Detection of low-frequency oscillations in renal blood flow

Detection of the low-frequency (LF; ∼0.01 Hz) component of renal blood flow, which is theorized to reflect the action of a third renal autoregulatory mechanism, has been difficult due to its slow dynamics. In this work, we used three different experimental approaches to detect the presence of the LF component of renal autoregulation using normotensive and spontaneously hypertensive rats (SHR), both anesthetized and unanesthetized. The first experimental approach utilized a blood pressure forcing in the form of a chirp, an oscillating perturbation with linearly increasing frequency, to elicit responses from the LF autoregulatory component in anesthetized normotensive rats. The second experimental approach involved collection and analysis of spontaneous blood flow fluctuation data from anesthetized normotensive rats and SHR to search for evidence of the LF component in the form of either amplitude or frequency modulation of the myogenic and tubuloglomerular feedback mechanisms. The third experiment used telemetric recordings of arterial pressure and renal blood flow from normotensive rats and SHR for the same purpose. Our transfer function analysis of chirp signal data yielded a resonant peak centered at 0.01 Hz that is greater than 0 dB, with the transfer function gain attenuated to lower than 0 dB at lower frequencies, which is a hallmark of autoregulation. Analysis of the data from the second experiments detected the presence of ∼0.01-Hz oscillations only with isoflurane, albeit at a weaker strength compared with telemetric recordings. With the third experimental approach, the strength of the LF component was significantly weaker in the SHR than in the normotensive rats. In summary, our detection via the amplitude modulation approach of interactions between the LF component and both tubuloglomerular feedback and the myogenic mechanism, with the LF component having an identical frequency to that of the resonant gain peak, provides evidence that 0.01-Hz oscillations may represent the third autoregulatory mechanism.

Lacrimal gland fluid secretion and lymphocytic infiltration in the NZB/W mouse model of Sjögren's syndrome

PURPOSE

The fluid secretory impairment of lacrimal and salivary glands in Sjögren's syndrome (SS) is thought to be related to the extent of lymphocytic infiltration (LI) and subsequent loss of glandular tissue. In this study, we examine the correlation between the extent of tear flow reduction and the extent of LI of lacrimal glands in the NZB/W mouse, a model of SS.

METHODS

We stimulated tear production by topical application of carbachol onto the gland while fluid was collected from the lacrimal duct. The lacrimal glands were removed after fluid collection for histology.

RESULTS

Fluid secretion in response to carbachol was less in the majority of young NZB/W females compared to C57 control animals and none of the glands showed LI. Fluid secretion was also impaired in the majority of old NZB/W females, and the extent of LI was highly variable. Some of the old SW females also showed blunted fluid secretory responses and some degree of focal LI. Young SW females showed no LI and most animals exhibited normal flow responses. Analysis of paired flow and LI measurements showed no correlation between LI and flow impairment in any of the groups or in the pooled data. Carbachol-stimulated protein secretion from lacrimal gland slices in vitro were similar in young and old SW and NZB/W mice.

CONCLUSIONS

These results suggest that LI alone is not sufficient to explain the secretory dysfunction in the NZB/W mouse model of Sjögren's syndrome.

New method for imaging innervation of the renal preglomerular vasculature. Alterations in hypertensive rats

OBJECTIVE

To develop a new method for viewing adrenergic innervation along renal preglomerular vessels; to assess nerve densities and vascular lesions along arcuate arteries (ArcA), arcuate arterial branches (ArcB), and interlobular arteries (ILA) in spontaneously hypertensive rats (SHR) and in angiotensin II (AngII) and in N(G)-nitro-L-arginine methyl ester (L-NAME) hypertensive rats.

METHODS

Preglomerular vasculatyres were isolated after HCl maceration and were immunostained against synaptophysin, a membrane protein of synaptic vesicles. Lesions were stained with Sudan black. Longitudinal nerve densities and relative frequencies of ArcA, ArcB, and ILA endowed with sudanophilic lesions were assessed separately.

RESULTS

Synaptophysin immunostaining revealed the vascular neural plexus. Nerves were adrenergic, as the plexus was destroyed by treatment with 6-hydroxy dopamine. Vascular lesions were not seen in SHR, and increased nerve density was observed along ArcA and ILA. In L-NAME- and AngII-hypertensive rats, vascular lesions affected predominantly ArcB and ILA, and nerve density was reduced by 12% and 28% (ArcA), 37% and 31% (ArcB), and by 55% and 34% (ILA), respectively, versus normotensive controls. Endothelin-1 receptor blockade did not affect AngII-induced hypertension but prevented both lesion development and reduction of density of the vascular neural plexus.

CONCLUSIONS

The method we have devised provides a direct en face view of the vascular adrenergic innervation of isolated preglomerular vasculature. Measurements in hypertensive rat models suggest a link between vascular lesions and reduction in nerve density in hypertension. Endothelin-1 likely plays a key role in mediation both vascular injury and altered vascular nerve density in hypertension.

Limit-cycle oscillations and tubuloglomerular feedback regulation of distal sodium delivery

A mathematical model was used to evaluate the potential effects of limit-cycle oscillations (LCO) on tubuloglomerular feedback (TGF) regulation of fluid and sodium delivery to the distal tubule. In accordance with linear systems theory, simulations of steady-state responses to infinitesimal perturbations in single-nephron glomerular filtration rate (SNGFR) show that TGF regulatory ability (assessed as TGF compensation) increases with TGF gain magnitude gamma when gamma is less than the critical value gamma(c), the value at which LCO emerge in tubular fluid flow and NaCl concentration at the macula densa. When gamma > gamma(c) and LCO are present, TGF compensation is reduced for both infinitesimal and finite perturbations in SNGFR, relative to the compensation that could be achieved in the absence of LCO. Maximal TGF compensation occurs when gamma approximately gamma(c). Even in the absence of perturbations, LCO increase time-averaged sodium delivery to the distal tubule, while fluid delivery is little changed. These effects of LCO are consequences of nonlinear elements in the TGF system. Because increased distal sodium delivery may increase the rate of sodium excretion, these simulations suggest that LCO enhance sodium excretion.

Advanced glycosylation end-products and NO-dependent vasodilation in renal afferent arterioles from diabetic rats

Systemic pressor responses to acetylcholine (ACh) are reduced in DM, an effect thought to be related to quenching of nitric oxide (NO) by advanced glycosylation end-products (AGE). We studied the effects of AGE in juxtamedullary (JM) afferent arterioles (AA) from rats with 40-50 days diabetes mellitus (DM) induced via streptozotocin. JM AA were perfused in vitro with solutions containing fresh RBCs suspended in either 6% bovine albumin or 6% AGE-albumin in euglycaemic Krebs-Ringer. Autoregulatory responses were evident in the DM vessels: AA constricted 31 +/- 2% (n=9) when perfusion pressure (PP) was raised from 60 to 140 mmHg. ACh (10 microM) caused a 43 +/- 15% dilation and Ca2+-channel blockade elicited a 95 +/- 14% dilation at 100 mmHg PP, indicating substantial basal vascular tone in DM AA. L-NAME (0.1 mM) constricted DM AA by 21 +/- 2% (n=9) at 100 mmHg PP, indicating significant basal NO production in DM vessels. Segments of renal resistance arteries from DM rats perfused in vitro responded to muscarinic stimulation and elevated glucose levels with significant increments in NO production, as measured with an NO-sensitive electrode. This observation shows that the renal endothelial NO system is intact in DM. While AGE in the perfusate dilated control AA, they had no effect on DM AA at all PP levels, although they blunted ACh-induced dilation. Hence, although AGE do appear to have vasoactive properties in the absence of hyperglycaemia, the results of this study are inconsistent with substantial NO quenching by AGE.

Carbon monoxide induces vasodilation and nitric oxide release but suppresses endothelial NOS

The vascular effects of carbon monoxide (CO) resemble those of nitric oxide (NO), but it is unknown whether the two messengers converge or exhibit reciprocal feedback regulation. These questions were examined in microdissected perfused renal resistance arteries (RRA) studied using NO-sensitive microelectrodes. Perfusion of RRA with buffers containing increasing concentrations of CO resulted in a biphasic release of NO. The NO response peaked at 100 nM CO and then declined to virtually zero at 10 microM. When a series of 50-s pulses of 100 nM CO were applied repeatedly (150-s interval), the amplitude of consecutive NO responses was diminished. NO release from RRA showed dependence on L-arginine but not D-arginine, and the responses to CO were inhibited by pretreatment with NG-nitro-L-arginine methyl ester (L-NAME), an inhibitor of NO synthases (NOS). CO (100 nM) also suppressed NO release induced by 100 microM carbachol, a potent agonist for endothelial NOS (eNOS). RRA from rats in which endogenous CO production from inducible HO was elevated (cobalt chloride 12 h prior to study) also showed suppressed responses to carbachol. Furthermore, responses consistent with these findings were obtained in juxtamedullary afferent arterioles perfused in vitro, where the vasodilatory response to CO was biphasic and the response to acetylcholine was blunted. Collectively, these data suggest that the CO-induced NO release could be attributed to either stimulation of eNOS or to NO displacement from a cellular storage pool. To address this, direct in vitro measurements with an NO-selective electrode of NO production by recombinant eNOS revealed that CO dose-dependently inhibits NO synthesis. Together, the above data demonstrate that, whereas high levels of CO inhibit NOS activity and NO generation, lower concentrations of CO induce release of NO from a large intracellular pool and, therefore, may mimic the vascular effects of NO.

AT1 receptor inhibition blunts angiotensin II-stimulated nitric oxide release in renal arteries

Nitric oxide (NO) is known to modulate the vascular effects of angiotensin II (AngII) in the kidney. To investigate the effect of AngII on NO release, a new technique was used that employs an NO-sensitive microelectrode to measure NO release from the vascular endothelium of perfused renal resistance arteries (tertiary branches of the renal artery or primary arcuate arteries) in vitro. The vessels were microdissected from isolated perfused rat kidneys, cannulated, and perfused at constant flow and pressure with Krebs-Ringer bicarbonate solution. The electrode was placed inside the glass collection cannula to measure vessel effluent NO concentration. Addition of AngII to the perfusate stimulated NO release in a dose-dependent manner; 0.1, 10, and 1000 nM AngII increased NO oxidation current by 85+/-18 pA (n=11), 148+/-22 pA (n=11), and 193+/-29 pA (n=11), respectively. These currents correspond to changes in effluent NO concentration of 3.4+/-0.5, 6.1+/-1.1, and 8.2+/-1.3 nM, respectively. The presence of 0.1 mM N(G)-nitro-L-arginine methyl ester in the perfusate significantly reduced the response to 10 nM AngII by 90.5+/-3.4% (n=5). Neither losartan (1 microM) nor candesartan (1 nM) significantly affected basal NO production, but both of these AT1-receptor blockers markedly blunted NO release in response to AngII (10 nM): 77+/-6% inhibition with losartan (n=8) and 63+/-9% with candesartan (n=8). These results demonstrate that AngII stimulates N(G)-nitro-L-arginine methyl ester-inhibitable NO release in isolated renal resistance arteries. Because the response was significantly blunted by AT1 receptor blockade, the findings suggest that endothelium-dependent modulation of AngII-induced vasoconstriction in renal resistance arteries is mediated, at least in part, by AT1 receptor-dependent NO release.

Insulin-like growth factor-I restores microvascular autoregulation in experimental chronic renal failure

Impairment of autoregulation (AR) is associated with accelerated progression of chronic renal failure (CRF). As the bioavailability of insulin-like growth factor-I (IGF-I) is low in CRF, we investigated the effects of acute luminal application of 10 nM recombinant human IGF-I on AR in juxtamedullary (JM) afferent arterioles (AA) perfused in vitro with a blood solution [(approximately 30% hematocrit (HCT)]. Studies were conducted in AA from adult male rats three to four weeks after five-sixths nephrectomy (Nx) by either surgical excision (N = 7) or infarction (N = 5) of two thirds of the remnant kidney; controls (N = 6) had sham surgery. AA from both Nx groups exhibited marked hypertrophy and impaired AR responses (60 to 140 mm Hg perfusion pressure), features more pronounced in the infarction group. Responses to abluminal acetylcholine (10 microM) were similar in sham and excision groups but were significantly blunted in the infarction group. All groups vasodilated significantly after Ca-channel blockade (10 mM MnCl2). IGF-I restored AR in AA from both Nx groups (P < 0.05, analysis of variance) while it vasodilated AA from controls. These results suggest that IGF-I may protect the glomerulus from injury by maintaining autoregulatory control of renal blood flow, thereby slowing the progression of CRF.

Angiotensin-II stimulates nitric oxide release in isolated perfused renal resistance arteries

Nitric oxide (NO) has been implicated as a modulator of the vascular effects of angiotensin II (ANG II) in the kidney. We used a NO-sensitive microelectrode to study the effect of ANG II on NO release, and to determine the effect of selective inhibition of the ANG II subtype I receptor (AT1) with losartan (LOS) and candesartan (CAN). NO release from isolated and perfused renal resistance arteries was measured with a porphyrin-electroplated, carbon fiber. The vessels were microdissected from isolated perfused rat kidneys and perfused at constant flow and pressure in vitro. The NO-electrode was placed inside the glass collection cannula to measure vessel effluent NO concentration. ANG II stimulated NO release in a dose-dependent fashion: 0.1 nM, 10 nM and 1000 nM ANG II increased NO-oxidation current by 85+/-18 pA (n = 11), 148+/-22 pA (n = 11), and 193+/-29 pA (n = 11), respectively. These currents correspond to changes in effluent NO concentration of 3.4+/-0.5 nM, 6.1+/-1.1 nM, and 8.2+/-1.3 nM, respectively. Neither LOS (1 muM) nor CAN (1 nM) significantly affected basal NO production, but both AT1-receptor blockers markedly blunted NO release in response to ANG II (10 nM): 77+/-6% inhibition with LOS (n = 8) and 63+/-9% with CAN (n = 8). These results are the first to demonstrate that ANG II stimulates NO release in isolated renal resistance arteries, and that ANG II-induced NO release is blunted by simultaneous AT1-receptor blockade. Our findings suggest that endothelium-dependent modulation of ANG II-induced vasoconstriction in renal resistance arteries is mediated, at least in part, by AT1-receptor-dependent NO release.

Effects of insulin-like growth factor I on the renal juxtamedullary microvasculature

To characterize the effects on the rat renal preglomerular microvasculature of insulin-like growth factor I (IGF-I), experiments were performed using the in vitro blood-perfused juxtamedullary nephron preparation. IGF-I induced a reversible vasodilation of pre- but not postglomerular microvessels in a dose-dependent manner (10(-9)-10(-7) M). The IGF-I-induced vasodilation was similar in all preglomerular vascular segments: interlobular artery, 11.5 +/- 1.2% of control (n = 16); mid-afferent arterioles, 11.6 +/- 1.7% (n = 24); and juxtaglomerular afferent segments, 16.1 +/- 2.8% (n = 19). Renal autoregulatory capacity was not reduced by IGF-I. Pretreatment with the nitric oxide (NO) synthase inhibitor NG-nitro-L-arginine methyl ester (10(-4) M) completely inhibited the vasodilatory response to IGF-I. IGF-I induced a rapid increase of NO concentration in intact renal microvessels, monitored by a NO-selective voltametric microelectrode. Pretreatment with the cyclooxygenase inhibitor indomethacin (10(-5) M) not only abrogated the IGF-I-induced dilation, but, moreover, IGF-I elicited a small but significant (approximately 10%) vasoconstriction in all preglomerular vessels. These results indicate that the renal vascular effects of IGF-I involve activation of two endogenous vasodilators (NO and vasodilatory prostaglandins). In addition, IGF-I may also release an undefined vasoconstrictor.

Spectral properties of the tubuloglomerular feedback system

A simple mathematical model was used to investigate the spectral properties of the tubuloglomerular feedback (TGF) system. A perturbation, consisting of small-amplitude broad-band forcing, was applied to simulated thick ascending limb (TAL) flow, and the resulting spectral response of the TGF pathway was assessed by computing a power spectrum from resulting TGF-regulated TAL flow. Power spectra were computed for both open- and closed-feedback-loop cases. Open-feedback-loop power spectra are consistent with a mathematical analysis that predicts a nodal pattern in TAL frequency response, with nodes corresponding to frequencies where oscillatory flow has a TAL transit time that equals the steady-state fluid transit time. Closed-feedback-loop spectra are dominated by the open-loop spectral response, provided that gamma, the magnitude of feedback gain, is less than the critical value gamma c required for emergence of a sustained TGF-mediated oscillation. For gamma exceeding gamma c, closed-loop spectra have peaks corresponding to the fundamental frequency of the TGF-mediated oscillation and its harmonics. The harmonics, expressed in a nonsinusoidal waveform for tubular flow, are introduced by nonlinear elements of the TGF pathway, notably TAL transit time and the TGF response curve. The effect of transit time on the flow waveform leads to crests that are broader than troughs and to an asymmetry in the magnitudes of increasing and decreasing slopes. For feedback gain magnitude that is sufficiently large, the TGF response curve tends to give a square waveshape to the waveform. Published waveforms and power spectra of in vivo TGF oscillations have features consistent with the predictions of this analysis.

Nonlinear filter properties of the thick ascending limb

A mathematical model was used to investigate the filter properties of the thick ascending limb (TAL), that is, the response of TAL luminal NaCl concentration to oscillations in tubular fluid flow. For the special case of no transtubular NaCl backleak and for spatially homogeneous transport parameters, the model predicts that NaCl concentration in intratubular fluid at each location along the TAL depends only on the fluid transit time up the TAL to that location. This exact mathematical result has four important consequences: 1) when a sinusoidal component is added to steady-state TAL flow, the NaCl concentration at the macula densa (MD) undergoes oscillations that are bounded by a range interval envelope with magnitude that decreases as a function of oscillatory frequency; 2) the frequency response within the range envelope exhibits nodes at those frequencies where the oscillatory flow has a transit time to the MD that equals the steady-state fluid transit time (this nodal structure arises from the establishment of standing waves in luminal concentration, relative to the steady-state concentration profile, along the length of the TAL); 3) for any dynamically changing but positive TAL flow rate, the luminal TAL NaCl concentration profile along the TAL decreases monotonically as a function of TAL length; and 4) sinusoidal oscillations in TAL flow, except at nodal frequencies, result in nonsinusoidal oscillations in NaCl concentration at the MD. Numerical calculations that include NaCl backleak exhibit solutions with these same four properties. For parameters in the physiological range, the first few nodes in the frequency response curve are separated by antinodes of significant amplitude, and the nodes arise at frequencies well below the frequency of respiration in rat. Therefore, the nodal structure and nonsinusoidal oscillations should be detectable in experiments, and they may influence the dynamic behavior of the tubuloglomerular feedback system.

Production and physiological actions of anandamide in the vasculature of the rat kidney

The endogenous cannabinoid receptor agonist anandamide is present in central and peripheral tissues. As the kidney contains both the amidase that degrades anandamide and transcripts for anandamide receptors, we characterized the molecular components of the anandamide signaling system and the vascular effects of exogenous anandamide in the kidney. We show that anandamide is present in kidney homogenates, cultured renal endothelial cells (EC), and mesangial cells; these cells also contain anandamide amidase. Reverse-transcriptase PCR shows that EC contain transcripts for cannabinoid type 1 (CB1) receptors, while mesangial cells have mRNA for both CB1 and CB2 receptors. EC exhibit specific, high-affinity binding of anandamide (Kd = 27.4 nM). Anandamide (1 microM) vasodilates juxtamedullary afferent arterioles perfused in vitro; the vasodilation can be blocked by nitric oxide (NO) synthase inhibition with L-NAME (0.1 mM) or CB1 receptor antagonism with SR 141716A (1 microM), but not by indomethacin (10 microM). Anandamide (10 nM) stimulates CB1-receptor-mediated NO release from perfused renal arterial segments; a similar effect was seen in EC. Finally, anandamide (1 microM) produces a NO-mediated inhibition of KCl-stimulated [3H]norepinephrine release from sympathetic nerves on isolated renal arterial segments. Hence, an anandamide signaling system is present in the kidney, where it exerts significant vasorelaxant and neuromodulatory effects.

Role of mesangial cells in macula densa to afferent arteriole information transfer

1. Extraglomerular mesangial cells are strategically positioned between the macula densa and the afferent arteriole. These cells form a syncytium and are connected with glomerular mesangial cells via gap junctions. The model of immunoablation of mesangial cells in anti-Thy-1 glomerulonephritis carries the promise for understanding the function of mesangial cells as potential transmitters of information between the macula densa and the afferent arteriole. 2. The above anatomical relations between structures in the juxtaglomerular apparatus predict several possible routes of information flow. This review charts some hypothetical routes. 3. Research into the messenger systems involved in the transfer of signals from the macula densa to mesangial cells and from mesangial cells to the afferent arteriole suggests several candidate molecules to function in this capacity. Mechanisms of action for each candidate are discussed. 4. The oscillating nature of the afferent signal and efferent function in the tubuloglomerular feedback system, as well as other discoveries, offer a fertile field for future studies.

Branching patterns and autoregulatory responses of juxtamedullary afferent arterioles

The spatial organization of autoregulatory responses (AR) was assessed in couples of afferent arterioles (AA), either grouped as anatomic pairs or branched sequentially along the same arcuate arterial branch (ArcB). With blood-perfused juxtamedullary nephron (JMN) preparations, AR were elicited by raising blood perfusion pressure from 60 to 120 mmHg and quantified by videomicroscopy as pressure-induced constrictions. Paired AA had unequal lengths (long-to-short ratio, 1.9 +/- 0.1; n = 36); however, no statistical difference in AR was found between long and short AA at juxtaglomerular or early AA (EAA) sites. Sequentially branched AA had the same length heterogeneity as paired AA (proximal-to-distal AA length ratio, 2.0 +/- 0.2; n = 30). However, AR exhibited a significant axial gradient, being higher in distal than in proximal AA or ArcB sites. In both AA branching patterns, EAA and nearby sites of the feed arteries had similar AR. Hence, our results are consistent with hemodynamic coupling in paired JMN. Around branching sites, AR are spatially organized in a way consistent with electrotonic vascular coupling.

Decreased hepatic insulin-like growth factor (IGF)-I and increased IGF binding protein-1 and -2 gene expression in experimental uremia

The imbalance between normal insulin-like growth factor-I (IGF-I) and markedly increased IGF binding protein (IGFBP) plasma levels plays a pathogenic role for growth retardation and catabolism in children with chronic renal failure. To investigate the mechanism of these alterations, experiments were performed in an experimental model of uremia in rats (5/6 nephrectomy) and in pair-fed and ad libitum-fed sham-operated controls Using a specific solution hybridization/RNase protection assay, we observed a marked reduction of hepatic IGF-I messenger RNA (mRNA) abundance at steady state in uremic animals (37 +/- 5% of control) compared both with pair-fed (65 +/- 10%) and ad libitum-fed controls (100 +/- 11%) (P < 0.001). Reduced IGF-I gene expression was clearly organ-specific; it was most pronounced in liver (significant vs., pair-fed controls) and lung and muscle tissue (significant vs., ad libitum-fed controls); no change was observed in kidney and heart tissue. To determine a potential mechanism of reduced hepatic IGF-I gene expression in uremia, the hepatic GH receptor gene expression in the same experimental animals was analyzed by specific solution hybridization/RNase protection assay. Uremic animals had a 20-30% reduction of hepatic GH receptor mRNA abundance compared with controls. Hepatic GHBP expression in uremia was decreased in parallel. Despite the reduction of hepatic IGF-I mRNA abundance, plasma IGF-I levels in uremia were not different from ad libitum-fed controls. This discrepancy is explained by an increased concentration of IGFBPs in uremic plasma. By RIA, plasma IGFBP-1 levels in uremia were increased 4-fold; by Western immunoblot, plasma IGFBP-2 levels were increased 7-fold and plasma IGFBP-4 levels were increased 2-fold compared with both control groups. Intact IGFBP-3 (M(r), approximately 48 kDa) and low molecular IGFBP-3 fragments were not significantly different among the three groups. By Northern blot analysis, hepatic IGFBP-1 mRNA levels in uremia were 2-fold higher than in controls. IGFBP-2 mRNA abundance in liver tissue was increased 4-fold, whereas in kidney there was a significant reduction of IGFBP-2 mRNA (30% of control). IGFBP-4 mRNA was increased by 50% in kidney but not in liver. Plasma insulin and corticosterone levels were not different among the groups. Our study shows that hepatic IGF-I gene expression was specifically reduced in uremia, partially as the consequence of a reduced hepatic GH receptor gene expression. One of the mechanisms contributing to increased IGFBP levels in uremia is increased hepatic gene expression of IGFBP-1 and IGFBP-2. The imbalance between reduced hepatic IGF-I production and increased hepatic IGFBP-1 and 2 production is likely to play a pathogenic role for catabolism and growth failure in CRF.

Alternative splicing of CREB and CREM mRNAs in an immortalized germ cell line

Alternative splicing of CREB (cAMP response element binding protein) and CREM (cAMP response element modulator) mRNAs in separated pachytene spermatocyte, round spermatid, and elongated spermatid fractions and the germ cell-derived immortalized cell line GC-2spd(ts) was studied by reverse transcription polymerase chain reaction (RT-PCR). Both primary germ cells and the GC-2spd(ts) cell line expressed the testis-specific CREB splice variant containing exon W. In the CREB C-E exon region, both primary germ cells and GC-2spd(ts) cells produced RT-PCR products that included exon Y. RT-PCR using CREM primers produced multiple bands in primary germ cells. The truncated CREAM deltaC-G form was found in all the germ cell fractions. The smaller splice forms of CREM were more prominent in the GC-2spd(ts) cells. GC-2spd(ts) cells resembled F9 teratocarcinoma cells more closely than primary germ cells with respect to the relative expression of both CREB and CREM alternative splice products. In Sertoli cells, RT-PCR products of CREB exon lacking W and the product corresponding to CREM delta C-G were most prominent. These data show that the GC-2spd(ts) cell line retains some qualitative characteristics of primary germ cells with respect to alternative splicing of CREB and CREM mRNA.

Capillary electrophoresis for the determination of glomerular filtration rate using nonradioactive iohexol

High-performance liquid chromatography (HPLC) has been used as an alternative to the isotopic method to calculate glomerular filtration rate (GFR). With the HPLC method, serum iohexol or iothalamate levels are measured, and the plasma clearance rate of the compound is used as a surrogate for GFR. However, HPLC is a labor-intensive procedure, which limits its usefulness in the clinical setting. Capillary electrophoresis, a newer technique in which electrophoretic separations are performed in capillary tubes, is easier and faster than HPLC. We used capillary electrophoresis for the determination of serum iohexol levels and the calculation of GFR. Patients underwent a simultaneous 125I-iothalamate clearance test and a plasma iohexol clearance test to determine GFR. Mean GFR (+/-SD) was 70.9 +/- 29.9 mL/min (range, 14.5 to 131 mL/min) in 52 patients as determined by standard iothalamate clearance methods. For iohexol clearance, the correlation coefficient and standard error were 0.93 and 10.9 mL/min, respectively, using capillary electrophoresis compared with the iothalamate method. Capillary electrophoresis is a simple, rapid method that can be used to calculate GFR and provides results at least as accurate as those obtained by HPLC and x-ray fluorescence.

Neuropathic pain in rats is associated with altered nitric oxide synthase activity in neural tissue

Peripheral nerve injury may lead to a chronic neuropathic pain state that results from an increase in excitability of central neurons. This central sensitization is mediated via an N-methyl-D-aspartic acid (NMDA) receptor and may involve the production of nitric oxide (NO). As NO is suggested to play a role in nociceptive transmission following nerve injury, we examined for altered NO synthase activity at multiple levels of peripheral and spinal neural tissue in a rat model of neuropathic pain. Peripheral neuropathy was induced in rats (N = 12) by ligation of the left L5 and L6 nerve roots. Six other rats had sham surgery. An ipsilateral decrease in paw withdrawal threshold to mechanical stimuli confirmed the presence of a neuropathic pain state. Samples of the lumbar and thoracic spinal cords, L4, L5, and L6 dorsal root ganglia (DRGs), and the sciatic nerves were obtained from the lesioned and contralateral sides at 2 and 4 weeks after neuropathic surgery (N = 6 per group). In the lumbar spinal cord, a bilateral decrease in nitric oxide synthase (NOS) activity was observed 2 and 4 weeks after neuropathic surgery. NOS activity was increased in the ipsilateral L5 and 6 DRGs 2 weeks following neuropathic surgery. An increase in NOS activity in the DRG may be an early mechanism for inducing more central changes. The bilaterally decreased NOS activity in the lumbar spinal cord may be secondary to a negative feedback mechanism resulting from increased NO production in the spinal dorsal root ganglia. Multiple alterations in expression of NOS activity that occur in both peripheral and central processing may play a role in the pain behavior resulting from peripheral nerve injury. (Preliminary results of these studies have been presented in abstract form at the annual meetings of the Society for Neuroscience, 1994, and the American Society of Anesthesiologists, 1994).

Accumulation of acidic renin isoforms in kidneys of cyclosporine-A-treated rats

Chronic cyclosporin A (CsA) treatment results in major hemodynamic changes in the renal microvasculature and in expression of the intrarenal renin angiotensin system. Changes in renin expression in kidneys of CsA-treated rats include the recruitment of immunoreactive renin in afferent arterioles and in the juxtaglomerular apparatus. This study presents evidence that an acidic isoform of renin is increased in kidneys of CsA-treated rats. Immunoblots of rat kidney homogenate separated by polyacrylamide-gel electrophoresis and also by isoelectric focusing demonstrate the presence of an acidic isoform (pl 5.5 and estimated molecular weight of approximately 32 to 36 kd) seen in increased amounts in kidney homogenate from CsA-treated rats. Silver-stained two-dimensional gels of renin separated from kidney homogenate with pepstatin agarose confirm the presence of an acidic renin isoform in CsA-treated rats. In rats that received CsA for varied intervals of 1, 3, 5, and 8 wk, this acidic isoform is shown to significantly accumulate relative to duration of treatment with CsA when immunoreactive bands are analyzed by densitometric scanning (r2 = 0.90, P < 0.001). Renin enzymatic activity also increased in kidney homogenate of CsA-treated rats relative to duration of treatment with CsA (r2 = 0.486, P < 0.001). Prorenin in these same samples was significantly decreased compared with controls. The acidic renin isoform identified in kidney homogenate of CsA-treated rats may be involved in the vascular changes that are seen in this model.

Measurement of glomerular filtration rate using nonradioactive Iohexol: comparison of two one-compartment models

Radioisotopic methods for the determination of the glomerular filtration rate (GFR) are highly accurate but require the collection of multiple blood and urine samples and are costly to perform due to personnel, material, and analysis costs. Nonradioactive methods of GFR determination have the potential of minimizing procedure costs while preserving accuracy. We determined the GFR simultaneously by 125I-iothalamate and nonradioactive iohexol clearance methods in 41 adults. The study group consisted of 54% males, with a mean age of 50.7 (range 28-79) years and a mean GFR by 125I-iothalamate clearance of 66.5 +/- 28.3 (range 10-118) ml/min. The iohexol concentrations were measured by a simplified high-performance liquid chromatography method that did not require sample preparation. The iohexol plasma clearance was calculated by both a new one-compartment model as well as by Jacobsson's one-compartment model. Using Jacobsson's single-sample model and data from the 240-min point, there was an excellent correlation between 125 I-iothalamate and nonradioactive iohexol clearance values: r2 = 0.95, standard error of the estimate = 11.4 ml/min, and intrapatient coefficient of variation = 16.9%. However, this formula tended to overestimate GFRs < 30 ml/min and to underestimate GFRs > 80 ml/min. The new one-compartment model is a modification of Bubeck's model, originally used for the determination of renal plasma blood flow. Using this modified model, there was an excellent correlation between 125I-iothalamate and nonradioactive iohexol clearance values at all levels of GFR tested: r2 = 0.95, standard error of the estimate = 9.2 ml/min, and intrapatient coefficient of variation = 13.7%. In conclusion, the determination of the plasma clearance of iohexol by a nonradioactive technique and a monoexponential model is a simple and accurate method of determining the GFR in patients with varying degrees of renal impairment.

Massive cerebral infarction caused by paradoxical embolism: detection by transesophageal echocardiography

Two days after coronary artery bypass, a 75-year-old woman had sudden dense left-sided hemiplegia. A transthoracic echocardiogram showed a suspicious mass in the right atrium and right ventricle, which was confirmed by transesophageal echocardiography. Transesophageal echocardiography further demonstrated an elongated mass across a patent foramen ovale. Deep femoral venous thrombosis and massive cerebral infarction were also noted by Doppler ultrasonography and head computed tomographic scanning, respectively. Paradoxical embolization was thought to be the cause of the stroke.

Branching points of renal resistance arteries are enriched in L-type calcium channels and initiate vasoconstriction

The morphologic structures responsible for the drop in blood pressure along the preglomerular vasculature are not completely defined. Theoretical and videomicroscopic analyses of nonrenal vascular beds implicate bifurcations of resistance arteries as important sites of hemodynamic regulation. These structures contain pacemaker cells sensitive to calcium channel blockers and appear to initiate vasomotion. In the present study, we examined the possibility of functional diversity of smooth muscle cells along resistance arteries with regard to the density of voltage-gated L-type calcium channels. Staining of microdissected renal resistance arteries with Bodipy-labeled dihydropyridine and analysis by confocal microscopy showed enhanced binding at branching points compared with the distal sites in daughter vessels. Antibodies directed against the alpha 1-subunit of the dihydropyridine-sensitive calcium channels confirmed the enhanced expression of L-type channels predominantly at the sites of bifurcations of renal resistance arteries. Fluorescence digital-image analysis of freshly microdissected branches of cortical radial (interlobular) and arcuate arteries intravitally labeled with a calcium indicator, fluo 3, identified branching points as initiator sites of depolarization-induced intracellular Ca2+ concentration ([Ca2+]i) transients, which propagated along the vascular wall at the rate of 2.0 +/- 0.7 micron/s. Videomicroscopy of blood-perfused rat juxtamedullary resistance arteries showed that branching points exhibit more pronounced contractile responses to KCl-induced depolarization than distal sites along the daughter vessels. Collectively, these results demonstrate that branching points are enriched in L-type calcium channels, a finding that suggests these structures may serve as important regulators of renal hemodynamics.

Instantaneous and steady-state gains in the tubuloglomerular feedback system

The load of water and solute entering each nephron of the mammalian kidney is regulated by the tubuloglomerular feedback (TGF) mechanism, a negative feedback loop. Experiments in rats have shown that key variables of this feedback system may exhibit TGF-mediated oscillations. Mathematical modeling studies have shown that the open-feedback-loop gain is a crucial parameter for determining whether oscillations will emerge. However, two different formulations of this gain have been used. The first is the steady-state gain, a readily measurable quantity corresponding to the steady-state reduction in single-nephron glomerular filtration rate (SNGFR) subsequent to a sustained increased in ascending limb flow rate. The second is an instantaneous gain, a variable arising from theoretical considerations corresponding to the maximum reduction in SNGFR resulting from an instantaneous shift of the ascending limb flow column, with the assumption that the SNGFR response is also instantaneous. Here we show by an analytic argument how the steady-state and instantaneous open-feedback-loop gains for the ascending limb are related. In the case of no solute backleak into the ascending limb, the two formulations of gain are equivalent; however, in the presence of solute backleak, the instantaneous gain is larger in magnitude than the steady-state gain. With typical physiological parameters for the rat, calculations with a model previously devised by us show that the gains differ by 5-10%. Hence, experimental measurements of the steady-state gain may provide useful lower-bound estimates of the instantaneous gain of the feedback system in the normal rat. However, the gains may diverge significantly in pathophysiological states where ascending limb transport is compromised by abnormally high NaCl permeability.

Anatomic pairing of afferent arterioles and renin cell distribution in rat kidneys

Close afferent arteriolar (AA) connectivity is a prerequisite for hemodynamic interaction between superficial rat nephrons. Studies were conducted in rat, mouse, rabbit, and human renal vasculatures obtained by an HCl maceration-microdissection technique to document the extent of AA connectivity. In rat kidneys, we assessed the possibility for a slow component of internephron coupling, as reflected by arteriolar renin cell distribution after specific immunostaining for renin. In the four species examined, 51% (human) to 60% (mouse) of total AA populations were organized as vascular units consisting of mostly two AA sharing a common origin and a connecting arterial segment. In rat AA pairs, branch lengths were significantly correlated, suggesting coordinated arteriolar growth. The sum of AA branch lengths averaged 278 +/- 6 microns. Rat arteriolar renin status, ranging from no renin cells to renin-recruited midafferent arterioles, distributed in a significantly nonrandom fashion within AA pairs, and 52% of the pairs had equal renin status. Hence, AA pairing is a consistent anatomic characteristic of mammalian kidneys and may constitute an optimal vascular design for hemodynamic as well as endocrine interactions.

Disappearing cardiac masses--the importance of intraoperative transesophageal echocardiography

A 25-year-old man presented with sudden onset right-sided hemiplegia. Transthoracic and transesophageal echocardiograms demonstrated a mobile mass attached to the anterior mitral leaflet. The mass was, however, not found at operation.

Decrease in ambient [Cl-] stimulates nitric oxide release from cultured rat mesangial cells

It has been hypothesized that fluctuations of the ionic composition in the interstitium of juxtaglomerular apparatus (JGA) modulate the function of extraglomerular mesangial cells (MC), thereby participating in tubuloglomerular feedback (TGF) signal transmission. We examined the effects of isosmotic reductions in ambient sodium concentration ([Na+]) and [Cl-] on cytosolic calcium concentration ([Ca2+]i) in cultured rat MC. Rapid reduction of [Na+] or [Cl-] in the bath induced a concentration-dependent rise in [Ca2+]i. MC are much more sensitive to decreases in ambient [Cl-] than to [Na+]; a decrease in [Cl-] as small as 14 mM was sufficient to elicit a detectable [Ca2]i response. These observations suggest that MC can be readily stimulated by modest perturbations of extracellular [Cl-]. Next, we examined whether activation of MC by lowered ambient [Cl-] influences cellular nitric oxide (NO) production. Using an amperometric NO sensor, we found that a 13 mM decrease in ambient [Cl-] caused a rapid, Ca2+/calmodulin-dependent rise in NO release from MC. This response was not inhibitable by dexamethasone, indicating the involvement of the constitutive rather than the inducible type of NO synthase in MC. In addition, the NO release was blunted by indomethacin pretreatment, suggesting that a metabolite(s) of cyclooxygenase regulates the activation of NO synthase in MC. Our findings that small perturbations in external [Cl-] stimulate MC to release NO, a highly diffusible and rapidly acting vasodilator, provide a possible mechanism to explain the transmission of the signal for the TGF response within the JGA.

Numerical simulation of propagating concentration profiles in renal tubules

Method-dependent mechanisms that may affect dynamic numerical solutions of a hyperbolic partial differential equation that models concentration profiles in renal tubules are described. Some numerical methods that have been applied to the equation are summarized, and ways by which the methods may misrepresent true solutions are analysed. Comparison of these methods demonstrates the need for thoughtful application of computational mathematics when simulating complicated time-dependent phenomena.

Ascending myogenic autoregulation: interactions between tubuloglomerular feedback and myogenic mechanisms

A mathematical model of the renal vascular and tubular systems was used to examine the possibility that synergistic interactions might occur between the tubuloglomerular feedback (TGF) and myogenic autoregulatory mechanisms in the kidney. To simulate the myogenic mechanism, the renal vasculature was modelled with a resistance network where the total preglomerular resistance varies with intravascular pressure. In addition, a steady-state model of glomerular filtration, proximal and Henle's loop reabsorption, and TGF-modulation of afferent arteriolar resistance was derived. The results show that, if TGF acts on the distal portion of the preglomerular vasculature, then any TGF-induced vasoconstriction should raise upstream intravascular pressure and, thereby, trigger a myogenic (AMYO) response. The model further predicts that the magnitude of the AMYO response can be similar in magnitude to the TGF-induced increment in afferent resistance. Hence, the effects of TGF excitation on whole kidney hemodynamics may be much greater than predicted from measurements in single nephrons. Moreover, a significant fraction of the intrinsic myogenic autoregulatory response to increased renal perfusion pressure may result from a synergistic interaction between the TGF and myogenic mechanisms.

Direct visualization of renin-cell distribution in preglomerular vascular trees dissected from rat kidney

Three methods to visualize directly the distribution of granulated renin-positive cells in vascular trees microdissected from rat kidney were developed. Kidneys were removed from anesthesized rats, hemisectioned, macerated in HCl, and soaked in distilled water for 24-48 h. Cortical preglomerular vascular trees consisting of arcuate and cortical radial arteries and afferent arterioles were microdissected with the aid of a stereomicroscope. Granulated cells can be visualized in three ways. First, under transmitted or incident light observation, granulated cells are readily distinguished from the surrounding smooth muscle cells, because of marked differences in the refractive properties of these two cell types. Second, quinacrine, a fluorescent, intravital stain selective for dense-core granules, can be administered (2 mg/kg iv) to the rat 1 h before nephrectomy. When illuminated with 440-nm light, granulated cells fluorescence strongly at 510 nm. Third, specific immunostaining for renin can be obtained with a polyclonal anti-rat renin antibody and avidin-biotin immunoperoxidase staining in vascular trees subjected to cell permeabilization with Triton. These new techniques permit the direct visualization of the distribution of granulated renin-positive cells in preglomerular vessels under conditions in which the vascular architecture is largely preserved.

Effect of CsA on the expression of renin and angiotensin type 1 receptor genes in the rat kidney

To determine whether Cyclosporine A (CsA) alters the intrarenal expression of the renin and type 1 angiotensin II receptor genes, male adult Sprague-Dawley rats were given 25 mg/kg/day CsA s.c. for three weeks (CsA, N = 20) and were compared to pair-fed vehicle treated rats (Con, N = 20). The intrarenal distribution of renin and its mRNA was assessed by immunocytochemistry and in situ hybridization. In addition, kidney renin and type 1 angiotensin II (AT1) receptor mRNA levels were determined by Northern blot analysis. The percentage of juxtaglomerular apparatuses containing renin was higher in the CsA (84 +/- 5.5%) than in the Con (61 +/- 6.7%) group, (P < 0.05). The length of renin immunostaining along afferent arterioles was higher in the CsA (74 +/- 4.5 microns) than in the Con (37 +/- 5.1 microns) group, (P < 0.05). In contrast, neither renin mRNA levels nor its intrarenal distribution were altered by chronic CsA administration. Kidney AT1 receptor mRNA levels were lower in the CsA group than in the Con group. We conclude that chronic CsA: (1) induces recruitment of renin containing cells along the afferent arteriole, (2) causes no changes in intrarenal renin mRNA levels or distribution, suggesting that post-transcriptional events may be responsible for the persistence and/or uptake of renin by the preglomerular vasculature, (3) promotes a downregulation of AT1 receptor gene in the kidney, suggesting that local angiotensin II may control AT1 receptor gene expression by a negative feedback.

Autoregulation of intravascular pressure in preglomerular juxtamedullary vessels

To quantify the functional significance of autoregulatory responses in preglomerular juxtamedullary (JM) vessels, intravascular pressures (P chi) were measured with a servonull instrument in blood-perfused arcuate (ArcA) and interlobular arteries (ILA), afferent arterioles (AA), and glomerular capillaries (GC) in vitro. P chi was determined at perfusion pressures (Pp) between approximately 60 and 150 mmHg, and the slope of the relationship between Px and Pp was estimated by linear regression. From the regression, Px was 98 +/- 1, 96 +/- 2, 64 +/- 9, and 48 +/- 2 mmHg for ArcA, ILA, AA, and GC, respectively, at the reference perfusion pressure of 100 mmHg. The results show good autoregulation of GC pressure (Pg), with a response slope of 0.10 +/- 0.07 mmHg per mmHg change in Pp, corresponding to an autoregulation index of 0.20 +/- 0.15. The slopes of the Px vs. Pp relationships in ArcA, ILA, and AA were 0.96 +/- 0.02, 0.79 +/- 0.08, and 0.32 +/- 0.11, respectively. To determine whether these observed relationships in preglomerular vessels reflect significant upstream resistance changes, we derived a new autoregulation index for Px measured at an arbitrary preglomerular location. This analysis takes into account the extent to which outflow pressure, Pg, is autoregulated by the ensemble action of the entire preglomerular vasculature. The analysis indicates that 20% autoregulatory compensation occurs upstream from the late ILA, 65% upstream from the late AA, and 80% for the entire preglomerular vascular tree. Hence, in the JM preglomerular circulation, the AA is the major site of autoregulatory resistances adjustment, with a smaller but significant contribution by the ILA.

Effect of cyclosporine on endothelial albumin leakage in rats

Short-term treatment of rats with cyclosporine (cyclosporine A [CsA]; Sandimmune) results in a marked reduction in intravascular plasma volume, a factor that might contribute to the renal dysfunction associated with this potent immunosuppressant. To examine the role of plasma extravasation in CsA-induced hypovolemia, intravascular plasma volumes (PV), blood volumes, [125I]albumin disappearance, and changes in hematocrit (Hct) were measured in Inactin-anesthetized rats subjected to minimal surgery. The rats were treated for 3 wk with either 25 mg/kg/day of CsA s.c. or vehicle. Plasma creatinine and urea were significantly elevated, and magnesium was reduced in the CsA group (N = 6) as compared with controls (CON) (N = 6). CsA treatment had no effect on urinary protein and albumin excretion. Blood volume was significantly lower in CsA than in CON (8.4 +/- 0.5 versus 10.6 +/- 0.3 mL/100 g body wt) as was PV (4.3 +/- 0.2 versus 5.5 +/- 0.2 mL/100 g body wt). Two hours after injection, plasma [125I]albumin concentration had fallen by 41 +/- 4% in CsA versus 23 +/- 5% in CON. Because Hct, and, hence PV, was unchanged in both groups during these 2 h, these data indicate enhanced endothelial albumin leakage in the CsA group. In two additional groups of six rats each, acute volume expansion with fresh whole blood (2 mL/100 g body wt) resulted in extravasation of plasma. Hct rose by 8.0 +/- 0.2% in CsA versus 3.8 +/- 0.2% in CON after 150 min, corresponding to 27 +/- 3 and 15 +/- 2% decreases in total PV, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Bifurcation analysis of TGF-mediated oscillations in SNGFR

Recent micropuncture studies in rats have demonstrated the existence of oscillatory states in nephron filtration mediated by tubuloglomerular feedback (TGF). We develop a minimal mathematical model of the TGF system, consisting of a first-order hyperbolic partial differential equation describing thick ascending limb (TAL) NaCl reabsorption and an empirical feedback relation. An analytic bifurcation analysis of this model provides fundamental insight into how oscillatory states depend on the physiological parameters of the model. In the special case of no solute backleak in the TAL, the emergence of oscillations explicitly depends on two nondimensional parameters. The first corresponds to the delay time of the TGF response across the juxtaglomerular apparatus, and the second corresponds to the product of the slope of the TGF response curve at the steady-state operating point and the space derivative of the steady-state NaCl concentration profile in the TAL at the macula densa. Numerical calculations for the case without TAL backleak are consistent with this result. Numerical simulation of the more general case with TAL backleak shows that the bifurcation analysis still provides useful predictions concerning nephron dynamics. With typical parameter values, the analysis predicts that the TGF system will be in oscillatory state. However, the system is near enough to the boundary of the nonoscillatory region so that small changes in parameter values could result in nonoscillatory behavior.

Syncytial organization of cultured rat mesangial cells

To investigate communication competence of cultured rat mesangial cells, Lucifer yellow transfer was studied using microinjection and scrape-loading techniques. Both methods yielded results indicating considerable gap junctional communication between cultured mesangial cells. Gap junctional communication between mesangial cells was upregulated by adenosine 3',5'-cyclic monophosphate (cAMP). Conversely, cell-to-cell communication was attenuated by exposure to the tumor promoter phorbol myristate acetate, the Ca ionophore ionomycin, reduced oxygen intermediates, and cell acidification. Expression of voltage gated calcium channels by mesangial cells was studied microspectrofluorimetrically using fura-2 fluorescence. KCl-induced depolarization, BAY-K 8644, and readdition of calcium to Ca-free depolarizing medium all produced a nifedipine-inhibitable increase in cytosolic calcium concentration. The existence of voltage-gated calcium channels in communication-competent cells suggests the possibility of propagation of depolarizing signals across the syncytium. This was studied by microapplication of KCl to the microenvironment of a single cell and monitoring fura-2 fluorescence in remote cells. This maneuver resulted in propagating calcium waves in communication-competent monolayers; calcium waves could not be evoked in monolayers exposed to an alkanol-type gap junction uncoupler, octanol. It is concluded that cultured rat mesangial cells form a syncytium capable of propagating calcium transients from a single depolarized cell to its coupled neighbors.

Arteriolar renin and vascular effects of angiotensin II in juxtamedullary nephrons

The SJMNs made accessible in the in vitro juxtamedullary nephron preparation possess an arteriolar renin and Ang II distribution similar to other nephron populations; renin-rich cells prevail in the JAA. Physiological studies have documented that exogenous Ang II constricts both pre- and postglomerular vessels of SJMNs. However, Ang II predominantly increases afferent resistance along the JAA. A functional interaction between Ang II and prostaglandins is likely to occur in preglomerular vessels and deserves further assessment. An additive, functional interaction was demonstrated between Ang II and autoregulation in afferent arterioles. Calcium channel blockers interfere with Ang II-induced constriction only in preglomerular vessels of SJMNs.

Tubuloglomerular feedback dependence of autoregulation in rat juxtamedullary afferent arterioles

Experiments were performed in blood-perfused juxtamedullary nephrons in vitro to evaluate the tubuloglomerular feedback (TGF) dependence of autoregulatory vasoconstriction in mid-to-late (mAA) and juxtaglomerular (jAA) afferent arterioles. Videometric measurements were made of perfusion pressure (PP) dependent changes in lumen diameter of superficial vessels before and after acute inhibition of the TGF mechanism by direct microinfusion of 0.1 mM furosemide solution into the macula densa (MD) segment. When PP was raised from 60 to 123 +/- 7 mm Hg in seven vessels, jAA diameter decreased by 29 +/- 3% (SEM, N = 7). During furosemide infusion with the same change in PP, jAA diameter decreased only 7 +/- 2%. After calcium channel blockade with 1 micromolar nimodipine, jAA lumen diameter increased by 21 +/- 7%. A similar pattern of responses was observed in eight jAA where TGF was inhibited with an oil block at the MD. mAA autoregulatory responses were also blunted by TGF inhibition. Raising PP from 60 to 120 mm Hg resulted in 15 +/- 2% and 7 +/- 2% decreases in mAA luminal diameter before and after TGF inhibition. These results demonstrate that the autoregulatory responses in mid- and juxtaglomerular afferent arteriolar segments are mediated by both TGF and a TGF-independent myogenic mechanism.

Indirect assessment of renal dysfunction in patients taking cyclosporin A for autoimmune diseases

The reliability of increases in serum creatinine and serum urea above initial values in detecting decreases in glomerular filtration rate below initial values was assessed in patients taking cyclosporin A (CyA) for autoimmune diseases. Both serum creatinine and serum urea provided reasonable estimates of the decline in glomerular filtration rate when measured simultaneously and when compared to patients' own baseline values. Combination of both serum creatinine and serum urea improved the assessment of renal dysfunction, partly by reducing the influence of any analytical errors. Frequent measurements, precise baseline evaluation and standardization of procedures can be expected to increase further the precision of assessing renal dysfunction from serum measurements. Hence, careful evaluation of changes in serum creatinine, with the option to include changes in serum urea, can provide a simple and reliable way of monitoring changes in renal function in patients taking CyA for autoimmune diseases.

Salt intake and renal hemodynamics in immature and mature Dahl salt-sensitive (DS/JR) and salt-resistant (DR/JR) rats

To determine if abnormalities in the maturation of renal function in Dahl salt-sensitive rats are associated with the development of hypertension, studies were performed in anesthetized 3 week old salt-sensitive (DS/JR) and salt-resistant (DR/JR) rats whose mothers were maintained on 0.15% (low-salt) during gestation and either 0.15% or 2.0% (high-salt) NaC1 diets after parturition. Mature DS/JR and DR/JR rats were maintained on either 0.15% or 2.0% NaC1 diets after weaning and studied at 8 to 9 weeks of age. High-salt diet raised blood pressure (BP) and reduced glomerular filtration rate (GFR) and renal blood flow (RBF) in mature DS/JR rats, but had no effect on BP, GFR and RBF in mature DR/JR rats. In immature DS/JR and DR/JR animals, high-salt intake resulted in poor growth with reductions in GFR and RBF in the DS/JR group. The response to acute volume expansion, (5% body weight physiologic saline infusion) differed among the groups. Mature rats all vasodilated while immature high-salt DS/JR did not, and immature low-salt DS/JR vasoconstricted. These studies demonstrated that both mature and immature DS/JR rats evidence abnormal responses to acute and chronic salt loading. Early exposure to high-salt intake affects the maturation of renal function in the DS/JR group. An enhanced vascular sensitivity to sodium is present at critical periods of postnatal development in DS/JR rats.

Autoregulation and tubuloglomerular feedback in juxtamedullary glomerular arterioles

Videometric measurements of changes in vessel lumen diameters were made to investigate autoregulatory and tubuloglomerular feedback (TGF) responses of early efferent arterioles (EA), mid-to-late afferent arterioles (MAA), and terminal, juxtaglomerular afferent arterioles (JAA) in rat juxtamedullary nephrons in vitro. High-contrast shadow-cast images of blood-perfused arterioles at the glomerular vascular pole were obtained with incident illumination and long-working-distance objectives fitted to a compound microscope. In response to an increase in blood perfusion pressure from 60 to 140 mmHg, strong autoregulatory vasoconstriction was observed in the MAA and JAA, with respective reductions in mean luminal diameter of 23 +/- 4 and 40 +/- 4% (mean +/- SE); EA diameter was unchanged. In response to TGF excitation by direct microinjection of Ringer solution into the cortical thick ascending limb segment near the macula densa, JAA luminal diameter decreased by 34 +/- 5%. The TGF responses were completely inhibited by the addition of 0.1 mM furosemide to the tubular injectate. Calcium channel blockade achieved by adding 1 microM nimodipine to the superfusate had no effect on early EA diameter but produced a blood pressure-dependent JAA and MAA vasodilation and complete inhibition of autoregulatory responses. These results provide direct evidence that the distal afferent arteriole in juxtamedullary nephrons is a major effector site for both renal autoregulation and tubuloglomerular feedback.

Transport-coupling hypothesis of tubuloglomerular feedback signal transmission

A mathematical model was used to explore the transport-coupling hypothesis of tubuloglomerular feedback (TGF) signal transmission from the macula densa (MD) to the extraglomerular mesangium (EGM) within the juxtaglomerular apparatus (JGA). The transport-coupling hypothesis supposes that changes in MD transport alter the ionic composition of the EGM interstitium, thereby stimulating the Goormaghtigh cells. This hypothesis is based on the avascularity of the EGM and the presence of a narrow cleft (JGA cleft) between the MD and Goormaghtigh cells. The model describes NaCl and water transport by MD cells and mass conservation in the JGA cleft. It calculates cleft water flow and NaCl concentration [( NaCl]). If the cleft is narrow, the model predicts that cleft [NaCl] will vary directly with luminal [NaCl] and net MD NaCl transport. With strong active NaCl transport, the MD cell plaque may act as an ionic amplifier, in that small changes in luminal [NaCl] might elicit much larger concentration changes within the cleft. Even without active NaCl transport, cleft [NaCl] could remain coupled to luminal [NaCl] if the MD cells passively secrete NaCl. With high hydraulic conductivity, cleft [NaCl] also varies with luminal osmolarity. With a wide cleft, a low diffusional resistance of the EGM interstitium, or swollen MD lateral intercellular spaces, the transport coupling between cleft and luminal [NaCl] is markedly attenuated. The predictions of our model of large changes in JGA interstitial composition agree well with published measurements made in Amphiuma. However, the low Na+-K+-ATPase content and high water permeability of mammalian MD suggest that the transport-coupling effects in mammals may be significantly less pronounced than in Amphiuma.

Inhibition of myogenic autoregulation in cyclosporine nephrotoxicity in the rat

The mechanisms responsible for the impairment of renal blood flow (RBF) autoregulation in cyclosporine nephrotoxicity were investigated with clearance and micropuncture studies in anesthetized rats. Early chronic cyclosporine nephrotoxicity (CCN) was induced in male rats by daily intramuscular injection of 10 mg/kg/day cyclosporine-A in olive oil for 7 days; control (CON) rats received vehicle injections. Glomerular filtration rate and RBF were both reduced by 33% in CCN when compared to CON rats. RBF autoregulation was also significantly impaired in CCN, with an autoregulation index (AI) of 0.53 +/- 0.03 vs. 0.16 +/- 0.01 in CON rats. Micropuncture studies showed that the tubuloglomerular feedback (TGF) system is not impaired in CCN. Rather, in CCN there was a slight resetting such that the maximum TGF response was greater and the onset occurred at lower rates of perfusion than in CON. In contrast, further micropuncture studies demonstrated that TGF-independent autoregulation of glomerular capillary pressure was significantly impaired in CCN, with an AI of 0.86 +/- 0.09 vs. 0.57 +/- 0.06 in CON. These results indicate that the loss of autoregulatory ability in rats with CCN results from substantial impairment of the myogenic autoregulatory mechanism that is an intrinsic property of the preglomerular vasculature of the kidney.

Cyclosporine nephrotoxicity: blood volume, sodium conservation, and renal hemodynamics

Glomerular filtration rate (GFR) and renal blood flow (RBF) are depressed by chronic cyclosporine treatment. We examined the hypothesis that depletion of extracellular or intravascular fluid volume contributes to the renal vasoconstriction of early cyclosporine nephrotoxicity (CCN). Control and CCN rats were given 10 mg/kg cyclosporine A or vehicle intramuscularly daily for 7 days. The effects of extracellular volume expansion, both acute (AVE, 10% body wt saline) and chronic (CVE, 10% body wt/day saline ip, 10 days including cyclosporine A treatment period), on renal hemodynamics were measured. In CCN, AVE completely normalized GFR and RBF, whereas CVE partially prevented the development of CCN. Renal autoregulatory ability was depressed in CCN but was largely restored by AVE. Intravascular volumes were measured with Evans blue and 51Cr-labeled red cells. Plasma and red cell volumes were reduced by 24% in CCN, indicating circulatory hypovolemia. Acute repletion of the deficit in blood volume by acute administration of an isoncotic solution (1.8 ml/100 g body wt of 5% albumin in isotonic saline) restored GFR and RBF to levels similar to those in control rats. Extracellular fluid volume, estimated as inulin space, was similar in both CCN and control groups. A metabolic study (7 day) showed stool Na loss in CCN to be twice that in controls but both groups remained in sodium balance. We conclude that the renal vasoconstriction produced in the rat by short-term cyclosporine treatment is, at least in part, prerenal in origin and related to the development of circulatory hypovolemia.

In vivo measurement of tubular fluid ferrocyanide with carbon-fiber microelectrodes

Techniques to construct carbon-fiber microelectrodes and to measure ferrocyanide ion concentration in single nephrons are described. The measurement involves polarizing an inert carbon-fiber microelectrode 500 mV positive with respect to a Ag-AgCl reference, while measuring the faradic current produced by the oxidation of ferrocyanide. A carbon fiber (5-7 micron diam) is heat sealed into a glass micropipette that is then sharpened, silanized, and electrochemically pretreated to minimize electrode degradation by protein. Circuit diagrams for an inexpensive voltage clamp-current monitor and a data sampling device are presented. The electrodes show a linear response to changes in ferrocyanide concentration in large and very small (20 nl) volumes in vitro. The electrodes were used in an electrochemical microassay to determine tubular fluid-to-plasma ferrocyanide concentration ratios and nephron filtration rates with proximal micropuncture samples. The results show excellent agreement with paired determinations using [3H]inulin. In vivo proximal tubule perfusion experiments show a rapid linear response to changes in tubular fluid ferrocyanide concentration. These electrodes permit rapid quantitative measurements of ferrocyanide concentration and water transport in the proximal tubule and may be useful in other biological systems.

Cyclosporine nephrotoxicity: sodium excretion, autoregulation, and angiotensin II

Cyclosporine-induced nephrotoxicity (CIN) was studied in rats treated for 7 days with cyclosporine (10 mg x kg-1 x day-1 im) or vehicle (CON). CIN rats displayed characteristic reductions in glomerular filtration (GFR) and renal blood blood flow (RBF), and electron microscopy showed injury to proximal cells. Metabolic studies (7 day) showed significantly lower renal sodium excretion in conscious CIN rats compared with CON. In anesthetized rats at similar blood pressures, nephron GFR (SNGFR) was lower in CIN than CON, but fractional Na reabsorption was similar. In CIN, SNGFR, measured proximally to block flow to the sensing site of tubuloglomerular feedback (TGF) at the macula densa, was not significantly different than distal SNGFR. The rate of distal fluid delivery was significantly lower in CIN than in CON. Inhibition of the renin-angiotensin system (RAS) with captopril (CAP, 10 mg/kg iv), or saralasin (SAR, 0.3 mg x kg-1 x h-1 iv) caused marked arterial hypotension in CIN and a fall in renal vascular resistance (RVR). With arterial pressure controlled, CAP or SAR increased GFR and RBF, and reduced RVR in CIN, but did not reverse the renal deficits compared with similarly treated CON. RBF autoregulation in CIN was impaired between 90 and 140 mmHg but was partially restored by CAP. We conclude that both the filtered load and excretion rate of sodium in CIN are significantly reduced compared with controls, that SNGFR in CIN is not depressed by TGF in response to elevated distal fluid delivery, and that the RAS is not a primarily mediator of the renal vasoconstriction in CIN.

Tubuloglomerular feedback control of distal fluid delivery: effect of extracellular volume

A closed-feedback loop micropuncture method was used to examine tubuloglomerular feedback (TGF) and the regulation of distal fluid delivery in hydropenic rats (CON), moderately hemorrhaged rats (HEM), and rats given desoxycorticosterone (DOC) and 0.6% saline to drink. Distal delivery and TGF response curves were measured with four samples per nephron: a spontaneous early distal collection, two distal collections during moderate (7.5 nl/min) and saturating (30 nl/min) perturbations in nephron fluid load, and a proximal collection to measure single-nephron glomerular filtration rate (SNGFR) during TGF inhibition. Arterial pressure, predistal volume reabsorption, SNGFR, and early distal flow were significantly higher in DOC than in HEM; the CON group exhibited intermediate values. Except for a greater maximum TGF response in HEM, the normalized TGF responses were similar in all three groups, as was the regulation of distal fluid delivery. However, the TGF onset threshold and the TGF operating point, defined by the spontaneous rates of early distal flow and SNGFR, were reset such that distal fluid delivery and SNGFR were higher in DOC than in HEM, as was renal sodium excretion. The results show that the level around which TGF stabilizes distal fluid delivery is reset when extracellular fluid volume is altered.