Calcium, cyclic AMP, and MAP kinases: dysregulation in polycystic kidney disease.

Low intracellular calcium, present in untreated polycystic kidney epithelia, results in a proliferative response to cyclic adenosine monophosphate. Treatment with a calcium channel blocker (CCB) caused exacerbation of autosomal dominant polycystic kidney disease in rats. Data regarding use of CCBs in human polycystic kidney disease (PKD) are limited and mixed. Thus, it is premature to extrapolate these findings to human PKD.

Increased renal expression of monocyte chemoattractant protein-1 and osteopontin in ADPKD in rats.

BACKGROUND: Human autosomal-dominant polycystic kidney disease (ADPKD) is variable in the rate of deterioration of renal function, with end-stage renal disease (ESRD) occurring in only approximately 50% of affected individuals. Evidence suggests that interstitial inflammation may be important in the development of ESRD in ADPKD. Han:SPRD rats manifest ADPKD that resembles the human disease. Homozygous cystic (Cy/Cy) rats develop rapidly progressive PKD and die near age 3 weeks. Heterozygous (Cy/+) females develop slowly progressive PKD without evidence of renal dysfunction until the second year of life, whereas heterozygous (Cy/+) males develop more aggressive PKD with renal failure beginning by 8 to 12 weeks of age. METHODS: To examine the relationship between proinflammatory chemoattractants and the development of interstitial inflammation and ultimately renal failure in ADPKD, we evaluated monocyte chemoattractant protein-1 (MCP-1) and osteopontin mRNAs and proteins in kidneys from Han:SRPD rats. RESULTS: MCP-1 and osteopontin mRNAs, expressed at low levels in kidneys from normal (+/+) animals at all ages, were markedly elevated in kidneys from 3-week-old Cy/Cy animals. In kidneys from heterozygous (Cy/+) adults of either gender, MCP-1 and osteopontin mRNAs were more abundant than normal; MCP-1 mRNA was more abundant in Cy/+ males than in females. Thus, chemoattractant mRNA expression correlated with the development of renal failure in Cy/Cy and Cy/+ rats. Osteopontin mRNA, localized by in situ hybridization, was moderately expressed in the renal medulla of normal animals; however, this mRNA was expressed at very high levels in the cystic epithelia of Cy/+ and Cy/Cy animals. MCP-1 and osteopontin proteins, localized by immunohistochemistry, were weakly detected in +/+ kidneys but were densely expressed in Cy/Cy and in adult Cy/+ kidneys, primarily over cystic epithelium. Increased expression of chemoattractants was associated with the accumulation of ED-1 positive cells (macrophages) in the interstitium of cystic kidneys. CONCLUSIONS: We suggest that proinflammatory chemoattractants have a role in the development of interstitial inflammation and renal failure in ADPKD.

Long-term ammonium chloride or sodium bicarbonate treatment in two models of polycystic kidney disease.

Administration of ammonium chloride aggravates, while short-term administration of sodium or potassium bicarbonate lessens the development of polycystic kidney disease in Han:SPRD rats. We have conducted studies to determine whether the protection afforded by the administration of sodium bicarbonate is sustained and prevents development of uremia during chronic administration and whether the effects of the administration of ammonium chloride and sodium bicarbonate are also observed in a different model of polycystic kidney disease, the CD1-pcy/pcy mouse. We found that chronic administration of 200 mM sodium bicarbonate to Han:SPRD rats inhibited cystic enlargement and prevented the subsequent development of interstitial inflammation, chronic fibrosis, and uremia. We also found that, while the administration of ammonium chloride has similar effects in Han:SPRD rats and CD1-pcy/pcy mice, the administration of sodium bicarbonate is only protective in the Han:SPRD rats. This probably reflects differences in these models (predominately involvement of proximal tubules in Han:SPRD rats and of collecting ducts and distal tubules in pcy/pcy mice) and the different location and nature of the renal metabolic responses to the administration of acid or alkaline load.

Volumetric determination of progression in autosomal dominant polycystic kidney disease by computed tomography.

BACKGROUND: Autosomal dominant polycystic kidney disease (ADPKD) is characterized by progressive renal enlargement and renal failure. We evaluated sequential radiocontrast-enhanced computed tomography (CT) scans to determine the rate of kidney enlargement in patients with ADPKD. METHODS: Ten adult patients with ADPKD (4 men and 6 women) with initial serum creatinine levels 0.05), and 185 +/- 52 mL (P < 0.01), respectively. In 19 individual spherical cysts selected in six patients, the mean initial volume was 15.0 +/- 7.2 mL (range 1.1 to 137 mL), and the average rate of volume increase was 0.52 +/- 0.21 mL/month (P < 0.025, range 0.02 to 4.15 mL/month). In five patients who eventually required dialysis, 11.2 years after the initial CT scan, the initial cyst/kidney volume ratio (combined for both kidneys) exceeded 0.43; four patients with lower cyst/kidney volume ratios had serum creatinine levels <1.5 mg/dL, 8.7 years after the initial CT scan. CONCLUSIONS: On the basis of this preliminary survey of archival material, we conclude that conventional contrast-enhanced CT scans can be used to quantitate volume components of progression in ADPKD. The rates of individual kidney and cyst enlargement are highly variable within and between patients, but overall, the values increase over time. The volume fraction of kidneys comprised of cysts may be a useful indicator of ADPKD progression.

Kid-1 expression is high in differentiated renal proximal tubule cells and suppressed in cyst epithelia.

The cDNA coding for the transcriptional repressor protein Kid-1 was cloned in a screen for zinc finger proteins, which are regulated during renal development and after renal ischemia. Kid-1 mRNA levels increase in the course of postnatal renal development and decrease after acute renal injury caused by ischemia or administration of folic acid. We have raised a monoclonal anti-Kid-1 antibody and demonstrate that the Kid-1 protein is strongly expressed in the proximal tubule of the adult rat kidney. During nephron development, the Kid-1 protein appears after the S-shaped body stage concomitantly with the brush-border enzyme alkaline phosphatase. In two animal models of polycystic kidney disease, the expression of Kid-1 is downregulated. The loss of expression of Kid-1 in cyst wall cells correlates with the loss of alkaline phosphatase histochemical staining. Kid-1 mRNA levels are also reduced in rodent renal cell carcinomas, another condition characterized by epithelial cell dedifferentiation and increased proliferation. We propose that Kid-1 plays an important role during the differentiation of the proximal tubule.

The effect of paclitaxel on the progression of polycystic kidney disease in rodents.

Woo et al (Nature 368:750-753) reported that parenteral administration of paclitaxel arrested the striking renal enlargement and prolonged life in C57BL/6J-cpk/cpk mice with a rapidly progressive form of polycystic kidney disease (PKD). In the current study, we sought to determine whether paclitaxel could alter the progression of other forms of hereditary PKD in rodents. Paclitaxel was administered by intraperitoneal injection to C57BL/6J-cpk/cpk mice and Han:SPRD-Cy/Cy rats with rapidly progressive PKD and to DBA/2FG-pcy/pcy mice and Han:SPRD-Cy/+ rats with slowly progressive PKD. Paclitaxel (150 micrograms/wk) prolonged the survival of cpk/cpk mice from 24.5 days to more than 65 days and decreased kidney weight relative to body weight from 16.5% at 21 days of age to 8.2% at more than 65 days of age. Mortality attributable to paclitaxel was 12%. By contrast, the administration of paclitaxel (0.1 to 15 mg/kg/wk) to 7- to 10-day-old Han:SPRD-Cy/Cy rats with rapidly progressive PKD had no effect on the course of the disease; moreover, paclitaxel caused severe side effects and premature death in all the Cy/Cy animals. Heterozygous male Cy/+ rats develop slowly progressive renal enlargement and azotemia. Paclitaxel, administered at 7, 15, or 27 mg/kg/wk to male Cy/+ rats from 4 until 10 weeks of age, reduced body weight gain, had an inconsistent effect on kidney weight relative to body weight, and had no effect on the serum urea nitrogen concentration. Mortality associated with the 7, 15, and 27 mg/kg/wk doses of paclitaxel was 0%, 15.4%, and 28.5%, respectively. DBA/2FG-pcy/pcy mice of either sex developed slowly progressive renal enlargement and azotemia. The administration of paclitaxel (100 to 150 micrograms/wk) from 2 to 10 weeks of age to DBA/2FG-pcy/pcy mice with cystic disease had no effect on the increase in kidney weight or on the level of serum urea nitrogen in comparison to untreated cystic animals. Mortality associated with 100- and 150-micrograms/wk doses of paclitaxel was 0% and 20%, respectively. We conclude that paclitaxel diminished the rate of renal enlargement and increased the life span of cpk/cpk mice but not Cy/Cy rats with rapidly progressive forms of PKD. Paclitaxel had no apparent benefit in Cy/+ rats nor pcy/pcy mice with slowly progressive PKD. On the basis of these studies in rodents, it appears that paclitaxel has limited potential usefulness as a therapeutic agent in the treatment of PKD.

Gender and the effect of gonadal hormones on the progression of inherited polycystic kidney disease in rats.

Human autosomal dominant polycystic kidney disease (ADPKD) is a common inherited disease and displays a gender dimorphism in renal disease progression. Han:SPRD-Cy rats manifest a form of ADPKD that is similar in many respects to that seen in humans. In Han:SPRD rats, male Cy/+ rats have more prominent renal changes and develop renal failure at an early age, whereas female Cy/+ rats exhibit less severe renal cystic change and have normal renal function until advanced age. To determine whether the male gonadal hormone, testosterone, contributes to this gender dimorphism, males were sham operated or castrated; some castrated rats were repleted with 5alpha-dihydrotestosterone. Female rats were sham operated or ovariectomized before sham operation or testosterone treatment. All treatments started at 4 weeks of age and ended at 10 weeks of age. Renal enlargement, cystic change, and renal function were assessed. In the males, castration reduced renal enlargement and cystic change; testosterone treatment abrogated these effects. Neither of these manipulations affected azotemia in male Cy/+ rats. In the females, testosterone was renotropic for both normal and cystic kidneys. In the Cy/+ females, testosterone treatment caused azotemia and an increase in the severity of the PKD. Ovariectomy blunted the effect of testosterone on cystic kidney enlargement. Testosterone treatment did not completely erase the gender-associated differences in azotemia in the Cy/+ rat. These data confirm the renotropic effects of testosterone and indicate that testosterone influences the progression of renal cystic change in male and female rats with ADPKD.

Modification of disease progression in rats with inherited polycystic kidney disease.

The most common inherited form of human polycystic kidney disease (PKD), autosomal dominant PKD (ADPKD), is a leading cause of chronic renal failure, but has a variable clinical presentation, with end-stage renal disease occurring in only 25% to 75%. Several findings are consistent with the idea that factors in addition to the primary mutation can affect the progression of cystic change and chronic renal failure in PKD. Epithelial cell proliferation is a central element in the pathogenesis of renal cysts. We postulated that the superimposition of a growth-promoting stimulus might promote more intense proliferation of cystic epithelial cells in inherited cystic disease. To study this, we subjected Han:SPRD rats, with a form of ADPKD that resembles human ADPKD, from 4 until 10 weeks of age to diets designed to promote tubule cell growth. The diets included supplemental NH4Cl (280 mmol/L in drinking water), limited dietary K+ (0.016% of diet; control diet was 1.1% K+), and increased dietary protein (50%; control diet was 23% protein). Treatments designed to promote cell growth caused more aggressive PKD in males and females, worsened azotemia in males, and resulted in azotemia in females (which normally develop PKD but not azotemia at the ages studied). NH4Cl, K+ restriction, and increased dietary protein each caused greater kidney enlargement in males (kidney weight/body weight ratios increased by 35%, 78%, and 105%, respectively) and worsened azotemia in males (serum urea nitrogen values increased by 63%, 514%, and 224%, respectively); in contrast, decreased dietary protein (4%) caused less severe PKD in males (kidney weight/body weight ratios decreased by 43%) and lessened azotemia in males (serum urea nitrogen values decreased by 49%). Similarly, NH4Cl and K+ restriction caused greater kidney enlargement in females (kidney weight/body weight ratios increased by 206% and 203%, respectively) and caused azotemia in females (serum urea nitrogen values increased by 177% and 430%, respectively). On the basis of these results, we conclude that growth-promoting stimuli can alter the expression of hereditary renal cystic disease. These findings demonstrate that the progression of hereditary renal cystic disease can be altered by factors in addition to the primary genetic defect.

In vivo adenovirus-mediated gene transfer into normal and cystic rat kidneys.

Gene transfer into the mammalian kidney has proved difficult because of the structural complexity of the organ and its low mitotic index. This article describes the use of intra-arterially injected adenovirus to study gene transfer into the rat kidney in vivo. By pre-chilling the kidney, and incubating the virus with the kidney in the cold for extended periods of time, we were able to successfully transfer a beta-galactosidase (beta-gal) reporter gene into the vasculature without ischemic injury to the kidney. Transfer occurred largely in the cortex when cold was used alone, whereas with the use of cold and vasodilators, transfer was accomplished into the outer medulla in both the inner and outer stripes. In the Han:SPRD rat model of autosomal dominant polycystic kidney disease (ADPKD), gene transfer occurred into the vasculature, some epithelial cysts and interstitial cells. This is the first description of substantial in vivo gene transfer into both normal and cystic kidneys. The methodology could find application in the creation of new models of renal disease, for in vivo therapeutic intervention or for genetic modification of an allograft at the time of harvest.

Renal expression of a transforming growth factor-alpha transgene accelerates the progression of inherited, slowly progressive polycystic kidney disease in the mouse.

Polycystic kidney disease (PKD) is a prevalent inherited disease in human beings. The pathogenesis of PKD is as yet unclear. The epidermal growth factor family of proteins has been implicated in PKD based largely on in vitro data. To determine whether these growth factors contribute to the progression of inherited PKD in vivo, we crossed mice with a transgene for human transforming growth factor-alpha (TGF-alpha, a member of the epidermal growth factor (EGF) family) and mice with the pcy gene (which causes a slowly progressive form of PKD very similar to human autosomal dominant PKD). Renal expression of the TGF-alpha transgene in cystic mice (homozygous for the pcy gene) accelerated the development of PKD as shown by an increased kidney weight as a percent of body weight and an increased volume density of renal cysts at 8.5 weeks of age. However, renal expression of the TGF-alpha transgene did not appear to precociously initiate cyst development (at 6.5 weeks), nor did it cause an increase in the final degree of renal enlargement (at 29 weeks). Thus TGF-alpha accelerated the enlargement of cysts once initiated. At 8.5 weeks of age, renal expression of the TGF-alpha mRNA correlated positively with the amount of renal enlargement. At all time points studied, cystic kidneys exhibited increased expression of c-myc mRNA as compared with phenotypic normal kidneys, consistent with PKD being a hyperplastic disease of renal tubules. However, the renal expression of c-myc in 8.5 week cystic kidneys, with or without the transgene, did not correlate with the degree of renal enlargement. The results of this study suggest that EGF-like proteins may accelerate the progression of inherited renal cystic disease. However, the final degree of cystic change is dictated by the primary disease process rather than by the continued presence of growth factor.

In vivo and in vitro osmotic regulation of HSP-70 and prostaglandin synthase gene expression in kidney cells.

As a function of the urinary concentrating mechanism, the cells of the renal medulla are exposed to elevated and constantly varying osmolalities and adapt to this environment by selectively expressing certain mRNAs. We evaluated the expression and regulation of two RNAs that may be important in adaptation of rental medullary cells to hyperosmolality. We demonstrate selective, modulated expression in the renal medulla of heat shock protein HSP-70 mRNA and prostaglandin synthase-1 mRNA, with the abundance of these two mRNAs regulated in vivo in concert with changes in medullary sodium and urea. We also determined the abundance of these mRNAs in cultured kidney cells (MDCK) in response to an increase in extracellular osmolality due to selected osmotic agents. HSP-70 and prostaglandin synthase-2 mRNA levels increased when extracellular osmolality was increased to 400-600 mosmol/kg by the addition of NaCl. At 500 mosmol/kg this response was evident at 6 h, was maximal near 24 h, and persisted for a total of 90 days. Prostaglandin synthase-1 mRNA levels in MDCK cells were also increased after chronic exposure to extracellular osmolality. Increased extracellular osmolality caused by agents to which cells are impermeable caused increased levels of HSP-70 and prostaglandin synthase-2 mRNAs, whereas increased extracellular osmolality caused by agents to which cells are permeable did not; thus osmotic regulation involved osmotic water movement. We conclude that the abundance of HSP-70 and prostaglandin synthase-1 mRNAs in the renal medulla is regulated in response to renal medullary osmolality and suggest that this may also be true for other medullary mRNAs yet to be described.

Effect of lovastatin on the development of polycystic kidney disease in the Han:SPRD rat.

Proliferation of tubular epithelial cells is a major element leading to cyst formation in Han:SPRD rats with autosomal dominant polycystic kidney disease (PKD). ras proteins are important in the control of renal cell proliferation, and ras gene expression is increased in PKD. Farnesyl pyrophosphate, an intermediate in the conversion of acetyl-CoA to cholesterol, is required for the activation of ras guanosine triphosphate (GTP)-binding proteins that are important in the execution of several cellular functions, including cell proliferation. 3-Hydroxy-3-methyl-glutaryl coenzyme A reductase inhibitors, such as lovastatin, reduce farnesyl production in responsive cells and thereby have potential for ameliorating the accelerated epithelial cell proliferation of PKD. We administered lovastatin to heterozygous (Cy/+) Han:SPRD rats (4 mg/kg/d subcutaneously) from age 4 to 10 weeks, a period of rapid cystic disease progression in these animals. Untreated male Cy/+ rats developed larger cystic kidneys and had more severe renal functional impairment than females, as reported previously. In males, lovastatin significantly decreased cystic kidney size (referenced to body weight), the volume density of cysts, and the serum urea nitrogen level 14.5%, 24.4%, and 25.6/%, respectively. The corresponding changes in females were insignificant, and lovastatin had no effect on kidney weight or serum urea nitrogen in homozygous (+/+) normal male animals. On the basis of these results we conclude that lovastatin diminishes the severity of PKD in heterozygous male Han:SPRD rats.

Epidermal growth factor ameliorates autosomal recessive polycystic kidney disease in mice.

C57BL/6J mice homozygous for the cpk gene exhibit an autosomal recessive (AR) form of polycystic kidney disease (PKD), similar to human ARPKD, with massive collecting duct cysts. These cysts are lined by epithelial with an immature phenotype. Since renal expression of epidermal growth factor (EGF) is also significantly decreased in affected mice, we hypothesized that renal EGF is necessary for normal developmental maturation of the collecting duct. To determine if the lack of EGF may be a decisive factor in the initiation and/or growth of collecting duct cysts, we administered exogenous EGF (1 microgram/g body wt subcutaneously) daily for Postnatal Days 3-9 (a critical period for collecting duct maturation) to C57BL/6J-cpk mice. EGF but not sham or albumin treatment retarded the development of PKD, reduced the degree of renal failure associated with the disease, and prolonged the survival of cystic mice. Sulfated glycoprotein-2 gene expression, a marker of immaturity in collecting duct cells, was reduced in cystic kidney by EGF treatment. This finding indicates that EGF treatment was associated with an increase in the maturation of the collecting duct epithelial cells. These findings support the view that decreased EGF may play a significant role in promoting the enlargement of collecting duct cysts in a hereditary model of ARPKD and that PKD involves defective and/or arrested collecting duct cell maturation.

Hyperoxia amplifies TNF-alpha production in LPS-stimulated human alveolar macrophages.

Human alveolar macrophages (AM) produce a number of inflammatory mediators including tumor necrosis factor (TNF). TNF-alpha has been implicated in several forms of lung injury including that associated with oxygen toxicity. To investigate whether oxygen could induce or augment the release of TNF from AM, we acquired AM from nonsmoking volunteers and determined TNF release after in vitro hyperoxia. Although TNF release was not induced by oxygen exposure alone, if lipopolysaccharide (LPS) stimulation occurred simultaneously, there was significant augmentation by 60 and 95% oxygen over LPS-stimulated AM exposed to 21% oxygen. This increase was paralleled by a significant increase of interleukin (IL)-1 beta. Dimethylthiourea (DMTU), a hydroxyl radical scavenger, inhibited this release. The increase in TNF extracellular concentrations induced by hyperoxia was not associated with significant increases in intracellular concentration or detectable mRNA over LPS-stimulated AM exposed to 21% oxygen. We hypothesize that hyperoxia exposure may alter the LPS-stimulated AM cytoplasmic milieu, thus further enhancing TNF-alpha production by a post-transcriptional mechanism.

Temporal alterations in regional gene expression after nephrotoxic renal injury.

To examine at a molecular level the repair process during recovery from acute renal failure, we determined, after nephrotoxic acute renal injury, levels for several RNAs associated with differentiated functions in the kidney. To delineate changes in different regions, we determined RNA levels separately in cortex, outer medulla, and inner medulla of adult rat kidney. Several RNAs were regionally distributed in control kidneys, including epidermal growth factor (EGF, highest in cortex and outer medulla), aldose reductase (highest in inner medulla), and prostaglandin synthase (highest in inner medulla). Futhermore, RNA for the heat shock protein Hsp70 was present at high levels in the inner medulla of controls. A single intraperitoneal dose of folic acid caused reversible, nonoliguric acute renal failure with impairment of glomerular filtration, tubular sodium reabsorption, and urinary concentration. Fractional excretion of sodium returned to normal by day 3, while serum creatinine, serum urea nitrogen, and urinary osmolality remained abnormal until day 7. During acute renal failure there was a marked, reversible decrease in the regional mRNA levels for EGF, aldose reductase, prostaglandin synthase, and Hsp70. Aldose reductase, prostaglandin synthase, and Hsp70 RNA levels returned to control levels by 7 to 10 days, while EGF remained depressed for a more prolonged period. High levels of aldose reductase, prostaglandin synthase, and Hsp70 RNAs in the inner medulla and their loss/recovery during acute renal failure with a time course similar to alterations in urinary osmolality were consistent with regulation in response to changes in inner medullary osmolality, as has been demonstrated for aldose reductase in normal animals. (ABSTRACT TRUNCATED AT 250 WORDS)

Methylprednisolone retards the progression of inherited polycystic kidney disease in rodents.

Polycystic kidney disease in adult laboratory animals and humans is associated with enlarged kidneys and a progressive decline of renal function, resulting in death from uremia. Interstitial inflammation and fibrosis typically are observed in association with the development of renal insufficiency. To determine whether amelioration of interstitial inflammation and fibrosis may diminish cyst expansion/kidney enlargement and stabilize renal function, we administered methylprednisolone, an anti-inflammatory drug with antifibrogenic effects, to mice and rats with hereditary polycystic kidney disease. The experiment was repeated once for each species. Mice were studied both in America and in Japan. Weanling male and female mice (DBA/FG pcy/pcy [cystic] and +/+ [normal], n = 87 and 20, respectively) and rats (Han:SPRD Cy/+ and +/+, n = 70 and 33, respectively) were administered methylprednisolone (1 to 2 mg/kg/d) in the drinking water for 100 days (mice) or 42 days (rats). Control animals drank distilled water. In normal DBA +/+ mice, methylprednisolone had no effect on serum urea nitrogen (SUN) levels, kidney weight, or kidney/body weight. Untreated male and female mice developed cystic kidneys and azotemia to an equal extent. Methylprednisolone administered in America to mice with renal cystic disease decreased kidney weight, kidney/body weight, SUN levels, volume density of cysts, and severity of interstitial fibrosis. In Japan, methylprednisolone decreased kidney weight and SUN levels of animals with cystic disease, but the effect on kidney/body weight did not reach statistical significance. In contrast to mice, male rats developed more severe renal cystic changes and were more azotemic than female rats. Methylprednisolone administered to male rats with cystic disease decreased SUN levels, kidney weight, kidney/body weight, volume density of cysts, and severity of interstitial fibrosis. Methylprednisolone had no effect on kidney/body weight or SUN levels in female rats with renal cystic disease. In normal Han:SPRD (+/+) rats of both sexes, kidney and body weight were decreased by methylprednisolone, but kidney/body weight and SUN levels were unchanged. On the basis of this study, we conclude that methylprednisolone decreased the extent of renal enlargement, reduced renal interstitial fibrosis, and preserved kidney function in mice and rats with relatively severe forms of inherited polycystic kidney disease.

Autosomal-dominant polycystic kidney disease in the rat.

Kaspareit-Rittinghausen described a rodent model of inherited polycystic kidney disease (PKD), the Han:SPRD rat [1, 2], in which heterozygotes develop renal cysts and renal failure (in males) over several months, whereas homozygous animals develop rapidly progressive renal enlargement that leads to death in a few weeks. In this study, we examined selected elements of the pathogenesis of this disease in heterozygotes and homozygotes from birth to advanced disease. Heterozygous male rats developed slowly progressive renal cystic disease with interstitial fibrosis and azotemia seen by six months of age. Female heterozygotes developed slowly progressive renal cystic disease, but did not develop interstitial fibrosis or azotemia. Epithelial cells lining cyst cavities showed various degrees of morphologic immaturity. Cyst walls also developed basement membrane thickening, especially in areas of cellular immaturity, suggesting an interrelationship between this basement membrane thickening and cellular dedifferentiation. Thickened basement membranes were associated with increased immunoreactivity for type IV collagen, laminin, and fibronectin. Homozygous rats developed massive renal enlargement, marked azotemia, and died near three weeks of age. Renal c-myc proto-oncogene expression was elevated in homozygous cystic infants and in adult heterozygotes. In situ hybridization showed high levels of c-myc mRNA in cyst epithelia, suggesting abnormal regulation of cellular proliferation in the cells lining cysts, as seen in other models of PKD. The Han:SPRD rat is the only well-documented animal model of inherited PKD with an autosomal-dominant inheritance pattern and appears to have several features which resemble human ADPKD.

Tumor necrosis factor-alpha mRNA and protein in rat uterine and placental cells.

The pregnant uterus contains TNF-alpha, a potent cytokine with pleotrophic effects. The uterus also contains numerous macrophages, which are well described sources of TNF-alpha. In order to determine if uterine TNF-alpha originated with these macrophages, patterns of macrophage tissue distribution and population densities were first established in rat uterine tissues from early, mid, and late stages of gestation by immunohistology. The potential of these and other uterine and placental cells to synthesize TNF-alpha was then tested by in situ hybridization with the use of biotinylated antisense and sense RNA probes. Although TNF-alpha mRNA was present during all stages of pregnancy, hybridization signals were highest in gestation day 15 tissues. The predominant TNF-alpha mRNA-containing cells were uterine epithelium, decidual cells, and placental trophoblast cells; these cells also contained immunoreactive TNF. Transcription of the TNF gene in the uterus and placenta was also documented by Northern blotting experiments, which showed that the transcript sizes for uterine, placental, and macrophage TNF mRNA were similar. Although stromal cells that were located in macrophage-rich uterine compartments (myometrium, metrial gland) contained TNF-alpha mRNA, the cells did not contain high levels of immunoreactive TNF-alpha. Thus, cells other than macrophages are likely to be the major contributors of TNF-alpha during uncomplicated pregnancy in the rat.