Detecting low-abundance vasoactive peptides in plasma: progress toward absolute quantitation using nano liquid chromatography-mass spectrometry.

Profiling changes in the concentration of functionally related peptide hormones is critical to understanding the etiology of many diseases and therapies. We present novel data using nano liquid chromatography-mass spectrometry (LC-MS) to simultaneously measure a select group of vasoactive peptides (angiotensin, bradykinin, and related hormones) in 50-microl plasma samples, enabling repeated sampling in rodent models. By chromatographically resolving target peptides and using multiple reaction monitoring to enhance MS sensitivity, linear responses down to 10(-17) mol were achieved. Purification of plasma peptides by either methanol precipitation or off-line high-performance liquid chromatography (HPLC) fractionation enabled the detection of endogenous peptides and revealed approaches for enhancing recovery. As proof of principle, seven vasoactive peptides were profiled before, during, and after acute angiotensin-converting enzyme (ACE) inhibition in an anesthetized rat. Of note was an apparent 10-fold increase in vasodilatory bradykinin that reversed after drug infusion but relatively minor changes in angiotensin II levels. Targeted MS analysis used to profile functionally related peptides or other analytes will greatly enhance our ability to define the sequence of events regulating complex and dynamic physiological processes.

Inhibition of inducible nitric oxide synthase alters Thy-1 glomeruonephritis in rats.

BACKGROUND/AIMS: Inducible nitric oxide (NO) synthase (iNOS) generated NO increases in the early phase of Thy-1 glomerulonephritis concurrently with mesangiolysis and reduction in glomerular filtration rate (GFR). Activation of ornithine decarboxylase (ODC), the rate-limiting enzyme of polyamine biosynthesis, is upregulated to allow mesangial cell proliferation which constitutes the repair phase in this model. Antiproliferative high-output NO generation inhibits proproliferative ODC activity, thereby temporally separating the early 'bactericidal' phase from the later 'growth' repair phase. METHODS: Renal function, ODC protein expression, arginine, ornithine, and polyamines by high-performance liquid chromatography, and histological changes were assessed in rats after induction of Thy-1 nephritis with and without NOS inhibition. RESULTS: Thy-1 significantly reduced the GFR relative to untreated controls. Treatment with a nonspecific NOS inhibitor, but not a selective iNOS inhibitor, further decreased the GFR at day 1. This implys a protective role for constitutive NOS in the early phase of this inflammatory model. Selective iNOS inhibition abrogated increased plasma NO(2)/NO(3) levels in Thy-1 glomerulonephritis, but did not significantly reduce mesangiolysis. However, inhibition of iNOS did result in significantly more nuclei/glomerulus during the proliferative phase, increasing the hypercellularity component of this disease model. This correlates with increased levels of polyamines, ornithine, and arginine beyond those observed with Thy-1 administration alone. CONCLUSIONS: These studies provide evidence that NO generation from different NOS isoforms can be protective in the temporal course of Thy-1 glomerulonephritis. The finding that iNOS attenuates hypercellularity in the repair phase of this inflammatory model adds cautionary insight in the therapeutic use of selective iNOS inhibition in vivo.

Choline transporter 1 maintains cholinergic function in choline acetyltransferase haploinsufficiency.

Choline acetyltransferase (ChAT), the enzyme that synthesizes the neurotransmitter acetylcholine (ACh), is thought to be present in kinetic excess in cholinergic neurons. The rate-limiting factor in ACh production is the provision of choline to ChAT. Cholinergic neurons are relatively unique in their expression of the choline transporter 1 (CHT1), which exhibits high-affinity for choline and catalyzes its uptake from the extracellular space to the neuron. Multiple lines of evidence indicate that the activity of CHT1 is a key determinant of choline supply for ACh synthesis. We examined the interaction of ChAT and ChT activity using mice heterozygous for a null mutation in the Chat gene (Chat+/-). In these mice, brain ChAT activity was reduced by 40-50% relative to the wild type, but brain ACh levels as well as ACh content and depolarization-evoked ACh release in hippocampal slices were normal. However, the amount of choline taken up by CHT1 and ACh synthesized de novo from choline transported by CHT1 in hippocampal slices, as well as levels of CHT1 mRNA in the septum and CHT1 protein in several regions of the CNS, were 50-100% higher in Chat+/- than in Chat+/+ mice. Thus, haploinsufficiency of ChAT leads to an increased expression of CHT1. Increased ChT activity may compensate for the reduced ChAT activity in Chat+/- mice, contributing to the maintenance of apparently normal cholinergic function as reflected by normal performance of these mice in several behavioral assays.

Increased expression of ornithine decarboxylase in distal tubules of early diabetic rat kidneys: are polyamines paracrine hypertrophic factors?

Polyamines are small biogenic molecules that are essential for cell cycle entry and progression and proliferation. They can also contribute to hypertrophy. The activity of ornithine decarboxylase (ODC), the rate-limiting enzyme in polyamine biosynthesis, increases in the early diabetic kidney to enable renal hypertrophy. Inhibition of ODC in early diabetes attenuates diabetic renal hypertrophy and glomerular hyperfiltration. The current studies examine the temporal profile of renal ODC protein expression and localization, intrarenal polyamine levels, and sites of proliferation in kidneys of rats during the first 7 days of streptozotocin diabetes. ODC mRNA and protein content were increased in diabetic kidneys. High-performance liquid chromatography analysis showed increased intrarenal polyamine concentrations peaking after 24 h of diabetes. A subsequent increase in the number of proliferating proximal tubular cells was detected by in vivo 5-bromodeoxyuridine (BrdU) incorporation on day 3. Surprisingly, immunohistochemical studies revealed that increased ODC protein was apparent only in distal nephrons, whereas the main site of diabetic kidney hypertrophy is the proximal tubule. These findings raise the possibility that polyamines produced in the distal nephron may mediate the early diabetic kidney growth of the proximal tubules via a paracrine mechanism.

Neuropeptidomic components generated by proteomic functions in secretory vesicles for cell-cell communication.

Diverse neuropeptides participate in cell-cell communication to coordinate neuronal and endocrine regulation of physiological processes in health and disease. Neuropeptides are short peptides ranging in length from ~3 to 40 amino acid residues that are involved in biological functions of pain, stress, obesity, hypertension, mental disorders, cancer, and numerous health conditions. The unique neuropeptide sequences define their specific biological actions. Significantly, this review article discusses how the neuropeptide field is at the crest of expanding knowledge gained from mass-spectrometry-based neuropeptidomic studies, combined with proteomic analyses for understanding the biosynthesis of neuropeptidomes. The ongoing expansion in neuropeptide diversity lies in the unbiased and global mass-spectrometry-based approaches for identification and quantitation of peptides. Current mass spectrometry technology allows definition of neuropeptide amino acid sequence structures, profiling of multiple neuropeptides in normal and disease conditions, and quantitative peptide measures in biomarker applications to monitor therapeutic drug efficacies. Complementary proteomic studies of neuropeptide secretory vesicles provide valuable insight into the protein processes utilized for neuropeptide production, storage, and secretion. Furthermore, ongoing research in developing new computational tools will facilitate advancements in mass-spectrometry-based identification of small peptides. Knowledge of the entire repertoire of neuropeptides that regulate physiological systems will provide novel insight into regulatory mechanisms in health, disease, and therapeutics.

The arginine metabolite agmatine protects mitochondrial function and confers resistance to cellular apoptosis.

Agmatine, an endogenous metabolite of arginine, selectively suppresses growth in cells with high proliferative kinetics, such as transformed cells, through depletion of intracellular polyamine levels. In the present study, we depleted intracellular polyamine content with agmatine to determine if attrition by cell death contributes to the growth-suppressive effects. We did not observe an increase in necrosis, DNA fragmentation, or chromatin condensation in Ha-Ras-transformed NIH-3T3 cells administered agmatine. In response to Ca(2+)-induced oxidative stress in kidney mitochondrial preparations, agmatine demonstrated attributes of a free radical scavenger by protecting against the oxidation of sulfhydryl groups and decreasing hydrogen peroxide content. The functional outcome was a protective effect against Ca(2+)-induced mitochondrial swelling and mitochondrial membrane potential collapse. We also observed decreased expression of proapoptotic Bcl-2 family members and of execution caspase-3, implying antiapoptotic potential. Indeed, we found that apoptosis induced by camptothecin or 5-fluorourocil was attenuated in cells administered agmatine. Agmatine may offer an alternative to the ornithine decarboxylase inhibitor difluoromethyl ornithine for depletion of intracellular polyamine content while avoiding the complications of increasing polyamine import and reducing the intracellular free radical scavenger capacity of polyamines. Depletion of intracellular polyamine content with agmatine suppressed cell growth, yet its antioxidant capacity afforded protection from mitochondrial insult and resistance to cellular apoptosis. These results could explain the beneficial outcomes observed with agmatine in models of injury and disease.

The antiproliferative effects of agmatine correlate with the rate of cellular proliferation.

Polyamines are small cationic molecules required for cellular proliferation. Agmatine is a biogenic amine unique in its capacity to arrest proliferation in cell lines by depleting intracellular polyamine levels. We previously demonstrated that agmatine enters mammalian cells via the polyamine transport system. As polyamine transport is positively correlated with the rate of cellular proliferation, the current study examines the antiproliferative effects of agmatine on cells with varying proliferative kinetics. Herein, we evaluate agmatine transport, intracellular accumulation, and its effects on antizyme expression and cellular proliferation in nontransformed cell lines and their transformed variants. H-ras- and Src-transformed murine NIH/3T3 cells (Ras/3T3 and Src/3T3, respectively) that were exposed to exogenous agmatine exhibit increased uptake and intracellular accumulation relative to the parental NIH/3T3 cell line. Similar increases were obtained for human primary foreskin fibroblasts relative to a human fibrosarcoma cell line, HT1080. Agmatine increases expression of antizyme, a protein that inhibits polyamine biosynthesis and transport. Ras/3T3 and Src/3T3 cells demonstrated augmented increases in antizyme protein expression relative to NIH/3T3 in response to agmatine. All transformed cell lines were significantly more sensitive to the antiproliferative effects of agmatine than nontransformed lines. These effects were attenuated in the presence of exogenous polyamines or inhibitors of polyamine transport. In conclusion, the antiproliferative effects of agmatine preferentially target transformed cell lines due to the increased agmatine uptake exhibited by cells with short cycling times.

Acute renal response to LPS: impaired arginine production and inducible nitric oxide synthase activity.

We have previously shown in rats that lipopolysaccharide (LPS) causes both decreased renal perfusion and kidney arginine production before nitric oxide (NO) synthesis, resulting in a >30% reduction in plasma arginine. To clarify the early phase effects of LPS, we asked the following two questions: 1) is the rapid change in renal arginine production after LPS simply the result of decreased substrate (i.e., citrulline) delivery to the kidney or due to impaired uptake and conversion and 2) is the systemic production of NO limited by plasma arginine availability after LPS? Arterial and renal vein plasma was sampled at 30-min intervals from anesthetized rats with or without citrulline or arginine (2 micromol.min(-1).kg(-1) iv) a dose with no effect on MAP, renal function, or NO production. Exogenous citrulline was quickly converted to arginine by the kidney, resulting in plasma levels similar to equimolar arginine infusion. Also, the increase in citrulline uptake resulted primarily from increased filtered load and reabsorption. In a separate series, citrulline was infused after LPS administration, verifying that citrulline uptake and conversion persists during impaired kidney function. Last, in rats given LPS, the elevation of plasma arginine had no discernable impact on mean arterial pressure, kidney function, or systemic NO production. This work demonstrates how arginine synthesis is normally "substrate limited" and explains how impaired kidney perfusion quickly results in decreased plasma arginine. However, contrary to in vitro studies, the significant reduction in extracellular arginine during the early phase response to LPS in vivo is not functionally rate limiting for NO production.

Regulatable acetylcholine-producing fibroblasts enhance cognitive performance.

Regulatable gene therapy systems provide a method to alter neurotransmitter levels in vivo. We developed a rodent fibroblast cell line expressing the choline acetyltransferase (ChAT) cDNA that is silenced by doxycycline (DOX) administration. The ability of the cell line to improve cognition was tested by grafting after cholinergic lesions. Ibotenic acid was injected bilaterally into the nucleus basalis of rats, which were distributed into three groups. One group received no treatment, while the second group received cortical transplants (Graft). The third group received identical grafts but was treated with DOX to turn off ChAT expression (Graft/DOX). An unlesioned group served as control. Water maze acquisition was significantly better in the Graft group compared to the Graft/DOX group, an effect also seen in the retention and spatial probe trials. However, cognitive enhancement was restricted to spatial tasks, as inhibitory avoidance or open-field activity measures were unchanged. Molecular and biochemical analyses confirmed that DOX regulated transgene transcription and ACh levels. This study demonstrates that regulatable gene therapy has therapeutic value for single-gene disorders and also provides a mechanism to deliver small molecules in a spatiotemporal pattern to delineate the role of these compounds in discrete behavioral tasks.

Kidney oxygen consumption, carbonic anhydrase, and proton secretion.

Oxygen consumed by the kidney (Q(O(2))) is primarily obligated to sodium reabsorption (T(Na)). The relationship of Q(O(2)) to T(Na) (Q(O(2))/T(Na)) may be altered by hormones and autacoids. To examine whether Q(O(2))/T(Na) depends on the mechanism of sodium reabsorption, we first evaluated the effects on Q(O(2)) and Q(O(2))/T(Na) of benzolamide (BNZ), a proximal diuretic that works by inhibiting membrane carbonic anhydrase. During BNZ infusion in anesthetized rats, Q(O(2)) increased by 50% despite a 25% decline in T(Na). However, BNZ failed to increase Q(O(2))/T(Na) when given along with the adenosine A1 receptor blocker, DPCPX, which inhibits basolateral Na-bicarbonate cotransport (NBC1), or EIPA, which inhibits sodium-hydrogen exchange (NHE). Incubating freshly harvested rat proximal tubules with BNZ also caused Q(O(2))to increase by 62%, an effect that was prevented by blocking the apical NHE3 with S3226. Blocking NBC1 or NHE3 in the proximal tubule will have opposite effects on cell pH, but both maneuvers should reduce active chloride transport. In conclusion, inhibiting membrane carbonic anhydrase in the proximal tubule increases Q(O(2)) and reduces the energy efficiency of sodium reabsorption by the kidney. This is not purely due to shifting the burden of reabsorption to a more expensive site downstream from the proximal tubule. Instead, increased cost may be incurred within the proximal tubule as the result of increased active chloride transport.

Oxygen consumption in the kidney: effects of nitric oxide synthase isoforms and angiotensin II.

BACKGROUND: Oxygen mitochondrial effects consumption by the kidney (Qo(2)), is linearly related to sodium reabsorption (T(na)), but recent studies suggest this relationship is variable and that metabolic efficiency (Qo(2)/T(na)) in kidney is regulated by hormonal factors. In the dog, nonselective inhibitors of nitric oxide synthase (NOS) increase Qo(2) and Qo(2)/T(na). Glomerular hemodynamic and reabsorptive consequences of NOS inhibition require angiotensin II (Ang II), implying an antagonistic relationship between nitric oxide and Ang II. Effects of NOS inhibition in the rat, the role of Ang II and the responsible NOS isoform have not been elucidated. METHODS: Kidney blood flow [renal blood flow (RBF)], glomerular filtration rate (GFR), and Qo(2)/T(na) were measured before and during intravenous administration of N(G)-monomethyl-l-arginine (L-NMMA), a nonselective NOS inhibitor, in control and losartan (Ang II receptor blocker)-treated rats and rats administered S-methyl-L-thiocitrulline (SMTC), a NOS-1 inhibitor. Effects of SMTC on oxygen consumption were also examined in freshly harvested proximal tubules. RESULTS: L-NMMA and high-dose SMTC decreased RBF, but L-NMMA + losartan and low-dose SMTC did not. Qo(2)/T(na) increased in both L-NMMA groups. Both low- and high-dose SMTC also increased Qo(2)/T(na). SMTC increased Qo(2) in proximal tubules in vitro at presumed lower levels of vectorial NaCl transport. Results suggest this effect was not mediated by influences on sodium transport alone. CONCLUSION: Nonselective NOS inhibition increases the oxygen costs of kidney function independent of Ang II. Kidney NOS-1 is responsible for these in vivo and in vitro effects. In vitro observations suggest that NOS-1 acts in part via effects on basal metabolism and mitochondrial function.

The complex role of nitric oxide in the regulation of glomerular ultrafiltration.

The complex role of nitric oxide in the regulation of glomerular ultrafiltration. Nitric oxide is an important neurohumoral modulator of glomerular ultrafiltration and renal hemodynamics. Multiple nitric oxide synthase (NOS) isoforms are present within the kidney. However, it is difficult to discern which NOS is most active from prior studies using non-selective NOS blockers. It is recently apparent that NOS activity is important to the activity of tubuloglomerular feedback (TGF) systems, systems that relate tubular reabsorption to the regulation of glomerular ultrafiltration. Neuronal (nNOS) or brain NOS (bNOS; NOS I) is present within the macula densa, the sensing element of TGF systems. Inhibition of NOS activity and specifically bNOS enhances TGF activity. The TGF system also adapts temporally and these events appear to be dependent upon up-regulation of activity of bNOS within the kidney. Temporal adaptation occurs within one to three hours whereby activation of TGF is followed by a gradual return of the glomerular filtration rate (GFR) and renal blood flow toward normal levels. After 24 hours of benzolamide treatment and withdrawal of this agent, glomerular filtration actually increases to supranormal levels and this is prevented by inhibition of bNOS activity. Factors regulating bNOS activity have not been fully clarified. We have recently observed N-methyl-d-aspartate (NMDA) receptors within the kidney that, when inhibited, result in major reductions in renal blood flow and GFR, suggesting an important role for the NMDA receptor in regulation of renal hemodynamics. Future studies will determine whether NMDA receptor is also an important regulator of bNOS activity and the TGF system.

Agmatine inhibits cell proliferation and improves renal function in anti-thy-1 glomerulonephritis.

Changes in the expression of alternate arginine metabolic pathways have been implicated in the pathogenesis of experimental glomerulonephritis. Agmatine, decarboxylated arginine, has been shown in vitro to suppress both inducible nitric oxide synthase and the rate-limiting enzyme of polyamine biosynthesis, ornithine decarboxylase (ODC). This study was undertaken to determine whether agmatine administration could reduce tissue injury by decreasing nitric oxide, and reduce cell proliferation, by diminishing ODC activity, in experimental mesangial proliferative glomerulonephritis (Thy-1 nephritis). Agmatine treatment (50 mg/kg per d intraperitoneally) in Thy-1 nephritis rats prevented a reduction in GFR at day 1. Agmatine treatment decreased nitric oxide production in Thy-1 nephritis rats by 23% and 41% at days 1 and 4, respectively. Agmatine treatment also reduced ODC activity and glomerular (3)H-thymidine incorporation on days 1, 4, and 7. Histologic evaluation revealed a decline in mesangial cell proliferation and extracellular matrix accumulation associated with agmatine treatment administered before or 24 h after Thy-1 antibody, and this was confirmed by a reduction in the number of cells expressing proliferating cell nuclear antigen on days 4 and 7. These studies provide the first in vivo evidence that agmatine administration can reduce cellular proliferation in Thy-1 nephritis and attenuate the initial reduction in renal function associated with this model.

Production of arginine by the kidney is impaired in a model of sepsis: early events following LPS.

Lipopolysaccharide (LPS) is used experimentally to elicit the innate physiological responses observed in human sepsis. We have previously shown that LPS causes depletion of plasma arginine before inducible nitric oxide synthase (iNOS) activity, indicating that changes in arginine uptake and/or production rather than enhanced consumption are responsible. Because the kidney is the primary source of circulating arginine and renal failure is a hallmark of septicemia, we determined the time course of changes in arginine metabolism and kidney function relative to iNOS expression. LPS given intravenously to anesthetized rats caused a decrease in mean arterial blood pressure after 120 min that coincided with increased plasma nitric oxide end products (NOx) and iNOS expression in lung and liver. Interestingly, impairment of renal function preceded iNOS activity by 30-60 min and occurred in tandem with decreased renal arginine production. The baseline rate of renal arginine production was approximately 60 micromol.h(-1).kg(-1), corresponding to an apparent plasma half-life of approximately 20 min, and decreased by one-half within 60 min of LPS. Calculations based on the systemic production and clearance show that normally only 5% of kidney arginine output is destined to become nitric oxide and that <25% of LPS-impaired renal production was converted to NOx in the first 4 h. In addition, we provide novel observations indicating that the kidney appears refractory to iNOS induction by LPS because no discernible enhancement of renal NOx production occurred within 4 h, and iNOS expression in the kidney was muted compared with that in liver or lung. These studies demonstrate that the major factor responsible for the rapid decrease in extracellular arginine content following LPS is impaired production by the kidney, a phenomenon that appears linked to reduced renal perfusion.