HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) All Versions of this Article: 290/4/R982    most recent 00346.2005v1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Web of Science (18) Citing Articles via Google Scholar Google Scholar Articles by Shi, Y. Articles by Cupples, W. A. Search for Related Content PubMed PubMed Citation Articles by Shi, Y. Articles by Cupples, W. A.

RENAL HEMODYNAMICS AND CARDIORENAL INTEGRATION

Tubuloglomerular feedback-dependent modulation of renal myogenic autoregulation by nitric oxide

¹Biology Department, Concordia University, and ²Lady Davis Institute for Medical Research, SMBD-Jewish General Hospital, Montreal, Quebec; ³Smooth Muscle Research Group, Faculty of Medicine, University of Calgary, Calgary, Alberta; ⁵Centre for Biomedical Research and Department of Biology, University of Victoria, Victoria, British Columbia, Canada; and ⁴Departments of Biomedical Engineering and Physiology, State University of New York Stony Brook, Stony Brook, New York

Submitted 16 May 2005 ; accepted in final form 14 November 2005

	ABSTRACT

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
Nonselective inhibition of nitric oxide (NO) synthase (NOS) augments myogenic autoregulation, an action that implies enhancement of pressure-induced constriction and dilatation. This pattern is not explained solely by interaction with a vasoconstrictor pathway. To test involvement of the Rho-Rho kinase pathway in modulation of autoregulation by NO, the selective Rho kinase inhibitor Y-27632 and/or the NOS inhibitor N-nitro-L-arginine methyl ester (L-NAME) were infused into the left renal artery of anesthetized rats. Y-27632 and L-NAME were also infused into isolated, perfused hydronephrotic kidneys to assess myogenic autoregulation over a wide range of perfusion pressure. In vivo, L-NAME reduced renal vascular conductance and augmented myogenic autoregulation, as shown by increased slope of gain reduction and associated phase peak in the pressure-flow transfer function. Y-27632 (10 µmol/l) strongly dilated the renal vasculature and profoundly inhibited autoregulation in the absence or presence of L-NAME in vivo and in vitro. Afferent arteriolar constriction induced by 30 mmol/l KCl was reversed (–92 ± 3%) by Y-27632. Phenylephrine caused strong renal vasoconstriction but did not affect autoregulation. Inhibition of neuronal NOS by N⁵-(1-imino-3-butenyl)-L-ornithine (L-VNIO) did not cause significant vasoconstriction but did augment myogenic autoregulation. Thus vasoconstriction is neither necessary (L-VNIO) nor sufficient (phenylephrine) to explain the augmented myogenic autoregulation induced by L-NAME. The effect of L-VNIO implicates tubuloglomerular feedback (TGF) and neuronal NOS at the macula densa in regulation of the myogenic mechanism. This conclusion was confirmed by the demonstration that systemic furosemide removed the TGF signature from the pressure-flow transfer function and significantly inhibited myogenic autoregulation. In the presence of furosemide, augmentation of myogenic autoregulation by L-NAME was significantly reduced. These results provide a potential mechanism to explain interaction between myogenic and TGF-mediated autoregulation.

kidney; blood flow; dynamics

Given the known targets of cGMP and, thus, NO (46) in vascular smooth muscle cells, it is not difficult to understand how NOS inhibition could cause strong renal vasoconstriction by, for instance, inhibition of large-conductance, Ca²⁺-sensitive K⁺ channels or voltage-sensitive K⁺ channels or by increased availability of L-type Ca²⁺ channels. All these channels have been implicated in responses to NOS inhibition in other beds (12, 40–42). However, it is unclear how NOS inhibition could affect any of these targets in a way that would augment myogenic vasodilatation. Another potential target of NO that could account for enhanced myogenic dilatation is Ca²⁺ sensitivity (4, 7). Regulation of Ca²⁺ sensitivity provides a plausible way in which NO could modulate myogenic autoregulation. When Ca²⁺ sensitivity is increased, smaller and, thus, faster excursions of intracellular Ca²⁺ concentration are required to achieve the same change in developed tension. Such an effect would be most apparent in vascular smooth muscle having rapid kinetics and dynamics, exactly the attributes of the afferent arteriole (10, 29, 32, 39). Recent studies have shown that activation of Rho kinase is the principal pathway leading to Ca²⁺ sensitization in vascular smooth muscle and that this occurs by phosphorylation and inactivation of myosin light chain phosphatase (43). Similarly, activation of myosin light chain phosphatase contributes importantly to vasodilatation induced by NO (4, 7).

The second issue, the source of NO that modulates myogenic autoregulation, has functional consequences, because all three NOS isoforms are constitutively present in kidney (34), so that any or all could contribute to autoregulation. A vascular source for NO, presumably produced by endothelial NOS (eNOS), is perhaps the simplest to explain and predicts a system driven by vascular shear stresses and circulating agonists. It is also likely that neuronal NOS (nNOS) at the macula densa is a significant source of NO that affects the microvasculature (17, 18, 27, 44). In this case, one would predict a linkage between tubular function and autoregulation as well as strong tubuloglomerular feedback (TGF)-myogenic interactions.

	METHODS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
The studies were approved by the Animal Care Committees of the SMBD-Jewish General Hospital (in vivo studies) and the University of Calgary (in vitro studies) and conducted under the guidelines promulgated by the Canadian Council on Animal Care. Experiments were performed in 10- to 14-wk-old male Wistar rats (in vivo studies) or Sprague-Dawley rats (in vitro studies) obtained from Charles River (Ste. Hyacinthe, QC, Canada). Dynamic autoregulation and renal vascular responses to NOS inhibition are identical in these strains (51), and the dynamics of renal autoregulation in the hydronephrotic kidney match those of the myogenic mechanism in vivo (9). Rats had free access to water and food at all times before experiments.

Procedures. Anesthesia was induced by 5% isoflurane in inspired gas (30% O₂-70% air). After induction, the anesthetic concentration was reduced to 2%. The animal was transferred to a servo-controlled, heated table to maintain body temperature at 37°C, intubated, and ventilated by a pressure-controlled small animal respirator (RSP 1002, Kent Scientific, Litchfield, CT) operating in respiratory-assist mode. During the 1-h postsurgical equilibration period, inspired anesthetic concentration was titrated to the minimum concentration that precluded a blood pressure response when the tail was pinched (i.e., 1%).

Cannulas were placed in the right femoral artery (PE-90 with narrowed tip) and vein (PE-50). A constant intravenous (iv) infusion delivered 1% of body weight per hour throughout the experiment and contained 2% charcoal-washed bovine serum albumin in normal saline. A fine Teflon cannula was placed in the left femoral artery and advanced into the abdominal aorta for subsequent placement in the left renal artery. The left kidney was approached by a left subcostal flank incision, immobilized in a plastic cup, and covered with plastic wrap. After the artery was stripped from hilus to aorta, the distal end of the Teflon cannula was manipulated into the renal artery. It received several separate lines for drug infusion and one line connected to a magnetic motor that was driven at 1.2 Hz. This provided alternating negative and positive pressure in the Teflon infusion cannula and served to mix the drugs with renal arterial blood, as shown by Parekh (37) and Cavarape et al. (6). Pilot experiments established that placement of the cannula tip into the renal artery or operation of the mixing pump had no discernible effect on blood pressure or RBF. The flow probe was placed around the renal artery as previously described (50–52); the probe head was fixed in place, and acoustic coupling was ensured by application of a gel based on surgical lubricant and NALCO 1181 as recommended by Transonic Systems. Femoral arterial pressure was measured by a pressure transducer (model TRN050; Kent) driven by an amplifier (model TRN005; Kent). RBF was measured by a transit time ultrasound flowmeter [model T401 (model 1PRB probe); Transonic Systems, Ithaca, NY].

To assess RBF dynamics in vivo, a motorized clamp was placed on the aorta between the right and left renal arteries and was used to increase the amplitude of pressure fluctuations, that is, to "force" blood pressure. The motor was driven by a program implemented in DT-VEE (Data Translation). Briefly, the program operates as a negative-feedback controller to maintain downstream pressure [renal perfusion pressure (RPP)] 15–20% below the spontaneous level of blood pressure. It iterates at 2 Hz, and at each iteration the target pressure is randomly changed within a predefined range, typically ±5% (50). In each period, the pressure drop across the occluder was adjusted so that drug actions could be compared at the same mean RPP.

Normally, experimental drugs were infused into the renal artery (ira) to minimize confounding systemic effects. Nonselective inhibition of NOS was achieved by N-nitro-L-arginine methyl ester (L-NAME; Sigma), which was delivered at 10 µg/min for 20 min and then at 3 µg/min for the remainder of the experiment. This dose duplicates the renal vascular effects of 10 mg/kg L-NAME delivered as an intravenous bolus, a dose that is saturating on mean arterial pressure (3). The selective Rho kinase inhibitor Y-27632 (19, 43, 48), a generous gift from Welfide, Japan, was delivered to achieve a nominal concentration of 10 µmol/l in renal arterial blood, with the assumption of an RBF of 6 ml/min. This concentration of Y-27632 provides essentially complete and highly selective blockade of Rho kinase (43). Preliminary studies showed that a delivered concentration of 20 µmol/l resulted in RPP too low for an autoregulation study and that 5 µmol/l Y-27632 produced some pressure reduction, indicating drug recirculation, but caused incomplete blockade of renal vascular responses to L-NAME. Two NOS isoform-selective inhibitors were used: N-[3-(aminomethyl)benzyl]acetamidine (1400W; Tocris Bioscience, Ellisville, MO), a highly selective inhibitor of inducible NOS (iNOS) (13), and the nNOS inhibitor N⁵-(1-imino-3-butenyl)-L-ornithine [L-VNIO; Alexis Biochemicals (Axxora), San Diego, CA], which is highly selective for nNOS vs. iNOS and moderately selective for nNOS vs. eNOS (2). Both are slow-onset inactivating inhibitors of their respective isoforms. 1400W was delivered for 30 min to achieve a nominal concentration of 5 µmol/l in renal arterial blood (13); then the infusion was stopped and data acquisition was begun. L-VNIO was infused to achieve a nominal concentration of 1 µmol/l in renal arterial blood together with 2 µmol/l L-arginine to minimize inhibition of eNOS. Data acquisition began 30 min after the start of the infusion, which continued until the end of the experiment. Similar doses and infusion protocols have been used previously (11).

In vivo experiments. Two experiments were performed to demonstrate that renal vasoconstriction, per se, has no effect on RBF dynamics and that the route of administration of the constrictor (iv or ira) also did not affect the result. In five rats, after a control recording was acquired, phenylephrine was infused at 10 µg·kg^–1·min^–1 iv. In another five rats, the control recording was followed by ira infusion of phenylephrine (1 µg·kg^–1·min^–1).

Two experiments were performed to assess the responses of renal vascular conductance and myogenic autoregulation to L-NAME in the absence and presence of selective Rho kinase inhibition by Y-27632. The first experiment employed seven rats. A 25-min control period (ira saline vehicle) was followed by ira of Y-27632 for 55 min and finally by 55 min of Y-27632 + L-NAME infusion. In each period, RPP was forced and data were acquired for the last 25 min. In the second experiment, the order of drug administration was reversed, so that L-NAME was given alone followed by L-NAME + Y-27632; eight rats were used.

Two experiments assessed the renal vascular responses to isoform-specific NOS blockade. In each case, a control period was followed by isoform-specific NOS inhibition and, subsequently, by infusion of L-NAME to provide a positive control. Eight rats received 1400W ira, and six rats received L-VNIO. Because the results of these experiments suggested an involvement of nNOS at the macula densa in myogenic autoregulation, a further experiment was performed using eight rats in which the initial control period was followed by iv furosemide infusion (5 mg/kg + 5 mg·kg^–1·h^–1 and 4 ml/h saline added to the infusion) and then by L-NAME (10 mg/kg iv).

In vitro experiments. Hydronephrotic kidneys were created by 6 wk of ureteral occlusion, harvested, and perfused as previously described with a DMEM-based perfusate plus control of PO₂, temperature, and pH (9, 26, 31, 32, 46). Perfusion pressure, which was monitored within the renal artery, was maintained at 80 mmHg. Afferent arteriolar diameter was sampled at 3 Hz over a 10- to 20-µm segment near the midpoint of the vessel and determined by online image processing. Mean diameter values were then averaged over the plateau of the response. All agents were added directly to the perfusate. A control period was followed by inclusion in the perfusate of L-NAME (100 µmol/l, n = 6) or Y-27632 (10 µmol/l, n = 6) and then by a third period in which both drugs were included in the perfusate. In each period, perfusion pressure was increased in 20-mmHg steps at 1-min intervals from 60 to 180 mmHg. An additional five hydronephrotic kidneys were perfused at 80 mmHg under control conditions after perfusate K⁺ concentration ([K⁺]) was increased isotonically to 30 mmol/l and then with 10 µmol/l Y-27632 added to the high-[K⁺] perfusate.

Data acquisition and analysis. The blood pressure and RBF signals were low-pass filtered at 20 Hz and sampled at 100 Hz online. Data segments of 1,311 s (2¹⁷ points) were band-pass filtered (0.004 and 1 Hz) using a fast Fourier transform (FFT)-inverse FFT filter with a rectangular window and subsampled to 3.125 Hz. Power spectra, transfer functions, and coherences based on the FFT were computed using standard algorithms as described previously (50–52) with 512 or 1,024 point segments shaped by the Hann window. The rate (slope) of gain reduction by a control system and the magnitude of the associated phase peak provide information about the internal dynamics of that system. A system that responds only to the level of the input variable will typically have a slope of gain reduction of 20 dB/decade and a phase peak of /4 rad at the corner frequency, whereas a system that responds to the level and also to the rate of change of the input variable will have a slope of 40 dB/decade and a phase peak of /2 rad (22, 33). Inhibition of NOS results in substantial increases in the slope of gain reduction by the myogenic mechanism and in the associated phase peak, changes that suggest development or marked enhancement of a rate-sensitive component (10, 23, 51, 52). A high coherence at any frequency indicates that the input and output signals are closely and linearly related; reduced coherence can indicate the presence of noise, unrelated signals, or increased dynamic complexity. Inhibition of NOS typically results in reduced coherence at frequencies slower than 0.1 Hz. Because coherence in this band was high before and, in some experiments, after L-NAME, we can exclude unrelated signals and noise as causes of the reduction of coherence. Thus we are able to use coherence in the frequency band from 0.05 to 0.08 Hz (Coh_05–08) as an indicator of dynamic complexity.

Differences within experiments were assessed by one-tailed, paired t-tests in the phenylephrine experiments, one-way repeated-measures ANOVA in the remaining in vivo experiments, and two-way repeated-measures ANOVA (drug x perfusion pressure) in the in vitro study as implemented in Statistica version 5.5 (Statsoft, Tulsa, OK). Contrast analysis was used to test drug 1 vs. control and drug 2 + drug 1 vs. drug 1. P < 0.05 was considered to indicate a significant difference. Values are means ± SE.

	RESULTS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
Results of the experiments using intravenous and ira infusion of phenylephrine are summarized in Table 1. Systemic infusion of phenylephrine increased blood pressure and reduced renal vascular conductance, whereas intrarenal infusion reduced only conductance. Coh_05–08 was reduced by ira, but not iv, phenylephrine from 0.92 ± 0.02 to 0.88 ± 0.03. This difference, although statistically significant (P = 0.026), is unlikely to be biologically relevant. The transfer function was not affected by phenylephrine in either experiment. In particular, neither the slopes of gain reduction by the myogenic mechanism nor the associated phase peaks were altered. Thus vasoconstriction, per se, did not affect RBF dynamics, consistent with previous results obtained in this laboratory with vasopressin (50, 51) and by others with ANG II (24). The slope of gain reduction and phase peak were significantly lower during intrarenal arterial than during intravenous infusion (both P < 0.01), suggesting that the presence of the intrarenal cannula could affect RBF dynamics.

Figures 1A and 2A show the RPP power spectra acquired in the experiments that assessed responses of RBF dynamics to L-NAME and Y-27632. RPP power spectra did not differ among periods and were also very similar in the two experiments, indicating that very similar inputs were achieved under all conditions. As shown in Figs. 1B and 2B, coherence between RPP and RBF was uniformly high at frequencies faster than 0.08 Hz and, during the control period, tended to decline at slower frequencies in both experiments. L-NAME alone reduced Coh_05–08 (P = 0.014), and Y-27632 significantly increased Coh_05–08 in the absence (P = 0.004) or presence (P = 0.001) of L-NAME. Admittance gains are shown in Figs. 1C and 2C, and admittance phases are shown in Figs. 1D and 2D. In the control periods of each experiment, there were discrete regions of gain reduction <0.2 and <0.04 Hz that, together with their associated phase peaks, reflect operation of the myogenic and TGF mechanisms, respectively. The slope of gain reduction by the myogenic system was significantly enhanced by L-NAME, and this enhancement was, as expected, accompanied by an increased phase peak, as summarized in Table 1. Autoregulation was markedly impaired by Y-27632 in the absence and presence of L-NAME. It is apparent in Figs. 1C and 2C that the discrete regions of gain reduction were much less obvious during infusion of Y-27632. This effect is summarized in Table 1, which shows that the slope of gain reduction by the myogenic mechanism and its associated phase peak were strongly reduced during Y-27632 infusion (all P < 0.001). Responses to L-NAME were almost completely inhibited by prior Y-27632 infusion, although L-NAME induced a small rise of phase peak in the presence of Y-27632.

View larger version (25K): [in this window] [in a new window]   Fig. 1. Renal perfusion pressure (RPP) and renal blood flow (RBF) dynamics during control, N-nitro-L-arginine methyl ester (L-NAME), and L-NAME + Y-27632 treatment. A: RPP power spectra, which were similar in the 3 periods. B: coherence between RPP and RBF, which was uniformly high at frequencies >0.1 Hz. Coherence at 0.05–0.08 Hz (Coh05–08) was reduced by L-NAME (P < 0.01) and subsequently increased by Y-27632 (P < 0.01). C and D: admittance gain and phase. Dashed lines in C are lines of best fit for the slope of gain reduction by the myogenic mechanism. Myogenic autoregulation was enhanced by L-NAME, as shown by increased slope of gain reduction and amplitude of phase peak centered at 0.1 Hz (both P < 0.05). Myogenic and TGF-mediated autoregulation were markedly inhibited during infusion of Y-27632, as shown by inhibition of gain reduction and almost flat phase spectrum (both P < 0.01 vs. L-NAME).

View larger version (23K): [in this window] [in a new window]   Fig. 2. RPP and RBF dynamics during control, Y-27632, and Y-27632 + L-NAME treatment. A: RPP power spectra, which were similar in the 3 periods. B: coherence between RPP and RBF, which was uniformly high at frequencies >0.1 Hz. Coh05–08 was increased by Y-27632 (P < 0.02), and subsequent infusion of L-NAME had no further effect. C and D: admittance gain and phase. Dashed lines in C are lines of best fit for the slope of gain reduction by the myogenic mechanism. There was strong inhibition of myogenic and TGF-mediated autoregulation by Y-27632, as shown by significant inhibition of gain reduction and almost flat phase spectrum (both P << 0.01). Subsequent infusion of L-NAME caused only a trivial, but significant (P < 0.05), increase of phase peak.

View larger version (27K): [in this window] [in a new window]   Fig. 3. Response of afferent arteriolar diameter to increased RPP. A: data from 6 hydronephrotic kidneys under control conditions, during perfusion with L-NAME, and during perfusion with L-NAME + Y-27632. Autoregulatory reduction of arteriolar diameter was evident in control and L-NAME periods but was abrogated by Y-27632. Arteriolar diameter differed significantly between control (or L-NAME) and Y-27632 periods at all pressures >80 mmHg. B: data from another 6 hydronephrotic kidneys in which sequence of drug infusions was reversed. Control record was acquired first, then Y-27632 and, finally, L-NAME. Autoregulatory diameter reduction is evident in control and was abrogated by Y-27632. Subsequent addition of L-NAME to the perfusate did not restore autoregulatory diameter reduction.

View larger version (28K): [in this window] [in a new window]   Fig. 4. RPP and RBF dynamics during control, 1400W, and 1400W + L-NAME periods. A: RPP power spectra, which were similar in the 3 periods. B: coherence between RPP and RBF. Coh05–08 was unchanged by 1400W and subsequently reduced by L-NAME (P < 0.01). C and D: admittance gain and phase. Average slopes of gain reduction by the myogenic mechanism are shown by dashed lines. Neither the slope of gain reduction by the myogenic mechanism nor the associated phase peak was altered by 1400W; L-NAME increased the slope of gain reduction (P = 0.027) and the associated phase peak (P = 0.01).

View larger version (30K): [in this window] [in a new window]   Fig. 5. RPP and RBF dynamics during control, N5-(1-imino-3-butenyl)-L-ornithine (L-VNIO) and L-VNIO + L-NAME treatment. A: RPP power spectra, which were similar in the 3 periods. B: coherence between RPP and RBF. Coh05–08, which was unchanged by L-VNIO and reduced by subsequent infusion of L-NAME (P < 0.01). C and D: admittance gain and phase. RBF dynamics were significantly affected by L-VNIO and L-NAME. Average slopes of gain reduction by the myogenic mechanism are shown by dashed lines. Slope of gain reduction by the myogenic mechanism was increased by L-VNIO (P = 0.002), as was the associated phase peak (P = 0.004); L-NAME had no additional effect on the slope of gain reduction but did increase further the associated phase peak (P = 0.014).

View larger version (23K): [in this window] [in a new window]   Fig. 6. RPP and RBF dynamics during control, furosemide, and furosemide + L-NAME periods. A: RPP power spectra, which were similar in the 3 periods. B: coherence between RPP and RBF. Coh05–08 was unchanged by furosemide and reduced by subsequent L-NAME (P < 0.01). C and D: admittance gain and phase. Average slopes of gain reduction by the myogenic mechanism are shown by dashed lines. RBF dynamics were altered by furosemide infusion, as shown by reduced slope of gain reduction and phase peak (both h P < 0.01), while L-NAME increased the slope of gain reduction and the amplitude of the associated phase peak (both P < 0.002).

	DISCUSSION

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

The phenylephrine experiments were included to assess the effect on RBF dynamics of reduced conductance per se and to provide a quality control study for intrarenal infusions. Intrarenal infusions with a mixing device (6, 37) were used to reduce the number and degree of confounding systemic effects and, importantly, to minimize changes in blood pressure and blood pressure fluctuation induced by vasoactive agents. The observation that use of an intrarenal arterial cannula reduces the efficiency of myogenic autoregulation is probably a consequence of the invasiveness of the procedure and is not unexpected. It is commonly observed that myogenic mechanisms are more susceptible than pharmacological responses to mechanical or other disruption. The major constraint imposed by the difference in autoregulatory efficiency is that it limits comparisons across experiments, particularly if infusion routes differ.

We hypothesized that the major target of NOS inhibition is activation of Rho kinase, resulting in inhibition of myosin light chain phosphatase and increased Ca²⁺ sensitivity. To test this hypothesis, the Rho kinase inhibitor Y-27632 was infused ira before or during ira infusion of L-NAME, both drugs being administered at blocking doses. We chose to use blocking rather than submaximal doses because of concerns that the dynamic range and resolution of the experiment would be insufficient to permit statistically reliable results. RBF dynamics during infusion of Y-27632, in the absence or presence of L-NAME, showed strong inhibition of vascular tone and myogenic and TGF-mediated autoregulation. There may be a small remnant of the L-NAME response after Y-27632: the phase peak increased significantly, and there was a borderline increase in slope (P = 0.068). However, the inhibition of autoregulation remained profound, if not technically complete, and the remaining response to L-NAME was trivial.

In the course of the in vivo experiments employing Y-27632, we were unable to find a concentration of the drug that, when infused directly into the kidney, did not reduce systemic blood pressure. The unavoidable reduction of RPP complicated interpretation of the results and led to the in vitro studies employing the hydronephrotic kidney. In this preparation, perfusion pressure is determined solely by the investigator, thus excluding pressure as an uncontrolled variable. Consequently, the effects of L-NAME and Y-27632 on myogenic autoregulation were examined over a wide range of perfusion pressures. Although little effect of NOS inhibition was apparent in this preparation, the effects of Y-27632 were striking. Autoregulation was paralyzed over the entire range of perfusion pressures tested from 80 to 180 mmHg by a concentration of Y-27632 (10 µmol/l) that is generally agreed to provide effective blockade of Rho kinase and to be selective for Rho kinase (43).

These results are consistent with the hypothesis that the major target of NOS inhibition is activation of Rho kinase but do not adequately test it, because autoregulation was almost paralyzed in the absence and presence of L-NAME, and the response to L-NAME was prevented and reversed. We therefore considered the extent to which Y-27632 affects processes mediated by depolarization and Ca²⁺ entry. It has been reported that 10 µmol/l Y-27632 caused only modest inhibition (–35 ± 5%) of afferent arteriolar vasoconstriction induced by 30 mmol/l K⁺ (36). This would be expected only to blunt responses due to depolarization and, if confirmed, would permit one to draw conclusions concerning NO targets that affect membrane potential in vascular smooth muscle cells. However, in our hands, there was essentially complete inhibition (–92 ± 3%) of vasoconstriction induced by 30 mmol/l K⁺. Because Y-27632 blocks vasoconstriction induced by high KCl and high perfusion pressure, both of which involve membrane depolarization, it was not possible to further test the hypothesis. Thus, consistent with the literature (5, 6, 36), one can conclude only that the Rho-Rho kinase pathway is very important in determining contractile behavior of the renal microcirculation.

The hydronephrotic kidney in vivo constricts in response to NOS inhibition (12) and in vitro responds normally to physiological levels of NO (46) but does not constrict or show enhanced autoregulation during NOS inhibition, indicating a lack of NO generation. The absence of constriction is likely due to reduced shear stress resulting from use of a cell-free perfusate. It is possible that this also accounts for the absence of effect of NOS inhibition on autoregulation, although it is also possible that the absence of modulation of autoregulation results from the loss of the relevant NO source, parenchymal iNOS or macula densa nNOS. Both isoforms are expressed constitutively in the kidney (34), and nNOS situated at or around the macula densa is a strong modulator of TGF (44, 45, 49, 53). Because of the known interaction between TGF and the myogenic mechanism (8, 55), it is quite conceivable that nNOS located in the macula densa could contribute to regulation of the myogenic mechanism.

We tested the involvement of these two NOS isoforms in regulation of myogenic autoregulation by means of ira infusion of isoform-selective inhibitors. In each experiment, intrarenal infusion of L-NAME was included as a positive control and to assess by subtraction the contribution of eNOS. The inhibitors employed, the doses used, and the infusion protocols were based on inhibition kinetics for iNOS (13) and nNOS (2). No positive control is available for the experiment with 1400W, and it is difficult to ensure that nNOS blockade by L-VNIO was complete. However, 1400W and L-VNIO are inactivating (i.e., irreversible) inhibitors of iNOS and nNOS, respectively (2, 13), so that even if the selected doses were low, there would still be effective inhibition after a 30-min infusion. As expected, inhibition of iNOS had no effect on conductance or on RBF dynamics. Similar data (not shown) were acquired from a separate group of Brown-Norway rats. Thus the results of this exclusion experiment are consistent with the literature consensus that iNOS does not play a significant role in regulation of renal hemodynamics.

In contrast, the nNOS-selective inhibitor L-VNIO did affect RBF dynamics. This inhibitor is highly selective for nNOS vs. iNOS, which is of little relevance here, and is moderately selective for nNOS vs. eNOS. Selectivity can be increased by infusion of L-VNIO together with L-arginine (2), and this procedure was followed. In a variety of vascular beds and in several species, nonselective NOS inhibition results in increased incremental distensibility (10, 21). In a pressure-flow transfer function, with the vascular bed denervated, this is shown by an increase in gain at frequencies faster than the myogenic mechanism (10). Because L-VNIO did not increase gain in this region of the spectrum and caused only minor vasoconstriction, we can be confident that there was little inhibition of eNOS. Despite the absence of effect on eNOS, L-VNIO significantly augmented myogenic autoregulation. Interestingly and in contrast to L-NAME, this response did not appear to increase dynamic complexity, as shown by the lack of change of low-frequency coherence. Interaction between nNOS and TGF has been shown previously in several laboratories (17, 44, 45, 49, 53), and it has been demonstrated using the isolated blood-perfused juxtamedullary nephron preparation that this effect involves afferent arteriolar constriction (17, 18). There has been a strong presumption that TGF-mediated constriction is affected by inhibition of nNOS, because in most studies perfusion pressure was constant and response to a perturbation of load at the macula densa was assessed. The present results indicate, instead, that the effect is mediated at least partly by the myogenic mechanism. There are three conclusions to be drawn from these findings.

The first conclusion to be drawn is that the response to L-VNIO implicates macula densa nNOS, and thus TGF, in regulation of the myogenic mechanism. It thus provides a mechanism to the interaction that is known to occur between the two mechanisms (8, 55). Second, assuming effective blockade of nNOS by L-VNIO, this result indicates that both eNOS and nNOS contribute to the renal hemodynamic responses induced by nonselective NOS inhibition. Because inhibition of nNOS duplicates most or all of the autoregulatory response to nonselective NOS inhibition, it would appear that this isoform is the primary contributor to autoregulation. Vascular tone appears to be preferentially affected by eNOS, which may also contribute to regulation of RBF dynamics. Third, the significant augmentation of myogenic autoregulation in the presence of modest and nonsignificant vasoconstriction complements the results obtained in this study with phenylephrine and in other studies with vasopressin and ANG II concerning a potential interaction between vascular tone and RBF dynamics. In particular, the L-VNIO result indicates that vasoconstriction is not necessary for augmentation of myogenic autoregulation, whereas the phenylephrine, vasopressin (50, 52), and ANG II (24) results indicate that vasoconstriction is not sufficient for augmentation of myogenic autoregulation. These results imply that the effects of NOS inhibition on RBF dynamics and on vascular tone are at least conceptually separable.

To further explore the role of TGF in myogenic autoregulation, we assessed the effects of a high dose of furosemide and subsequent L-NAME, both administered systemically, on RBF dynamics. As expected, furosemide caused complete inhibition of the TGF signature in the transfer function (1, 22). The modest, though significant, vasoconstriction that was also induced is not unprecedented. Such vasoconstriction is a common, but by no means uniform, finding (eg., 1) and appears to be due to elevation of circulating catecholamines (20). It is relevant here, because it suggests that furosemide is not inhibiting myogenic autoregulation via a direct action on the vascular smooth muscle (35). The effect of furosemide to reduce the slope of gain to 20 dB/decade and the phase peak to /4 rad suggests removal of positive, TGF-dependent modulation from the myogenic mechanism, leaving simpler, first-order dynamics. Presumably, the modulation exposed by furosemide is not mediated by NOS. Such modulation is consistent with the results of the L-VNIO experiment and the results of Schnermann and Briggs (38), who showed that autoregulation of glomerular capillary pressure was more effective with TGF clamped on than with it clamped off. It is also consistent with the known TGF-mediated vascular interaction among neighboring nephrons (16, 25).

In this experiment, the response of RBF dynamics to subsequent administration of L-NAME was highly significant, although numerically the response appeared to be less profound than in the other experiments in the present study. However, in this experiment the drugs were given systemically, whereas in the other experiments they were administered into the renal artery. Earlier results (see above) suggested that placement of the intrarenal cannula somewhat impaired autoregulation. We therefore chose to compare the effect of L-NAME after furosemide with that of L-NAME alone using data recalculated from a previously published study (51). In the previous study, there was remarkable consistency among normotensive strains (Wistar, Sprague-Dawley, and Long-Evans) in the effect of L-NAME on RBF dynamics. In the previous study and after administration of L-NAME, slopes of gain reduction ranged from 46 ± 7 to 58 ± 7 dB/decade, phase peaks ranged from 1.56 ± 0.11 to 1.85 ± 0.10 rad, and Coh_05–08 ranged from 0.66 ± 0.04 to 0.50 ± 0.04 (recalculated from Ref. 51). Statistical analysis in the previous report (51) and subsequently reveals no differences in RBF dynamics among strains in the presence of L-NAME. Values from the previous study are numerically different from those shown in Table 2 when L-NAME was given after furosemide. Slope and phase are numerically higher and Coh_05–08 values are numerically lower. Whether one compares the present results with the results from Wistar rats in the previous report or with the pooled results from the previous report, one reaches the same conclusion: the effect of nonselective NOS inhibition on the myogenic response is blunted in the presence of furosemide. We thus conclude that this experiment plus the L-VNIO experiment indicate a role for TGF in regulating myogenic autoregulation and that this regulation involves NO produced by macula densa nNOS.

Just and Arendshorst (24) recently reported a similar, but much stronger, interaction between TGF and nonselective NOS inhibition in regulating the myogenic mechanism. In their study, furosemide blunted the constrictor response to L-NAME and abrogated the otherwise strong enhancement of myogenic autoregulation. The results of the study by Just and Arendshorst and of the present study are largely consistent: Both studies show strong modulation of myogenic autoregulation by NO and demonstrate involvement of TGF in this modulation. They differ in the extent to which the effects of NOS inhibition are attributed to TGF. We do not have an explanation for this discrepancy, but we do find their observation somewhat surprising given 1) the additional effect of L-NAME on RBF dynamics after inhibition of nNOS by L-VNIO and 2) the extensive diffusion of NO within the renal cortex (30).

In summary, the present results are consistent with a major role for the Rho-Rho kinase pathway in mediating the effects of NO on myogenic autoregulation. They demonstrate that vasoconstriction is neither necessary nor sufficient to explain the augmentation of myogenic autoregulation by NOS inhibition. Because of the experimental separation of constrictor and dynamic responses, the results suggest the presence of another level of complexity in NO actions in the renal microcirculation. The results demonstrate interaction between TGF in the myogenic system, with the former influencing the latter, and they implicate macula densa nNOS in this interaction. Furthermore, involvement of nNOS and TGF in regulation of the myogenic mechanism suggests coupling of the myogenic mechanism to renal function.

	GRANTS

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
This study was funded by grants-in-aid from the Canadian Institutes for Health Research and the Kidney Foundation of Canada (to W. A. Cupples).

	ACKNOWLEDGMENTS

 
We thank Dr. R. D. Loutzenhiser, in whose laboratory the experiments employing hydronephrotic kidneys were performed.

	FOOTNOTES

 

Address for reprint requests and other correspondence: W. A. Cupples, Centre for Biomedical Research, Univ. of Victoria, PO Box 3020, STN CSC, Victoria, BC, Canada V8W 3N5 (e-mail: wcupples{at}uvic.ca)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

	REFERENCES

TOP ABSTRACT METHODS RESULTS DISCUSSION GRANTS REFERENCES

 

1. Ajikobi DO, Novak P, Salevsky FC, and Cupples WA. Pharmacological modulation of spontaneous renal blood flow dynamics. Can J Physiol Pharmacol 74: 964–972, 1996.[CrossRef][Web of Science][Medline]
2. Babu BR and Griffith OW. N⁵-(1-imino-3-butenyl)-L-ornithine, a neuronal isoform-selective mechanism-based inactivator of nitric oxide synthase. J Biol Chem 273: 8882–8889, 1998.[Abstract/Free Full Text]
3. Beierwaltes WH, Sigmon DH, and Carretero OA. Endothelium modulates renal blood flow but not autoregulation. Am J Physiol Renal Fluid Electrolyte Physiol 262: F943–F949, 1992.[Abstract/Free Full Text]
4. Bolz SS, Vogel L, Sollinger D, Derwand R, de Wit C, Loirand G, and Pohl U. Nitric oxide-induced decrease in calcium sensitivity of resistance arteries is attributable to activation of the myosin light chain phosphatase and antagonized by the RhoA/Rho kinase pathway. Circulation 107: 3081–3087, 2003.[Abstract/Free Full Text]
5. Cavarape A, Bauer J, Bartoli E, Endlich K, and Parekh N. Effects of angiotensin II, arginine vasopressin and thromboxane A₂ in renal vascular bed: role of Rho-kinase. Nephrol Dial Transplant 18: 1764–1769, 2003.[Abstract/Free Full Text]
6. Cavarape A, Endlich N, Assaloni R, Bartoli E, Steinhausen M, Parekh N, and Endlich K. Rho-kinase inhibition blunts renal vasoconstriction induced by distinct signaling pathways in vivo. J Am Soc Nephrol 14: 37–45, 2003.[Abstract/Free Full Text]
7. Chitaley K and Webb RC. Nitric oxide induces dilation of rat aorta via inhibition of Rho-kinase signaling. Hypertension 39: 438–442, 2002.[Abstract/Free Full Text]
8. Chon KH, Chen YM, Marmarelis VZ, Marsh DJ, and Holstein-Rathlou H. Detection of interactions between the myogenic and TGF mechanisms using nonlinear analysis. Am J Physiol Renal Fluid Electrolyte Physiol 267: F160–F173, 1994.[Abstract/Free Full Text]
9. Cupples WA and Loutzenhiser RD. Dynamic autoregulation in the in vitro perfused hydronephrotic rat kidney. Am J Physiol Renal Physiol 275: F126–F130, 1998.[Abstract/Free Full Text]
10. Cupples WA, Ajikobi DO, and Wang X. Kidney-specific responses of myogenic autoregulation to inhibition of nitric oxide synthase. In: The IMA Volumes in Mathematics and Its Applications. Membrane Transport and Renal Physiology, edited by Layton HE and Weinstein AM. New York: Springer, 2002, vol. 129, p. 293–310.
11. Deng Y and Kaufman S. Splenorenal reflex regulation of arterial pressure. Hypertension 38: 348–352, 2001.[Abstract/Free Full Text]
12. Fukao M, Mason HS, Britton FC, Kenyon JL, Horowitz B, and Keef KD. Cyclic GMP-dependent protein kinase activates cloned BK_Ca channels expressed in mammalian cells by direct phosphorylation at serine 1072. J Biol Chem 274: 10927–10935, 1999.[Abstract/Free Full Text]
13. Garvey EP, Oplinger JA, Furfine ES, Kiff RJ, Laszlo F, Whittle BJR, and Knowles RG. 1400W is a slow, tight binding, and highly selective inhibitor of inducible nitric-oxide synthase in vitro and in vivo. J Biol Chem 272: 4959–4963, 1997.[Abstract/Free Full Text]
14. Hayashi K, Suzuki H, and Saruta T. Nitric oxide modulates but does not impair myogenic vasoconstriction of the afferent arteriole in spontaneously hypertensive rats: studies in the isolated perfused hydronephrotic kidney. Hypertension 25: 1212–1219, 1995.[Abstract/Free Full Text]
15. Hoffend J, Cavarape A, Endlich K, and Steinhausen M. Influence of endothelium-derived relaxing factor on renal microvessels and pressure-dependent vasodilation. Am J Physiol Renal Fluid Electrolyte Physiol 265: F285–F292, 1993.[Abstract/Free Full Text]
16. Holstein-Rathlou NH. Synchronization of proximal tubular pressure oscillations: evidence for interaction between nephrons. Pflügers Arch 408: 438–443, 1987.[CrossRef][Web of Science][Medline]
17. Ichihara A, Inscho EW, Imig JD, and Navar LG. Neuronal nitric oxide synthase modulates rat renal microvascular function. Am J Physiol Renal Physiol 274: F516–F524, 1998.[Abstract/Free Full Text]
18. Ichihara A and Navar LG. Neuronal NOS contributes to biphasic autoregulatory response during enhanced TGF activity. Am J Physiol Renal Physiol 277: F113–F120, 1999.[Abstract/Free Full Text]
19. Ishizaki T, Uehata M, Tamechika I, Keel J, Nonomura K, Maekawa M, and Narumiya S. Pharmacological properties of Y-27632, a specific inhibitor of Rho-associated kinases. Mol Pharmacol 57: 976–983, 2000.[Abstract/Free Full Text]
20. Janssen BJA, Eerdmans PHA, and Smits JFM. Mechanisms of renal vasoconstriction following furosemide in conscious rats. Naunyn Schmiedebergs Arch Pharmacol 349: 528–537, 1994.[Web of Science][Medline]
21. Joannides R, Richard V, Haefeli WE, Benoist A, Linder L, Lüscher TF, and Thuillez C. Role of nitric oxide in the regulation of the mechanical properties of peripheral conduit arteries in humans. Hypertension 30: 1465–1470, 1997.[Abstract/Free Full Text]
22. Just A, Wittmann U, Ehmke H, and Kirchheim HR. Autoregulation of renal blood flow in the conscious dog and the contribution of the tubuloglomerular feedback. J Physiol 506: 275–290, 1998.[Abstract/Free Full Text]
23. Just A, Ehmke H, Wittmann U, and Kirchheim HR. Tonic and phasic influences of nitric oxide on renal blood flow autoregulation in conscious dogs. Am J Physiol Renal Physiol 276: F442–F449, 1999.[Abstract/Free Full Text]
24. Just A and Arendshorst WJ. Nitric oxide blunts myogenic autoregulation in rat renal but not skeletal muscle circulation via tubuloglomerular feedback. J Physiol 569: 959–974, 2005.[Abstract/Free Full Text]
25. Kallskog O and Marsh DJ. TGF-initiated vascular interactions between adjacent nephrons in the rat kidney. Am J Physiol Renal Fluid Electrolyte Physiol 259: F60–F64, 1990.[Abstract/Free Full Text]
26. Kirton CA and Loutzenhiser R. Alterations in basal protein kinase C activity modulate renal afferent arteriolar myogenic reactivity. Am J Physiol Heart Circ Physiol 275: H467–H475, 1998.[Abstract/Free Full Text]
27. Komers R, Lindsley JN, Oyama TT, Allison KM, and Anderson S. Role of neuronal nitric oxide synthase (NOS1) in the pathogenesis of renal hemodynamic changes in diabetes. Am J Physiol Renal Physiol 279: F573–F583, 2000.[Abstract/Free Full Text]
28. Kramp R, Fourmanoir P, and Caron N. Endothelin resets renal blood flow autoregulatory efficiency during acute blockade of NO in the rat. Am J Physiol Renal Physiol 281: F1132–F1140, 2001.[Abstract/Free Full Text]
29. Lessard A, Salevsky FC, Bachelard H, and Cupples WA. Incommensurate frequencies of major vascular regulatory mechanisms. Can J Physiol Pharmacol 77: 293–299, 1999.[CrossRef][Web of Science][Medline]
30. Levine DZ, Burns KD, Jaffey J, and Iacovitti M. Short-term modulation of distal tubule fluid nitric oxide in vivo by loop NaCl reabsorption. Kidney Int 65: 184–189, 2004.[CrossRef][Web of Science][Medline]
31. Loutzenhiser R. In situ studies of renal arteriolar function using the in vitro perfused hydronephrotic rat kidney. Int Rev Exp Pathol 36: 145–160, 1996.[Web of Science][Medline]
32. Loutzenhiser R, Bidani A, and Chilton L. Renal myogenic response: kinetic attributes and physiological role. Circ Res 90: 1316–1324, 2002.[Abstract/Free Full Text]
33. Milhorn TH. The Application of Control Theory to Physiological Systems. Philadelphia, PA: Saunders, 1966, p. 170–174.
34. Mohaupt MG, Elzie JL, Ahn KY, Clapp WL, Wilcox CS, and Kone BC. Differential expression and induction of mRNAs encoding two inducible nitric oxide synthases in rat kidney. Kidney Int 46: 653–665, 1994.[Web of Science][Medline]
35. Mulvany MJ and Aalkjaer C. Structure and function of small arteries. Physiol Rev 70: 921–961, 1990.[Abstract/Free Full Text]
36. Nakamura A, Hayashi K, Ozawa Y, Fujiwara K, Okubo K, Kanda T, Wakino S, and Saruta T. Vessel- and vasoconstrictor-dependent role of Rho/Rho-kinase in renal microvascular tone. J Vasc Res 40: 244–251, 2003.[CrossRef][Web of Science][Medline]
37. Parekh N. A novel method for infusing drugs continuously into the renal artery of rats. Am J Physiol Renal Fluid Electrolyte Physiol 268: F967–F971, 1995.[Abstract/Free Full Text]
38. Schnermann J and Briggs JP. Interaction between loop of Henle flow and arterial pressure as determinants of glomerular pressure. Am J Physiol Renal Fluid Electrolyte Physiol 256: F421–F429, 1989.[Abstract/Free Full Text]
39. Shiraishi M, Wang X, Walsh MP, Kargacin G, Loutzenhiser K, and Loutzenhiser R. Myosin heavy chain expression in renal afferent and efferent arterioles: relationship to contractile kinetics and function. FASEB J 17: 2284–2286, 2003.[Abstract/Free Full Text]
40. Simard JM and Li X. Functional integrity of endothelium determines Ca²⁺ channel availability in smooth muscle: involvement of nitric oxide. Pflügers Arch 439: 752–758, 2000.[CrossRef][Web of Science][Medline]
41. Sobey CG and Faraci FM. Effect of nitric oxide and potassium channel agonists and inhibitors on basilar artery diameter. Am J Physiol Heart Circ Physiol 272: H256–H262, 1997.[Abstract/Free Full Text]
42. Sobey CG and Faraci FM. Inhibitory effect of 4-aminopyridine on responses of the basilar artery to nitric oxide. Br J Pharmacol 126: 1437–1443, 1999.[CrossRef][Web of Science][Medline]
43. Somlyo AP and Somlyo AV. Ca²⁺ sensitivity of smooth muscle and nonmuscle myosin II: modulated by G proteins, kinases, and myosin phosphatase. Physiol Rev 83: 1325–1358, 2003.[Abstract/Free Full Text]
44. Thomson SC, Deng A, Komine N, Hammes JS, Blantz RC, and Gabbai FB. Early diabetes as a model for testing the regulation of juxtaglomerular NOS I. Am J Physiol Renal Physiol 287: F732–F738, 2004.[Abstract/Free Full Text]
45. Thorup C and Persson AEG. Macula densa-derived nitric oxide in regulation of glomerular capillary pressure. Kidney Int 49: 430–436, 1996.[Web of Science][Medline]
46. Trottier G, Triggle CR, O'Neill SK, and Loutzenhiser R. Cyclic GMP-dependent and cyclic GMP-independent actions of nitric oxide on the renal afferent arteriole. Br J Pharmacol 125: 563–569, 1998.[CrossRef][Web of Science][Medline]
47. Turkstra E, Braam B, and Koomans HA. Impaired renal blood flow autoregulation in two-kidney, one-clip hypertensive rats is caused by enhanced activity of nitric oxide. J Am Soc Nephrol 11: 847–855, 2000.[Abstract/Free Full Text]
48. Uehata M, Ishizaki T, Satoh H, Ono T, Kawahara T, Morishita T, Tamakawa H, Yamagami K, Inui J, Maekawa M, and Narumiya S. Calcium sensitization of smooth muscle mediated by a Rho-associated protein kinase in hypertension. Nature 389: 990–994, 1997.[CrossRef][Medline]
49. Vallon V, Traynor T, Barajas L, Huang YG, Briggs JP, and Schnermann J. Feedback control of glomerular vascular tone in neuronal nitric oxide synthase knockout mice. J Am Soc Nephrol 12: 1599–1606, 2001.[Abstract/Free Full Text]
50. Wang X, Ajikobi DO, Salevsky FC, and Cupples WA. Impaired myogenic autoregulation in kidneys of Brown Norway rats. Am J Physiol Renal Physiol 278: F962–F969, 2000.[Abstract/Free Full Text]
51. Wang X and Cupples WA. Interaction between nitric oxide and renal myogenic autoregulation in normotensive and hypertensive rats. Can J Physiol Pharmacol 79: 238–245, 2001.[CrossRef][Web of Science][Medline]
52. Wang X, Salevsky FC, and Cupples WA. Nitric oxide, atrial natriuretic factor, and dynamic renal autoregulation. Can J Physiol Pharmacol 77: 777–786, 1999.[CrossRef][Web of Science][Medline]
53. Wilcox CS, Welch WJ, Murad F, Gross SS, Taylor G, Levi R, and Schmidt HH. Nitric oxide synthase in macula densa regulates glomerular capillary pressure. Proc Natl Acad Sci USA 89: 11993–11997, 1992.[Abstract/Free Full Text]
54. Wronski T, Seeliger E, Persson PB, Forner C, Fichtner C, Scheller J, and Flemming B. The step response: a method to characterize mechanisms of renal blood flow autoregulation. Am J Physiol Renal Physiol 285: F758–F764, 2003.[Abstract/Free Full Text]
55. Yip KP, Holstein-Rathlou NH, and Marsh DJ. Mechanisms of temporal variation in single-nephron blood flow in rats. Am J Physiol Renal Fluid Electrolyte Physiol 264: F427–F434, 1993.[Abstract/Free Full Text]

This article has been cited by other articles:

				A. Just, L. Kurtz, C. de Wit, C. Wagner, A. Kurtz, and W. J. Arendshorst Connexin 40 Mediates the Tubuloglomerular Feedback Contribution to Renal Blood Flow Autoregulation J. Am. Soc. Nephrol., July 1, 2009; 20(7): 1577 - 1585. [Abstract] [Full Text] [PDF]

				C. Lau, I. Sudbury, M. Thomson, P. L. Howard, A. B. Magil, and W. A. Cupples Salt-resistant blood pressure and salt-sensitive renal autoregulation in chronic streptozotocin diabetes Am J Physiol Regulatory Integrative Comp Physiol, June 1, 2009; 296(6): R1761 - R1770. [Abstract] [Full Text] [PDF]

				J. Prakash, M. H. de Borst, M. Lacombe, F. Opdam, P. A. Klok, H. van Goor, D. K.F. Meijer, F. Moolenaar, K. Poelstra, and R. J. Kok Inhibition of Renal Rho Kinase Attenuates Ischemia/Reperfusion-Induced Injury J. Am. Soc. Nephrol., November 1, 2008; 19(11): 2086 - 2097. [Abstract] [Full Text] [PDF]

				T. D. Bell, G. F. DiBona, R. Biemiller, and M. W. Brands Continuously measured renal blood flow does not increase in diabetes if nitric oxide synthesis is blocked Am J Physiol Renal Physiol, November 1, 2008; 295(5): F1449 - F1456. [Abstract] [Full Text] [PDF]

				R. Iliescu, R. Cazan, G. R. McLemore Jr., M. Venegas-Pont, and M. J. Ryan Renal blood flow and dynamic autoregulation in conscious mice Am J Physiol Renal Physiol, September 1, 2008; 295(3): F734 - F740. [Abstract] [Full Text] [PDF]

				N. Kleinstreuer, T. David, M. J. Plank, and Z. Endre Dynamic myogenic autoregulation in the rat kidney: a whole-organ model Am J Physiol Renal Physiol, June 1, 2008; 294(6): F1453 - F1464. [Abstract] [Full Text] [PDF]

				O. V. Sosnovtseva, A. N. Pavlov, E. Mosekilde, K.-P. Yip, N.-H. Holstein-Rathlou, and D. J. Marsh Synchronization among mechanisms of renal autoregulation is reduced in hypertensive rats Am J Physiol Renal Physiol, November 1, 2007; 293(5): F1545 - F1555. [Abstract] [Full Text] [PDF]

				A. Just and W. J. Arendshorst A novel mechanism of renal blood flow autoregulation and the autoregulatory role of A1 adenosine receptors in mice Am J Physiol Renal Physiol, November 1, 2007; 293(5): F1489 - F1500. [Abstract] [Full Text] [PDF]

				X. Wang, R. D. Loutzenhiser, and W. A. Cupples Frequency modulation of renal myogenic autoregulation by perfusion pressure Am J Physiol Regulatory Integrative Comp Physiol, September 1, 2007; 293(3): R1199 - R1204. [Abstract] [Full Text] [PDF]

				M. Oppermann, P. B. Hansen, H. Castrop, and J. Schnermann Vasodilatation of afferent arterioles and paradoxical increase of renal vascular resistance by furosemide in mice Am J Physiol Renal Physiol, July 1, 2007; 293(1): F279 - F287. [Abstract] [Full Text] [PDF]

				W. A. Cupples and B. Braam Assessment of renal autoregulation Am J Physiol Renal Physiol, April 1, 2007; 292(4): F1105 - F1123. [Abstract] [Full Text] [PDF]

				X. Wang, J. Breaks, K. Loutzenhiser, and R. Loutzenhiser Effects of inhibition of the Na+/K+/2Cl- cotransporter on myogenic and angiotensin II responses of the rat afferent arteriole Am J Physiol Renal Physiol, March 1, 2007; 292(3): F999 - F1006. [Abstract] [Full Text] [PDF]

				A. Just Mechanisms of renal blood flow autoregulation: dynamics and contributions Am J Physiol Regulatory Integrative Comp Physiol, January 1, 2007; 292(1): R1 - R17. [Abstract] [Full Text] [PDF]

				Y. Shi, C. Lau, and W. A. Cupples Interactive modulation of renal myogenic autoregulation by nitric oxide and endothelin acting through ET-B receptors Am J Physiol Regulatory Integrative Comp Physiol, January 1, 2007; 292(1): R354 - R361. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) All Versions of this Article: 290/4/R982    most recent 00346.2005v1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Web of Science (18) Citing Articles via Google Scholar Google Scholar Articles by Shi, Y. Articles by Cupples, W. A. Search for Related Content PubMed PubMed Citation Articles by Shi, Y. Articles by Cupples, W. A.