Inhibition of renal rho kinase attenuates ischemia/reperfusion-induced injury.

The Rho kinase pathway plays an important role in dedifferentiation of epithelial cells and infiltration of inflammatory cells. For testing of the hypothesis that blockade of this cascade within the kidneys might be beneficial in the treatment of renal injury the Rho kinase inhibitor, Y27632 was coupled to lysozyme, a low molecular weight protein that is filtered through the glomerulus and is reabsorbed in proximal tubular cells. Pharmacokinetic studies with Y27632-lysozyme confirmed that the conjugate rapidly and extensively accumulated in the kidney. Treatment with Y27632-lysozyme substantially inhibited ischemia/reperfusion-induced tubular damage, indicated by reduced staining of the dedifferentiation markers kidney injury molecule 1 and vimentin, and increased E-cadherin relative to controls. Rho kinase activation was inhibited by Y27632-lysozyme within tubular cells and the interstitium. Y27632-lysozyme also inhibited inflammation and fibrogenesis, indicated by a reduction in gene expression of monocyte chemoattractant protein 1, procollagen Ialpha1, TGF-beta1, tissue inhibitor of metalloproteinase 1, and alpha-smooth muscle actin. Immunohistochemistry revealed reduced macrophage infiltration and decreased expression of alpha-smooth muscle actin, collagen I, collagen III, and fibronectin. In contrast, unconjugated Y27632 did not have these beneficial effects but instead caused systemic adverse effects, such as leukopenia. Neither treatment improved renal function in the bilateral ischemia/reperfusion model. In conclusion, the renally targeted Y27632-lysozyme conjugate strongly inhibits tubular damage, inflammation, and fibrogenesis induced by ischemia/reperfusion injury.

Bioanalysis and pharmacokinetics of the p38 MAPkinase inhibitor SB202190 in rats.

We have developed a sensitive and reproducible high performance liquid chromatography (HPLC)-UV method for the quantification of the p38 MAPkinase inhibitor SB202190 in serum, kidney homogenates and urine samples. Liquid-liquid extraction of SB202190 from the samples was performed using diethylether after adding a derivative of SB202190 as internal standard (I.S.). Chromatography was carried out using a C8 reversed-phase column with an isocratic mobile phase consisting of acetonitrile-water-trifluoroacetic acid (30:70:0.1, v/v/v; pH 2.0). Both drug and I.S. were measured at 350 nm and eluted at 5.0 and 10.6 min, respectively. Peak-height ratios of the drug and the I.S. were used for the quantification of SB202190 from the different matrixes. The limit of quantitation of SB202190 in serum, kidney and urine were 0.25 microg/ml, 1 microg/g and 1 microg/ml, respectively. The average recoveries were 74, 75 and 92% in serum, kidney and urine, respectively. The intra- and inter-day precision (% CV) and accuracy (% bias) were below 15% for all concentrations. The method was successfully applied for a pharmacokinetic study of SB202190 in rats.

Renal targeting of captopril selectively enhances the intrarenal over the systemic effects of ACE inhibition in rats.

1 In previous studies on the renal targeting of the ACE inhibitor captopril, we demonstrated that a 6 fold increased concentration of this drug could be obtained in the kidney after conjugation to the low-molecular-weight protein lysozyme. In this study, we investigated in unrestrained rats whether systemic administration of captopril-lysozyme also results in an enhanced effect on renal parameters, relative to the systemic effects. 2 Renal effects: intravenous infusion of captopril-lysozyme for 6 h resulted in a more pronounced increment of renal blood flow (31+/-2% vs 17+/-4% at 0.5 mg kg(-1) 6h(-1), P<0.01) and an approximately 5 fold enhanced natriuresis (167+/-17% vs 36+/-7% at 1 mg kg(-1) 6 h(-1), P<0.001) in comparison with equimolar amounts of captopril as a free drug. In correspondence with these findings, renal ACE inhibition was potentiated approximately 5 fold (-50+/-4% vs -22+/-3% at 1 mg kg(-1) 6 h(-1), P<0.001). 3 Systemic effects: conjugated captopril did not affect blood pressure in dosages up to 5 mg kg(-1) 6 h(-1). This effect coincided with a less pronounced inhibition of the pressor response to intravenously administered angiotensin I (-12+/-3% vs -66+/-5% at 1 mg kg(-1) 6 h(-1), P<0.001), and a markedly attenuated plasma ACE inhibition (-19+/-2% vs -37+/-3% at 1 mg kg(-1) 6 h(-1), P<0.001) compared to an equivalent dose of free captopril. 4 An experiment of continued intravenous administration of captopril-lysozyme for 7 days in nephrotic syndrome demonstrated that the conjugate is also active in renal disease: the antiproteinuric response was substantially augmented (-67+/-5% vs -15+/-7% at 4 mg kg(-1) 24 h(-1), P<0.001) compared to the free drug, in the absence of blood pressure reduction. 5 These data demonstrate that intravenous administration of a captopril-lysozyme conjugate leads to more selective renal ACE inhibition and enhanced renal effects as well as less systemic effects compared to captopril itself.

Targeting of doxorubicin to the urinary bladder of the rat shows increased cytotoxicity in the bladder urine combined with an absence of renal toxicity.

Targeting of anti-tumor drugs to the urinary bladder for the treatment of bladder carcinoma may be useful, since these agents generally have a low degree of urinary excretion and are highly toxic elsewhere in the body. The anti-tumor drug doxorubicin was coupled to the low-molecular weight protein lysozyme via the acid-sensitive cis-aconityl linker. All free amino groups of the lysozyme were used for drug attachment to achieve intact excretion of the doxorubicin-aconityl-lysozyme conjugate into the bladder. In the bladder, the cytotoxic drug should be regenerated through acidification of the urine. First, the doxorubicin-aconityl-lysozyme conjugate was tested in rats for its target specificity and general toxicity. Wistar rats were injected intravenously with 2 mg/kg free doxorubicin or 10 mg/kg lysozyme-conjugated doxorubicin. Total urinary excretion of doxorubicin was about 10 times higher if the drug was coupled to lysozyme (39 +/- 3% versus 4.4 +/- 0.4%). Free doxorubicin had no detectable toxic effects on heart, liver and lung but caused severe renal damage (proteinuria, N-acetylglucosaminidase excretion and glomerulosclerosis). None of the rats injected with doxorubicin-lysozyme conjugate showed such renal toxicity. Second, we tested whether doxorubicin could be released from the conjugate in the bladder through acidification of the urine and if the released doxorubicin could still exert a cytotoxic effect. Doxorubicin-aconityl-lysozyme (2 mg/kg conjugated doxorubicin, i.v.) was administered in rats with acidified urine (pH 6.1 +/- 0.1) and in rats with a high urinary pH (8.2 +/- 0.4). Ten times more doxorubicin was released from the conjugate in the group with acidified urine (15 +/- 7% versus 1.7 +/- 0.1%). In agreement with this, cytotoxicity was also higher in the low pH group (IC50 of 255 +/- 47 nM versus 684 +/- 84 nM doxorubicin). In conclusion, a specific delivery of doxorubicin to the urinary bladder combined with a reduced toxicity of doxorubicin in the kidneys can be achieved by coupling this anti-tumor drug to the low-molecular weight protein lysozyme via an acid-labile linker. A release of cytotoxic doxorubicin in the urinary bladder can be achieved by acidification of the urine. This technology, after further optimization, may provide an interesting tool for the treatment of bladder carcinoma.

Renal targeting of captopril using captopril-lysozyme conjugate enhances its antiproteinuric effect in adriamycin-induced nephrosis.

INTRODUCTION: High-sodium intake blunts the renoprotective efficacy of angiotensin-converting enzyme (ACE) inhibitors. We investigated whether targeting the drug to the kidneys may attenuate the inferior response to ACE inhibitor (ACE-I) under high-sodium conditions. The ACE-I, captopril, was coupled to the low molecular weight protein (LMWP) lysozyme, yielding captopril-lysozyme conjugates that accumulate specifically in the proximal tubular cells of the kidneys. We compared the antiproteinuric efficacy of captopril to that of the captopril-lysozyme conjugate in adriamycin-induced proteinuric rats fed with a high-sodium diet. MATERIALS AND METHODS: Rats with adriamycin (single injection 2 mg/kg)- induced proteinuria were put on a high-sodium diet (HS; 3% NaCl). When stable proteinuria developed at 5.5 weeks, animals were assigned to the following subcutaneous treatments: (1) vehicle (n=7); (2) lysozyme (equivalent to the amount in conjugate) (n=7); (3) captopril (5 mg/kg/24 hours) (n=8); (4) captopril-lysozyme conjugate (captopril content equivalent to 1mg captopril/kg/24 hours) (n=7). Blood pressure and proteinuria were monitored. After 10 days of treatment the rats were sacrificed and kidneys and plasma were removed. RESULTS: Results are given as mean + S.E.M. After injection with adriamycin at t=0, stable proteinuria developed, amounting to 547+79 mg/24 hours at week 5.5. Subsequently, after seven and nine days of treatment, no reduction of proteinuria was observed in the captopril-treated group. In contrast, a significant reduction in proteinuria, amounting to 35+4% (day seven) and 25+2% (day nine), was observed in the captopril-lysozyme conjugate group (p<0.05 compared with the captopril group). In contrast, blood pressure was reduced in the captopril-treated group by 13.9+2.9 mmHg, while in the captopril-lysozyme treated group, an increase of 7.9+3.3 mmHg was found. Renal ACE activity was lowered by 30% in the captopril, as well as in the captopril-lysozyme conjugate treated group, compared with control. Furthermore, the ratio of kidney: plasma levels of captopril almost doubled as a consequence of coupling to lysozyme. CONCLUSION: In proteinuric rats fed with a high-sodium diet, captopril induced a reduction in blood pressure without an effect on proteinuria. In contrast, renal targeting of a five times lower dose of the ACE-I with the captopril-lysozyme conjugate reduced proteinuria without reducing blood pressure. Therefore, renal targeting of ACE-I may be a promising strategy to optimise the therapeutic response of ACE-I.

Cell-specific delivery of a transforming growth factor-beta type I receptor kinase inhibitor to proximal tubular cells for the treatment of renal fibrosis.

PURPOSE: Activation of tubular epithelial cells by transforming growth factor-beta (TGF-beta) plays an important role in the pathogenesis of renal tubulointerstitial fibrosis. We developed a renally accumulating conjugate of a TGF-beta type-I receptor kinase inhibitor (TKI) and evaluated its efficacy in vitro and in vivo. METHODS: TKI was conjugated to the protein Lysozyme (LZM) via a platinum-based linker. TKI-LZM was evaluated in human tubular cells (HK-2) for its anti-fibrotic activity. Plasma, kidney and urine drug levels after a single intravenous dose of TKI-LZM in rats were determined by HPLC or immunodetection. Anti-fibrotic effects of TKI-LZM were examined in the unilateral ureteral obstruction (UUO) model. RESULTS: TKI-LZM conjugate was successfully synthesized at an 1:1 drug/carrier ratio, and inhibited TGF-beta1-induced procollagen-1alpha1 gene expression in HK-2 cells. In vivo, TKI-LZM accumulated rapidly in tubular cells and provided a local depot for 3 days. Interestingly, a single dose of TKI-LZM inhibited the activation of tubular cells and fibroblasts in UUO rats and reduced renal inflammation. In contrast, free TKI at an equimolar (low) dosage exhibited little effects. CONCLUSIONS: Inhibition of TGF-beta signaling by local drug delivery is a promising antifibrotic strategy, and demonstrated the important role of tubular activation in renal fibrosis.

Intracellular delivery of the p38 mitogen-activated protein kinase inhibitor SB202190 [4-(4-fluorophenyl)-2-(4-hydroxyphenyl)-5-(4-pyridyl)1H-imidazole] in renal tubular cells: a novel strategy to treat renal fibrosis.

During renal injury, activation of p38 mitogen-activated protein kinase (MAPK) in proximal tubular cells plays an important role in the inflammatory events that eventually lead to renal fibrosis. We hypothesized that local inhibition of p38 within these cells may be an interesting approach for the treatment of renal fibrosis. To effectuate this, we developed a renal-specific conjugate of the p38 inhibitor SB202190 [4-(4-fluorophenyl)-2-(4-hydroxyphenyl)-5-(4-pyridyl)1H-imidazole] and the carrier lysozyme. First, we demonstrated that SB202190 inhibited the expression of albumin-induced proinflammatory (monocyte chemoattractant protein-1) and transforming growth factor (TGF)-beta1-induced profibrotic (procollagen-Ialpha1) genes over 50% in renal tubular cells (normal rat kidney-52E). Next, we conjugated SB202190 via a carbamate linkage to lysozyme. However, this conjugate rapidly released the drug upon incubation in serum. Therefore, we applied a new platinum(II)-based linker approach, the so-called universal linkage system (ULS), which forms a coordinative bond with SB202190. The SB202190-ULS-lysozyme remained stable in serum but released the drug in kidney homogenates. SB202190-ULS-lysozyme accumulated efficiently in renal tubular cells and provided a local drug reservoir during a period of 3 days after a single intravenous injection. Treatment with SB202190-ULS-lysozyme inhibited TGF-beta1-induced gene expression for procollagen-Ialpha1 by 64% in HK-2 cells. Lastly, we evaluated the efficacy of a single dose of the conjugate in the unilateral renal ischemia-reperfusion rat model. A reduction of intrarenal p38 phosphorylation and alpha-smooth muscle actin protein expression was observed 4 days after the ischemia-reperfusion injury. In conclusion, we have developed a novel strategy for local delivery of the p38 MAPK inhibitor SB202190, which may be of use in the treatment of renal fibrosis.

Renal-selective delivery and angiotensin-converting enzyme inhibition by subcutaneously administered captopril-lysozyme.

In previous studies, we have demonstrated that the low molecular weight protein lysozyme can be used as a renal-selective drug carrier for delivery of the angiotensin-converting enzyme (ACE) inhibitor captopril. Typically, such macromolecular drug-targeting preparations are administered intravenously. In the present study, we investigated the fate of captopril-lysozyme following subcutaneous administration, a convenient route for long-term treatment. The absorption from the subcutaneous injection site and renal uptake of lysozyme were determined by gamma scintigraphy in rats. Bioavailability, renal accumulation, and stability of the captopril-lysozyme conjugate were evaluated by high performance liquid chromatography analysis and by ACE activity measurements. Lysozyme was absorbed gradually and completely from the subcutaneous injection site within 24 h and accumulated specifically in kidneys. After subcutaneous injection of the captopril-lysozyme conjugate, higher renal captopril levels and lower captopril-lysozyme levels in urine indicated the improved renal accumulation in comparison with intravenous administration of the conjugate, as well as its stability at the injection site. After both treatments, captopril-lysozyme conjugate effectuated renal ACE inhibition, whereas plasma ACE was not inhibited. In conclusion, our results demonstrate that we can use the subcutaneous route to administer drug delivery preparations like the captopril-lysozyme conjugate.

Specific drug delivery to the kidney.

The mesangial cells of the glomerulus, the proximal tubular cells and the interstitial fibroblasts are the first choice targets for renal drug delivery since they play a pivotal role in many disease processes in the kidney. In the present review, only targeting to the proximal tubular cell is addressed because only this has been studied extensively. Two approaches of drug delivery to the proximal tubular cell have been studied up to now, the prodrug/softdrug and low-molecular-weight protein (LMPWP) approach. Most research on tubular specific drug delivery has focused on the development of amino-acid prodrugs that, after delivery, require activation by more or less kidney-selective enzymes. Large differences in renal selectivity are found. For some prodrugs, a rapid removal of the released drug from the kidney explained the low renal selectivity whereas for others, cleavage in non-target tissue and insufficient transport across the cell to the enzyme site seemed mainly responsible. The LMWP approach is based on drug attachment to a protein (<30 kD) that is freely filtered through the glomerulus and after accumulation is selectively catabolized in the lysosomes of the proximal tubular cell. Using LMWPs as drug carriers, a higher renal selectivity can be attained and a broader range of drugs can be attached while the rate of drug release can also be manipulated. The studies with captopril-lysozyme and naproxen-lysozyme clearly showed that targeting resulted in a higher renal selectivity and that drugs delivered into and regenerated in the proximal tubular cell exert renal selective pharmacological activity. Further testing will provide more definite data on the added value of this delivery technology.

Effects of anti-proteinuric therapy with angiotensin-converting-enzyme inhibition on renal protein catabolism in the adriamycin-induced nephrotic rat.

A direct consequence of glomerular protein leakage is an increased exposure of proximal tubular cells to proteins. The aim of the present study was to examine whether chronic proteinuria affects the tubular handling of proteins and whether anti-proteinuric therapy by angiotensin-converting-enzyme (ACE) inhibition restores this tubular function. Renal uptake and catabolic rate of the low-molecular-weight protein (LMWP) myoglobin was determined in anaesthetized control and adriamycin-induced nephrotic rats by external counting after radiolabelling. Proteinuria correlated with the uptake as well as the catabolism of myoglobin. The higher the proteinuria, the lower was the renal uptake of myoglobin (r =0.72, P =0.002). Also, the catabolic rate of myoglobin (r =0.80, P =0.0002) was lower with increasing severity of proteinuria. During treatment with the ACE inhibitor lisinopril, proteinuria was lowered by 79+/-9% (mean+/-S.E.M.). Renal uptake and catabolic rate of the LMWP were not restored by ACE inhibition. The catabolic rate of myoglobin was even decreased further with 48+/-5% compared with pretreatment levels. In summary, adriamycin-induced proteinuria is associated with a lower uptake and a lower catabolic rate of LMWP in the proximal tubule. ACE inhibition lowers proteinuria, but does not restore the affected LMWP uptake and rate of catabolism. The rate of LMWP catabolism is even decreased further. In contrast, the urinary excretion of N -acetyl glucosaminidase, the tubular marker of toxicity, was effectively returned to normal levels during ACE inhibition. Taken together, the data suggest that proteinuria is toxic for the proximal tubular cells and that ACE inhibition protects the remaining functional tubular cells directly against destruction through decreasing hypercatabolism.