly reduce space charging in the ICR cell irregardless of ion flux. Resulting accurate mass measurements of 2 ppm or better using external calibration are achieved for the base peak as well as ions at 2% relative abundance. The linear trap is used to perform ion accumulation and activation prior to detection in the ICR cell which increases the scan rate. The increased duty cycle allows for data-dependent mass analysis of coeluting peptides to be acquired increasing protein sequence coverage without increasing the gradient length. In addition, the linear trap could be used as an ion detection device to perform simultaneous detection of tandem mass spectra with full scan mass spectral detection in the ICR cell resulting in the fastest scan cycles for performing bottom-up sequencing of protein digests. Comparisons of protein sequence coverage are presented for product ion detection in the linear trap and ICR cell.

Inhibition of Cell Migration via G Protein-Coupled Receptors to Opioid Peptides and Angiotensin

Neurotransmitters are stimulatory as well as inhibitory regulators of cell migration. Angiotensin is such an inhibitory regulator of the SDF-1-induced migration of cytotoxic T lymphocytes, as we have investigated by time-lapse videomicroscopy and computer-assisted cell tracking. For angiotensin II, the most effective form of angiotensin for the inhibition of migration, two G protein-coupled receptors are known, which both downregulate the activity of the adenylyl cyclase via activation of inhibitory G proteins. This downregulation of the enzymatic activity is a key signaling event for the inhibition of T lymphocyte and tumor cell migration, while stimulatory neurotransmitters--for example, norepinephrine--cause an activation of the adenylyl cyclase. Similar to angiotensin, the SDF-1-induced migration of cytotoxic T lymphocytes was inhibited by DAMGO, a specific agonist for the mu-opioid receptor, which is coupled to inhibitory G proteins, too. More interestingly, DAMGO downregulated the met-enkephalin-induced migration of MDA-MB-468 breast carcinoma cells. Met-enkephalin binds to the delta-opioid receptor and, with lower affinity, to the mu-opioid receptor. Since the delta-opioid receptor also activates inhibitory G proteins, the promigratory effect of met-enkephalin is caused by an intracellular signaling distinct from the engagement of each opioid receptor alone. In summary, the dual control of the adenylyl cyclase functions as an integrator of stimulatory and inhibitory signals for T lymphocyte and tumor cell migration, which are delivered by neurotransmitters and other signal substances that bind to G protein-coupled receptors.

Angiotensin I-converting enzyme-like activity in tissues from the Atlantic hagfish (Myxine glutinosa) and detection of immunoreactive plasma angiotensins

Using a highly sensitive fluorimetric assay, significant levels of angiotensin I -converting enzyme-like activity (ACELA) were detected in a range of tissues (branchial heart, gill, kidney with associated vasculature and archinephric duct, liver, whole brain and gut) from the Atlantic hagfish (Myxine glutinosa). The highest ACELA occurred in heart and gill (1.8 and 1.5 nmol His-Leu min(-1) mg protein(-1), respectively). The mammalian angiotensin I-converting enzyme (ACE) inhibitor, captopril, at 10(-5) M was a potent inhibitor of the ACELA found in all hagfish tissues. Radioimmunoassay showed that immunoreactive angiotensins (251.8+/-11.8 pM) were detectable in hagfish plasma. The validity of the assay for measurement of hagfish angiotensins was indicated by the parallelism of the angiotensin II standard curve against serially diluted hagfish plasma. Measurement of immunoreactive plasma angiotensins and detection of significant levels of ACELA in a wide range of tissues gives indirect evidence for the presence of a renin-angiotensin system in hagfishes, the earliest evolved group of craniates.

Mass spectrometric analysis of DNA mixtures: instrumental effects responsible for decreased sensitivity with increasing mass

Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry has demonstrated great potential to replace gel electrophoresis for DNA sequence analysis. A current limitation in this method is, however, the decreased sensitivity with increasing mass of DNA molecules. In the present study, instrumental effects on the mass analysis of DNA molecules were investigated quantitatively using an equimolar DNA mixture. It is shown that detection efficiency, detector saturation, and ion beam divergence account for the entirety of the observed falloff in signal intensity with increasing mass. Although the present study focused upon the analysis of DNA mixtures, the instrumental effects observed apply equally to other macromolecular mixtures (e.g., proteins, polymers).

Determination of the stoichiometry of protein complexes using liquid chromatography with fluorescence and mass spectrometric detection of fluorescently labeled proteolytic peptides

A method for the determination of the stoichiometry of protein complexes has been developed, which is based on proteolytic digestion of the complex, labeling with a fluorescent reagent, specific for amino or sulfhydryl groups, and separation by liquid chromatography with fluorescence and mass spectrometric detection. The intensity of the fluorescence signal of the labeled peptides resulting from different proteins is directly proportional to the stoichiometry of these proteins in the complex. The performance of the method was evaluated with standard peptides and proteins to ensure that accurate molar ratios can be obtained from the fluorescence chromatogram. Standard deviations of the measured molar ratio from the expected molar ratio were below 10% for both peptides and proteins. The method was finally employed for the determination of the stoichiometry of the 1:1 complex of sFc gamma RIII and hFc1. Using the described methodology, a stoichiometry of 1:1.1 was measured, which agrees well with a 1:1 complex.

Cross-linked thermoresponsive anionic polymer-grafted surfaces to separate bioactive basic peptides

Cross-linked, thermoresponsive poly(N-isopropylacrylamide-co-acrylic acid-co-N-tert-butylacrylamide) [poly(IPAAm-co-AAc-co-tBAAm)] thin hydrogel layers on silica beads were used as new column matrix modifiers for LC separation of basic bioactive peptides, angiotensin subtypes I, II, and III. Terpolymer poly(IPAAm-co-AAc-co-tBAAm) showed both phase transition and apparent carboxylate pKa shifts in water, depending on temperature. Polymer-grafted silica bead surfaces exhibited simultaneous thermally modulated changes in hydrophilic/hydrophobic properties and charge densities. More effective separation of angiotensin peptide subtypes was achieved on columns of these terpolymer thin hydrogel grafted surfaces, as compared to an uncharged control binary copolymer of IPAAm and tBAAm. Although hydrophobic interactions effect separation of angiotensin subtypes, combined electrostatic and hydrophobic interaction resulted in more pronounced retention. At temperature below the terpolymer phase transition, hydrophobic interactions predominated, and minimal changes in electrostatic interactions were supported by little shift in the apparent AAc carboxylate pKa values. Above the phase transition temperature, electrostatic interactions were dramatically reduced as a result of the decreased charge densities of the polymer grafted surfaces. Therefore, peptide retention times were also reduced, exhibiting a maximum at near 30-35 degrees C. Interestingly, column retention behavior of angiotensins is dramatically modulated by applied step temperature gradients. Thermoresponsive surface property alteration is a very rapid, reversible phenomenon, allowing step temperature gradients on thermoresponsive columns to enable the analogous performance advantages as gradient elution in reversed-phase HPLC. More importantly, injected peptides were recovered completely from the columns from calculation of peak area. In conclusion, these anionic thermoresponsive polymer-modified surfaces are good candidates for improved separation of bioactive peptides under exclusively aqueous conditions.

Resonant neutral-particle emission in collisions of electrons with peptide ions in a storage ring

Electron-biomolecular ion collisions were studied using an electrostatic storage ring with a merging beam technique for singly protonated peptides (angiotensin I, II, and III). A strong neutral-particle emission at around 6.5 eV was found in addition to neutrals from recombination at low energies. The rates of the high-energy peak greatly decreased with a slight decrease in the number of amino-acid residues from angiotensin I to III. These results suggest that some peptide bonds were selectively cleaved.

Mutational analysis of the complex of human RNase inhibitor and human eosinophil-derived neurotoxin (RNase 2)

RNase inhibitor (RI) binds diverse proteins in the pancreatic RNase superfamily with extremely high avidity. Previous studies showed that tight binding of RNase A and angiogenin (Ang) is achieved primarily through interactions of hot spot residues in the 434-460 C-terminal segment of RI with the enzymatic active site; Asp435 of RI forms key hydrogen bonds with the catalytic lysine in both complexes, whereas the other contacts are largely distinctive. Here we have investigated the structural basis for recognition of a third ligand, eosinophil-derived neurotoxin (EDN), by single-site and multisite mutagenesis. Surprisingly, Ala replacement of Asp435 decreases affinity for EDN only by 14-fold, as compared to the several hundred-fold decreases with RNase A and Ang, and individual mutations of three other hot spot residues-Tyr434, Tyr437, and Ser460-have essentially no effect. Ala substitutions of nine additional residues, selected by examining a computational model of the RI.EDN complex, also have no marked impact. Overall, the losses in affinity for the single-residue variants examined account for only approximately 25% of the free energy of binding for the complex. However, multisite mutagenesis of RI reveals strong superadditivity of mutational effects, indicating that part of this shortfall reflects negative cooperativity. Replacement of Tyr434 together with Asp435 or Tyr437 increases K(i) by 540- and 290-fold, respectively. Thus, the C-terminal region of RI again plays an important role in ligand recognition, although probably smaller than for binding RNase A and Ang. Simultaneous substitutions of three neighboring tryptophans (261, 263, and 318) on RI attenuate affinity even more dramatically (by 4900-fold), indicating that the interactions of this RI region also contribute a considerable amount of the binding energy for the EDN complex. These findings highlight the potential importance of cooperativity in protein-protein interactions and the consequent limitations of single-site mutagenesis for assessing interface energetics.

Tool command language automation of the modular ion cyclotron data acquisition system (MIDAS) for data-dependent tandem Fourier transform ion cyclotron resonance mass spectrometry

This manuscript describes the addition of data-dependent automation to the modular ion cyclotron resonance data acquisition system (MIDAS). The automation is made possible by developments and incorporation of a tool command language (Tcl) interpreter for automated acquisition. To accomplish the automation, real-time generation of excitation waveforms and scriptable data post-processing has been implemented into the MIDAS source code. In addition a new excitation event has also been added to allow for run-time generation of a single notch stored waveform inverse Fourier transform (SWIFT) excitation event. Examples of these new features and discussion of their enhancement to the existing data station are presented.

Lys40 but not Arg143 influences selectivity of angiotensin conversion by human alpha-chymase

Human alpha-chymase is an efficient angiotensin (AT) converting enzyme, selectively hydrolyzing AT I at Phe8 to generate bioactive AT II, which can promote cardiac hypertrophy, vascular stenosis, and hypertension. Some related enzymes, such as rat beta-chymase 1, are much less selective, destroying AT by cleaving at Tyr4. Comparisons of chymase structure and activity led to speculation that interaction between AT and the side chain of Lys40 or Arg143 accounts for the human enzyme's marked preference for Phe8 over Tyr4. To test these hypotheses, we compared AT hydrolysis by wild-type chymase with that by mutants changing Lys40 or Arg143 to neutral residues. Lys40 was exchanged for alanine, the residue found in canine alpha- and rat beta-chymase 1, the latter being dramatically less selective for hydrolysis at Phe8. Arg143 was exchanged for glutamine found in rat beta-chymase 1. The Lys40Ala mutant is a dog-like enzyme retaining strong preference for Phe8 but with Tyr4 hydrolytic rates enhanced 16-fold compared to wild-type human enzyme. Thus, of 40 residues mismatched between dog and human enzymes, a single residue accounts for most of the difference in specificity between them. The Arg143Gln mutant, contrary to prediction, remains highly Phe8-selective. Therefore, Lys40, but not Arg143, contributes to human chymase's remarkable preference for AT II generation over destruction.

Synthesis and pharmacological properties of TOAC-labeled angiotensin and bradykinin analogs

Angiotensin II (AngII) and bradykinin (BK) derivatives containing the TOAC (2,2,6,6-tetramethylpiperidine-N-oxyl-4-amino-4-carboxylic acid) spin label were synthesized by solid phase methodology. Ammonium hydroxide (pH 10, 50 degrees C, l h) was the best means for reverting nitroxide protonation occurring during peptide cleavage. EPR spectra yielded rotational correlation times for internally labeled analogs that were nearly twice as large as those of N-terminally labeled analogs. Except for TOAC(1)-AngII and TOAC(0)-BK, which showed high intrinsic activities, other derivatives were inactive in smooth muscle preparations. These active paramagnetic analogs may be useful for conformational studies in solution and in the presence of model and biological membranes.

Atmospheric pressure laser desorption/ionization on porous silicon

A recently developed commercial atmospheric pressure matrix-assisted laser desorption/ionization (AP-MALDI) source (MassTech, Inc.) was modified to adopt commercially available DIOS plates (Mass Consortium Corp.) for the studies of laser desorption from the surface of porous silicon under atmospheric pressure conditions. The feasibility of atmospheric pressure laser desorption/ionization from the surface of porous silicon (AP-DIOS) was demonstrated. The advantages of this new AP-DIOS technique include reasonably good sensitivity (subpicomole range for standard peptide mixtures), simplicity of sample preparation, uniformity of target spots and the absence of matrix peaks in the spectra. The AP-DIOS source was interfaced with a commercial ion trap (LCQ Classic, Thermo Finnigan) which additionally provides a unique MS(n) capability. The AP-DIOS spectrum of 250 fmol of unseparated tryptic digest of bovine serum albumin (BSA) was compared with that of AP-MALDI for the same compound. AP-DIOS offers significantly better coverage for the digest components in the mass range 200-1000 Da. The combined data of both techniques enabled us to nearly double the number of matched peaks in BSA digest analysis compared with AP-DIOS or AP-MALDI analysis separately.

The purification and characterization of an 88-kDa Porphyromonas endodontalis 35406 protease

A Porphyromonas endodontalis ATCC 35406 protease was purified from Triton X-114 cell extracts by preparative SDS-PAGE followed by electroelution. The purified enzyme exhibits a molecular size of 88 kDa and was dissociated into two polypeptides of 43 and 41 kDa upon heating in the presence of sodium dodecyl sulfate with or without a reducing agent. The protease (pH optimum 7.5-8.0) degraded the extracellular matrix proteins fibrinogen and fibronectin. Collagen IV was also degraded at 37 degrees C but not at 28 degrees C. The protease also cleaved the bioactive peptide angiotensin at amino acid residue phenylalanine-8 and tyrosine-4 but failed to hydrolyze bradykinin, vasopressin and synthetic chromogenic substrates with phenylalanine or tyrosine at the P1 position. In addition, two peptidases were detected in P. endodontalis cells: a proline aminopeptidase that remained associated with the cell pellet after detergent extraction and peptidase/s that partitioned into the Triton X-114 phase after phase separation and degraded the bioactive peptides bradykinin and vasopressin. These P. endodontalis peptidases and proteases may play an important role in both the nutrition and pathogenicity of these assacharolytic microorganisms. The inactivation of bioactive peptides and degradation of extracellular matrix proteins by bacterial enzymes may contribute to the damage of host tissues accompanied with endodontic infections.

Cardiovascular regulation in TGR(mREN2)27 rats: 24h variation in plasma catecholamines, angiotensin peptides, and telemetric heart rate variability

Dysfunction of the sympathetic nervous system might play an important role in disturbed 24h blood pressure regulation in transgenic hypertensive TGR (mREN2)27 (TGR) rats. Our study was performed to determine possible differences in activity of the sympathetic nervous system in TGR rats in comparison to their normotensive Sprague-Dawley (SPRD) controls; we measured plasma catecholamine and angiotensin concentrations throughout 24h under synchronized light-dark 12h:12H (LD 12:12) conditions. In the TGR rat strain, rhythms of plasma catecholamines were blunted, and the concentrations were significantly decreased. In addition, TGR rats showed increased plasma angiotensin I and II concentrations without any significant rhythm. An impaired autonomic regulation was confirmed by monitoring heart rate variability in TGR rats. Data showed that the TGR rat strain is characterized by a reduction in plasma catecholamines and an increase in angiotensin peptides. At present, it is not clear whether the reduction in catecholamines represents a decrease in sympathetic tone mediated by baroreflex activation or an increased catecholamine turnover induced by elevated angiotensin II. However, the blunted, but normally phased, rhythms in plasma catecholamines in TGR rats make it unlikely that the sympathetic nervous system is mainly responsible for the inverse circadian blood pressure rhythm in the transgenic strain.

Time-of-flight secondary ion mass spectrometry of matrix-diluted oligo- and polypeptides bombarded with slow and fast projectiles: positive and negative matrix and analyte ion yields, background signals, and sample aging

Human angiotensin II, chain B of bovine insulin, and porcine insulin were determined by time-of-flight secondary ion mass spectrometry under impact of approximately 25 keV Xe+ and SF5+ ion beams and approximately 100 MeV 252Cf fission fragments. Matrix-embedded samples, dissolved in a large surplus of alpha-cyano-4-hydroxycinnamic acid, were prepared by nebulizer spray deposition, neat samples by the droplet technique. It is shown that the status of the sample can be assessed by evaluating the matrix-specific features of the mass spectra. The beneficial effect of matrix isolation was small for angiotensin but large for the insulin samples, which did not show parent peaks from neat material. Negative ion yields under SF5+ impact were up to a factor of 50 higher than with Xe+. For positive secondary ions, the enhancement was much smaller. The mass spectra produced by slow ion beams or fast fission fragments were qualitatively similar. Quantitative differences include the following: with fast projectiles the yields were about 10-30 times higher than with slow ions, but similar for negative ion emission under SF5+ bombardment; the analyte-to-matrix yield ratios were higher with slow ions and up to 250 times higher than the molar analyte concentration; for analyte ions the peak-to-background ratios were higher using slow projectiles; the fraction of carbon-rich collisionally formed molecular ions was much higher with fast projectiles. Sample aging in vacuum for up to five weeks strongly reduced the yield of protonated analyte molecules ejected by slow ion impact, but not of deprotonated species. Hence protonation seems to correlate with sample "wetness" or the presence of volatile proton-donating additives.

Binding and signaling of angiotensin-(1-7) in bovine kidney epithelial cells involves the AT(4) receptor

Angiotensin-(1-7) decreased mitogen-activated protein (MAP) kinase (Erks) activation in cultured Mardin-Darby bovine kidney (MDBK) epithelial cells. Also, saturable, high-affinity (125)I-angiotensin-(1-7) binding was detected in MDBK cell membranes. Together, the data suggested the possible presence of an angiotensin-(1-7) receptor. However, ligand structure-binding studies revealed that angiotensin-(3-7) and AT(4) receptor ligands competed with high-affinity for (125)I-angiotensin-(1-7) binding. Furthermore, angiotensin-(3-7) and AT(4) receptor ligands decreased MAP kinase activation in MDBK cells. These results demonstrate that NH(2)-terminal-deleted metabolites of angiotensin-(1-7) can bind with high affinity to the AT(4) receptor and regulate the MAP kinase/Erk signaling pathway in renal epithelial cells.

Coupling capillary high-performance liquid chromatography to matrix-assisted laser desorption/ionization mass spectrometry and N-terminal sequencing of peptides via automated microblotting onto membrane substrates

To minimize low-quantity sample handling for protein sequencing and matrix-assisted laser desorption/ionization (MALDI) mass spectrometry, a system consisting of an HPLC interfaced to an automated blotting device was used for off-line sample collection. Typically, protein digests are separated by reverse-phase HPLC and the resulting peptide fractions are pooled, concentrated, and then subjected to N-terminal sequence analysis. Obtaining unambiguous sequence from peptides derived from protein digestion at subpicomole levels requires careful sample handling to prevent loss of sample. In cases where multiple sequences are present, a secondary method such as mass spectrometry is needed to confirm the identity of the peptides. To minimize sample handling, commercial microblotting instruments have become available to deposit peptides directly onto polyvinylidene difluoride (PVDF) membrane for automated N-terminal sequence analysis. In order to adapt this technology to mass spectrometry, we investigated the use of MALDI-MS compatible membranes such as Teflon and polyethylene (PE) as the blotting media for fraction collection. Using a panel of standard peptides as well as protein digests, we demonstrate that peptides separated by capillary HPLC can be collected directly onto Teflon or PE and detected into the femtomole range. Furthermore, detailed sequence analysis could be obtained by postsource decay fragmentation spectra of individual peptides blotted onto either PE or Teflon. Due to the high sensitivity of the MALDI-MS from these membranes, it was discovered that the small amount of peptide that passed through the PVDF membrane during a collection of peptides for N-terminal sequencing was sufficient to be collected and mass analyzed from a second underlying MALDI-MS compatible membrane. Therefore, from a single HPLC separation, samples could be collected onto both PVDF for traditional N-terminal sequencing and PE or Teflon for MALDI-MS. We demonstrate the general utility of this method for sequencing peptides from a tryptic digestion at subpicomole levels and for identifying unknown proteins separated by 2-dimensional gel electrophoresis. The ability to generate both N-terminal sequence and confirmatory mass information from multiple peptides in a single separation greatly improves the reliability and the accuracy of protein characterization at subpicomole levels.

[Structure of the renin-angiotensin system and its significance in the body]

Renin-angiotensin system (RAS) is a methabolic pathway producing octapeptid angiotensin II (AII) with vasoconstrictive effects, which is also involved in the regulation of water homeostasis and electrolyte balance in the organism. Genes encoding individual components of the RAS can be considered as "candidate genes" for some cardiovascular diseases e.g. hypertension or myocardial infarction. Besides the circulating RAS, also local tissue systems exist. Local RASs are involved in various physiological functions e.g. regulation of growth and proliferation, apoptosis or signal transmission where AII serves as the neurotransmitter.

Effects of ANG II and III and angiotensin receptor blockers on nasal salt gland secretion and arterial blood pressure in conscious Pekin ducks (Anas platyrhynchos)

The vertebrate renin-angiotensin system controls cardiovascular, renal and osmoregulatory functions. Angiotensin II (ANG II) is the most potent hormone of the RAS but in some vertebrate animals angiotensin III (Val4-ANG III) may be a hormone. We studied the effects of some angiotensins and mammalian ANG II receptor antagonists on nasal salt gland function and arterial blood pressure in conscious white Pekin ducks. Nasal salt gland fluid secretion (NFS) was induced by a 10 ml.kg-1 bw i.v. injection of a NaCl solution (1000 mosmol.kg-1 H2O) and maintained by a continuous i.v. infusion of the same solution at a rate of 0.97 ml.min-1. There was a positive linear correlation between nasal fluid [Na+] and osmolality, between [Na+] and [K+], and also between the rate of NFS and [Na+] and [K+]. [Asp1, Val5]-ANG II (1 nmol.kg-1 i.v.) inhibited NFS but did not change ionic concentrations. Val4-ANG III (1 or 5 nmol.kg-1) and ANG I (1-7) (20 nmol.kg-1) had no effect on NFS. [Sar1, Ile8]-ANG II (SARILE) acted as an ANG II receptor agonist and resulted in a prolonged and complete inhibition of NFS. The AT1 receptor antagonist, losartan (DuP 753) and the AT2 receptor antagonist, PD 123319 both failed to block the inhibitory effect of [Asp1, Val5]-ANG II on the nasal salt glands. [Asp1, Val5]-ANG II (2 nmol.kg-1 i.v.) increased mean arterial blood pressure (MABP), whereas the same dose of [Asn1, Val5]-ANG II (teleost) had only 30% of the pressor potency of the avian ANG II. Neither 1 nor 5 nmol.kg-1 of Val4-ANG III i.v. nor 20 nmol.kg-1 of ANG I (1-7) had any measurable effect on MABP. SARILE blocked completely the pressor response to [Asp1, Val5]-ANG II but the AT1 antagonists losartan and CGP 48933 and the AT2 antagonist PD 123319 all failed to block the pressor response to [Asp1, Val5]-ANG II. These results have substantiated an important role of the nasal salt gland in potassium regulation and highlighted a pharmacological dimorphism of saralasin, namely agonist and antagonist to angiotensin II-mediated inhibition of nasal salt gland function and pressor response, respectively. Using specific nonpeptidergic angiotensin II receptor antagonists, we have confirmed the distinct pharmacology of the avian angiotensin II receptors in a nongallinaceous species and the absence of significant angiotensin I (1-7) and angiotensin II effects on the cardiovascular system and nasal salt gland.

Angiotensin III and IV activation of the brain AT1 receptor subtype in cardiovascular function

The present investigation determined that native angiotensins II and III (ANG II and III) were equipotent as pressor agents when ICV infused in alert rats, whereas native angiotensin IV (ANG IV) was less potent. An analogue of each of these angiotensins was prepared with a hydroxyethylamine (HEA) amide bond replacement at the N-terminus, yielding additional resistance to degradation. These three angiotensin analogues, HEA-ANG II, HEA-ANG III, and HEA-ANG IV, were equivalent with respect to maximum elevation in pressor responses when ICV infused; and each evidenced significantly extended durations of effect compared with their respective native angiotensin. Comparing analogues, HEA-ANG II had a significantly longer effect compared with HEA-ANG III, and HEA-ANG IV, whereas the latter were equivalent. Pretreatment with the AT1 receptor subtype antagonist, Losartan (DuP753), blocked subsequent pressor responses to each of these analogues, suggesting that these responses were mediated by the AT1 receptor subtype. Pretreatment with the specific AT4 receptor subtype antagonist, Divalinal (HED 1291), failed to influence pressor responses induced by the subsequent infusion of these analogues. These results suggest an important role for Ang III, and perhaps ANG IV, in brain angiotensin pressor responses mediated by the AT1 receptor subtype.

Role of angiotensinogen in the genetics of essential hypertension

Although essential hypertension has long been recognized to involve a strong genetic predisposition, the genes that increase susceptibility remain virtually unknown. With recent advances in molecular biology and statistical methods, it has become feasible to study candidate genes which may contribute to the pathogenesis of essential hypertension in humans. Recently, the angiotensinogen (AGT) locus was demonstrated to exhibit genetic linkage and association to essential hypertension and to preeclampsia. While the statistical evidence that mutations of the AGT gene or a neighboring gene contribute to the development of hypertension is strong, the exact mechanism(s) by which these mutations affect the regulation of blood pressure (BP) is unknown. Increasing attention is now being focused on elucidating this mechanism(s).

Role of the NH2-terminal domain of angiotensin II (ANG II) and [Sar1]angiotensin II on conformation and activity. NMR evidence for aromatic ring clustering and peptide backbone folding compared with [des-1,2,3]angiotensin II

The role of the NH2 termini of angiotensin II (ANG II) and [Sar1]ANG II on conformation and activity were examined by proton NMR two-dimensional-J-correlated spectroscopy and one-dimensional nuclear Overhauser effect studies in the relatively nonpolar "receptor-simulating" environment provided by dimethyl sulfoxide-d6, using the biologically inactive COOH-terminal pentapeptide [des1,2,3]ANG II as control. Irradiation of C alpha H, C2H, and C4H proton resonances in ANG II and [Sar1]ANG II resulted in enhancements of Tyr and Phe ring proton resonances, indicating that the three aromatic rings cluster together. Very strong enhancements (17-22%) of the C alpha Y proton resonance in ANG II and [Sar1]ANG II upon irradiation of the C alpha H proton resonance, and vice versa, revealed that a Tyr-Ile-His bend is a predominant feature of the conformation of the two agonists. In contrast, saturation of the C alpha H and C alpha Y proton resonances in the control pentapeptide [des-1,2,3]ANG II did not produce, respectively, any C alpha Y or C alpha H proton nuclear Overhauser effect enhancement, illustrating the absence of a Tyr-Ile-His bend in the truncated ANG II peptide. The present findings indicate that the NH2-terminal domain of ANG II appears to have an essential role in generating the biologically active charge relay conformation of the hormone.

Three-dimensional recognition requirements for angiotensin agonists: a novel solution for an old problem

A novel approach involving the search for a common spatial arrangement of functionally important (pharmacophoric) groups in low-energy conformers of AT and its active analogs has been employed to determine the receptor-bound ("biologically active") conformation(s) for angiotensin II (Asp1-Arg2-Val3-Tyr4-Val/Ile5-His6-Pro7-Phe8, AT). The four pharmacophoric groups for AT are the aromatic moieties of Tyr4, His6 and Phe8 residues, as well as the C-terminal carboxyl. Geometrical comparison of the sets of low-energy backbone conformers for AT itself, and two analogs, [(alpha Me)Phe4]-AT and [Pro5]-AT, yielded the model for the receptor-bound conformation(s), which is compatible with cyclic AT analogs possessing substantial binding to specific AT receptors. A new analog, [D-Tyr4, Pro5]-AT, was designed based on the proposed receptor-bound conformation. The analog showed a good affinity (IC50 = 42.8 nM) towards specific AT receptors.

[The current concept of the renin-angiotensin system]

Traditionally, the renin angiotensin system (RAS) has been thought of primarily as an endocrine system that delivers circulating angiotensin II to target tissues. This peptide is a potent vasoconstrictor and a primary stimulus for aldosterone secretion. In addition, angiotensin II has many other targets such as kidney, heart and brain, from which it elicits different specific responses. Numerous studies using pharmacologic or immunologic inhibitors of the system have shown an important role for the circulating RAS in blood pressure and electrolyte as well as fluid homeostasis. Although it acts as a classical circulating endocrine system, there is increasing evidence to show that the RAS may also have an important local autocrine or paracrine role in a variety of tissues since it has been shown that the RAS components are present in all of these tissues. In addition, several investigators have recently demonstrated the expression of renin and angiotensinogen genes in multiple tissues, which strongly suggests that these proteins are locally synthesized. Moreover, it has been demonstrated that tissue RAS is independently regulated from circulating system under different pathological situations such as hypertension. As a result, the concept of the RAS as an endocrine system alone is in question. Locally expressed RAS may be involved with the regulation of individual tissue function independent of the circulating counterpart. However, the importance of these local systems in circulatory control and body volume homeostasis has yet to be defined. It has been proposed that the main function of the circulating RAS is to provide short-term cardiorenal homeostasis. The tonic control (e.g., adrenal and kidney) is influenced by the intrinsic tissue RAS. This new concept provides a broader outlook on the RAS and challenges its traditional endocrine role.