Interstitial water and solute recovery by inner medullary vasa recta.

A recent model of volume and solute microvascular exchange in the renal medulla was extended by simulating the deposition of NaCl, urea, and water into the medullary interstitium from the loops of Henle and collecting ducts with generation rates that undergo spatial variation within the inner medullary interstitium. To build an exponential osmolality gradient in the inner medulla, as suggested by Koepsell et al. (H. Koepsell, W. E. A. P. Nicholson, W. Kriz, and H. J. Höhling. Pflügers Arch. 350: 167-184, 1974), the ratio of the interstitial area-weighted generation rate of small solutes to that of water must increase along the corticomedullary axis. We satisfied this condition either by holding the area-weighted generation rate of water constant while increasing that of NaCl and urea or by reducing the input rate of water with medullary depth. The latter case, in particular, yielded higher solute concentrations at the papillary tip. Assuming that the fraction of the filtered load recovered by inner medullary vasa recta for water, NaCl, and urea is 1%, 1%, and 40%, respectively, papillary tip osmolality is 1,470 mosmol/kgH(2)O when urea generation and NaCl generation per unit volume of interstitium increase exponentially and linearly, respectively. The inner medullary osmolar gradient also increases further when 1) medullary blood flow is reduced, 2) hydraulic conductivity of descending vasa recta (DVR) is lowered, and 3) vasa recta permeability to NaCl and urea is maximized. The coupling between water and small solute transport, resulting from aquaporin-1-mediated transcellular flux in DVR, also enhances tip osmolality.

Dietary compounds that induce cancer preventive phase 2 enzymes activate apoptosis at comparable doses in HT29 colon carcinoma cells.

Dietary agents that induce glutathione S-transferases and related detoxification systems (Phase 2 enzyme inducers) are thought to prevent cancer by enhancing elimination of chemical carcinogens. The present study shows that compounds of this group (benzyl isothiocyanate, allyl sulfide, dimethyl fumarate, butylated hydroxyanisole) activated apoptosis in human colon carcinoma (HT29) cells in culture over the same concentration ranges that elicited increases in enzyme activity (5-25, 25-100, 10-100, 15-60 micromol/L, respectively). Pretreatment of cells with sodium butyrate, an agent that induces HT29 cell differentiation, resulted in parallel increases in Phase 2 enzyme activities and induction of apoptosis in response to the inducers. Cell death characteristics included apoptotic morphological changes, appearance of cells at sub-G1 phase on flow cytometry, caspase activation, DNA fragmentation and TUNEL-positive staining. The results suggest that dietary Phase 2 inducers may protect against cancer by a mechanism distinct from and in addition to that associated with enhanced elimination of carcinogens. If this occurs in vivo, diets high in such compounds could eliminate precancerous cells by apoptosis at time points well after initial exposure to chemical mutagens and carcinogens.

Temporal effects of the detoxification enzyme inducer, benzyl isothiocyanate: activation of c-Jun N-terminal kinase prior to the transcription factors AP-1 and NFkappaB.

Benzyl isothiocyanate (BIT), a microconstituent found in cruciferous vegetables, is known to be a potent inducer of the detoxification enzyme, NAD(P)H: quinone reductase (QR). QR catalyzes a two-electron transfer to a wide variety of redox-cycling species, including quinones, transforming them into dihydrodiols, thereby preventing the mutation of DNA and reducing cancer risk. The upstream signaling mechanisms that lead to the induction of QR remain unclear. The 5' promoter region of the human QR gene contains the cis-acting AP-1 and NFkappaB transcription factor binding sites. When HT29 human colon cells were exposed to 25microM benzyl isothiocyanate, AP-1 binding increased, beginning at 3 hours and increasing until 16 hours. NFkappaB binding also increased, reaching a maximum at around 6 hours. We also found that c-Jun N-terminal kinase (JNK), which phosphorylates c-Jun, a component of AP-1, was activated 9-fold over controls, beginning at 60 minutes. The temporal sequence of these events supports the idea that JNK is involved in the induction of QR and that this is an initial event preceding an increase in transcription factor binding and subsequent QR activity.

Effects of sulindac, sulindac metabolites, and aspirin on the activity of detoxification enzymes in HT-29 human colon adenocarcinoma cells.

Non-steroidal anti-inflammatory drugs (NSAIDs) have been found to reduce cancer rates in various segments of the gastro-intestinal tract in both animals and humans. In this study we examined the effect of sulindac, sulindac sulfide, sulindac sulfone and aspirin on QR and GST activity. We found that sulindac itself increased QR activity as much as 2-fold over controls but had no effect on GST activity. Sulindac sulfone, a metabolite of sulindac which lacks the ability to inhibit prostaglandin (PG) synthesis, increased QR and GST to 1.5-fold over controls in both cases. Aspirin increased QR and GST to 1.5-fold and 3.5-fold over controls respectively. These data indicate that NSAIDs increase phase II enzyme detoxification enzyme activity. Consequently, this effect may contribute to the protective effect of NSAIDs against colon cancer and may be an anticarcinogenic effect of these drugs that is distinct from their ability to inhibit PG synthesis.

Apoptosis: a modulator of cellular homeostasis and disease states.

In normal epithelial tissue, a homeostatic balance is maintained between cell replication and apoptosis. Disruption of this balance has serious pathological consequences in disease states, such as Sjögren's syndrome, salivary gland degeneration, and cancers. Apoptosis may be modulated by cytokine endogenous factors and exogenous factors. A vast array of environmental compounds, such as differentiating agents and microconstituents found in the diet, initiate apoptosis through a redox signal mechanism. In addition to increasing apoptosis, these redox signals and transient or permanent changes in cellular redox status elevate detoxification enzymes known to protect against many disease states. Clearly a further understanding of the regulation of apoptosis and protective enzyme elevation by exogenous redox signals will lead to the development of future therapeutic strategies against disease.