Overview of Kidney Structure and Function

Mammals possess two kidneys located near the lower ribs. Each kidney receives its blood supply from a single renal artery that originates in the aorta. Renal blood drains into a single renal vein that connects with the inferior vena cava. Urine normally empties from a single ureter and then into the bladder. On a gross, whole-organ level, the kidneys are subdivided into three regions: cortex, outer medulla, and inner medulla. The outer medulla is further divided into the outer stripe and inner stripe. The inner medulla is further divided into the base and tip; the latter is also called the papilla. Whereas small mammals, such as the rat, mouse, and rabbit, have a single papilla in each kidney, larger mammals, including humans, have multiple papilla per kidney. In either unipapillate or multipapillate mammals, urine exits from the tip of the papilla into the renal pelvis.

The functional unit of the kidneys is the nephron (Figure 7.1), which is a series of epithelial cells of varying types (see later) that form a tube of one-layer-thick cells enclosing a luminal compartment. Mammalian kidneys contain millions of nephrons, each of which leads into a common collecting duct. Nephrons are categorized as either superficial, midcortical, or juxtamedullary, depending on the location of their glomeruli. The renal cortex contains glomeruli, proximal convoluted and some proximal straight tubules, macula densa, cortical thick ascending limbs, distal convoluted tubules, connecting tubules, initial collecting ducts, interlobular arteries, and afferent and efferent capillary networks. The outer stripe of the outer medulla is located just below or inside the cortex and contains proximal straight tubules, medullary thick ascending limbs (mTAL), and outer medullary collecting ducts. The inner stripe of the outer medulla is located below or inside the outer stripe and contains thin descending limbs, thick ascending limbs, and outer medullary collecting ducts. The inner medulla contains thin descending limbs, thin ascending limbs, and inner medullary collecting ducts. The renal vasculature surrounds the tubule and parallels the nephron.

The primary function of the kidneys is to maintain the internal environment of the body. They do this by regulating total body salt (e.g., sodium, potassium, and chloride ions), water, and acid–base balance (e.g., proton, bicarbonate, and ammonia transport and metabolism), reabsorbing nutrients (e.g., glucose, amino acids), and excreting waste products (e.g., urea, creatinine, uric acid, phosphates, sulfates). As shown in Table 7.1, the kidneys are extremely efficient at reabsorbing key electrolytes and water. The critical function of the kidneys in water conservation is exemplified by a consideration of how fluid input and output are balanced. Water input is determined largely (~88%) by ingestion via the gastrointestinal tract, with the remainder (~12%) coming from metabolism. In contrast, water output is determined primarily by the kidneys (~72%), with the remainder coming from the skin (~12%), lungs (~12%), and gastrointestinal tract (~4%).

Three general mechanisms are involved in accomplishing these key functions: glomerular filtration, tubular reabsorption, and tubular secretion. Glomerular filtration is defined as the movement of water and solutes across the glomerular capillary wall to form an ultrafiltrate of plasma. The rate at which this process occurs is called the glomerular filtration rate (GFR). A typical GFR in a normal, young, healthy adult human is 125 ml/min or 180 l/24 h. As discussed in Section 7.3, this GFR value represents a high degree of reserve function such that individuals are not considered to have compromised renal function until GFR declines to below 60 ml/min. The movement of electrolytes or metabolites from the tubular fluid back into the plasma is called tubular reabsorption, resulting in retention in the body, whereas that from plasma into the tubular fluid is called tubular secretion, ultimately resulting in excretion into the urine.

The kidneys also possess specialized endocrine functions, such as synthesis of 1,25-dihydroxy vitamin D₃ and the protein erythropoietin. The latter is critical for synthesis of red blood cells. In fact, deficiency in the renal synthesis of erythropoietin is invariably associated with anemia. Additionally, although the liver is considered the primary organ of drug metabolism, the kidneys possess significant drug metabolism capabilities. As described in Section 7.5, some classes of chemicals are specifically bioactivated by renal enzymes to reactive metabolites that lead to their nephrotoxicity.

Nephron Structure and Heterogeneity

The mammalian kidney is a complex organ whose basic structural unit, the nephron, is composed of many cell populations, each exhibiting diverse morphological, biochemical, and functional properties (Table 7.2). Differences exist among cell types in morphology, membrane structure, energetics, and the composition of transporters and drug metabolism enzymes. As a consequence of this functional heterogeneity, exposure of the kidneys, either in vivo or in vitro, to various nephrotoxicants or to pathological conditions such as ischemia or hypoxia, produces distinct patterns of cellular injury. Thus, certain cell populations are either specific targets of or are particularly susceptible to one form of injury or another. In some cases, the specificity is due to the selective presence in a given cell population of a membrane transport system or a bioactivation or detoxication enzyme. In other cases, however, susceptibility is explained by the basic biochemical function of the cell.

For example, mTAL cells are particularly susceptible to injury from hypoxia or ischemia–reperfusion because of their relatively poor oxygenation and primary reliance on glycolysis for generation of ATP. The proximal tubules are the most common targets for chemically induced injury because they are the first nephron cell type with which filtered chemicals come in contact, they possess a large array of membrane transporters that mediate uptake and intracellular accumulation of chemicals (see later), and they contain relatively high activities of drug metabolism enzymes that can metabolize chemicals to reactive and toxic species.

Countercurrent Flow and Urinary Concentration Mechanism

The ability to generate the high osmolarity of the medullary interstitium is dependent on two principal factors: (1) active chloride or salt reabsorption in the ascending limb, and (2) the anatomical relationship between the descending and ascending limbs of the loop of Henle; the fact that both limbs are close together and that flow in each limb is in the opposite direction is a critical feature. This results in what is called countercurrent flow. Additionally, as noted earlier, there is a parallel vascular structure to the nephron structure that forms a countercurrent exchange of blood. This arrangement prevents solutes from coming out in the descending limb and being washed away but also contributes to the ability of the renal epithelium to concentrate certain chemicals to levels several-fold higher than those in either the plasma or glomerular filtrate.

Membrane Transport Processes

A critical feature of all transporting epithelia is the presence of an array of carrier proteins selectively localized on either the brush-border plasma membrane (BBM) or basolateral plasma membrane (BLM) that mediates the uptake and/or efflux of ions and metabolites. Because of nephron heterogeneity, most of the transport of drugs and environmental chemicals occurs in the proximal tubules as these cells contain the highest activities of carrier proteins for organic anions (OA^–) and cations and intermediary metabolites.

Three modes of transport are relevant to a consideration of the role of carrier-mediated transport in chemically induced nephrotoxicity (Figure 7.2). In the pathway for chemical A, the chemical is taken up into the cell from the lumen by transport across the BBM and is then reabsorbed into plasma by efflux across the BLM. In contrast, in the pathway for chemical B, the chemical is taken up into the cell from the plasma by transport across the BLM and is then excreted into the lumen and ultimately the urine by efflux across the BBM. For the pathway for chemical C, however, high-affinity uptake from plasma occurs across the BLM. Poor transport across the BBM, however, leads to intracellular accumulation of chemical C, thereby promoting toxicity.

The high efficiency by which renal cells, particularly those of the proximal tubule, take up chemicals from the plasma is associated with the presence of coupled, active transport systems in the plasma membranes (Figure 7.3). This coupling is achieved on the BLM by the action of the primary active transporter the (Na⁺ + K⁺)-stimulated ATPase, which catalyzes efflux of two Na⁺ ions in exchange for uptake of three K⁺ ions and is energized by the hydrolysis of ATP. This primary active transporter, so called because it uses high-energy ATP, generates a large, inwardly directed gradient of Na⁺ ions across the BLM that can be used to facilitate uptake of anions. Such a facilitated, Na⁺-coupled uptake occurs for 2-oxoglutarate (2-OG^2–), which is catalyzed by the sodium dicarboxylate 3 carrier (NaC3; SLC13A3). This is considered a secondary active transporter as it uses the Na⁺ gradient generated by a primary active transporter to facilitate uptake of other substrates. The NaC3 carrier, in turn, generates an inwardly directed gradient of 2-OG^2–, which is used in a tertiary active transport process to catalyze uptake of OA^–, which can be mediated by, among others, the OA^– transporters 1 and 3 (OAT1/3; SLC22A6/8).

The importance of these coupled processes is highlighted by the realization that a substantial number of drugs and nephrotoxicants are OA^– and are thus transported across the BLM by OAT1 and/or OAT3. These carriers, particularly OAT1, are inhibited by the classic OA^– transport inhibitor probenecid. For many nephrotoxicants that are OA^–, their toxicity can be modulated by probenecid, demonstrating the critical role of the BLM transport step. Coadministration of multiple drugs that are all transported by these anion carriers can lead to drug–drug interactions that limit the therapeutic efficacy of these drugs and may lead to nephrotoxicity as a side effect of exposure.

Summary of Physiological Factors Contributing to the Kidneys as a Target Organ for Toxic Chemicals

The foregoing discussion highlights the various aspects of renal physiology that contribute to susceptibility of the kidneys as a target organ for many toxic chemicals. These factors are summarized in Table 7.3. As described earlier, the physiological functions of the kidneys can enhance nephrotoxicity when the chemical being handled is a nephrotoxicant. Additionally, membrane transporters and drug metabolism enzymes that are similar to those found in the liver, which is the organ usually considered the major site of drug metabolism, also exist in the kidneys, particularly in the proximal tubules.

Acute Kidney Injury

There are four basic mechanisms by which chemicals can produce acute kidney injury:

1. Hypoperfusion or hypofiltration: This mechanism of acute renal injury involves reductions in renal blood flow due to either renal vasoconstriction or glomerular injury, and has been associated with acute exposures to drugs such as the fungicide amphotericin B, aminoglycoside antibiotics, cyclosporin, nonsteroidal anti-inflammatory agents (NSAIDs), and radiocontrast agents.
   
2. Acute tubular necrosis: This mechanism involves direct injury to tubular epithelial cells and includes the largest and most diverse array of chemical exposures. Examples of nephrotoxic chemicals that produce direct tubular injury include aminoglycoside antibiotics, the antifungal agent amphotericin B, the analgesic acetaminophen (APAP), β-lactam antibiotics, cisplatin (CDDP), halogenated hydrocarbons, radiocontrast agents, and heavy metals such as inorganic mercury (Hg) and cadmium (Cd).
   
3. Obstruction: Radiocontrast agents can produce tubular obstruction due to the formation of urinary protein casts. This is believed to be due to the hyperosmolar nature of these agents, producing 5- to 10-fold higher concentrations of the agents in the tubular lumen than in the plasma and hemodynamic effects (i.e., renal vasoconstriction).
   
4. Tubulointerstitial fibrosis: Certain nephrotoxicants, including β-lactam antibiotics, NSAIDs, sulfonamides, and tetracycline can cause interstitial fibrosis through immunological and inflammatory effects.

Measurement of GFR

One of the primary means of assessing renal function in the whole animal or in patients is to monitor GFR. GFR is defined as the volume of blood completely removed of a substance per unit time (ml/min); GFR = 125 ml/min in healthy, young humans. Two commonly used indicators of GFR are blood urea nitrogen (BUN) or serum creatinine (SCr) levels. Nitrogenous wastes derive from protein and amino acid degradation. Under normal conditions, amino acids are reabsorbed by the proximal tubules and breakdown products of proteins are efficiently excreted, with much of the N-containing waste products being excreted as ammonia or ammonium salts. Under conditions of impaired renal function, however, the efficiency of nitrogenous waste excretion is diminished, leading to increased retention of N-containing compounds. Creatinine (M_r = 113) is released from skeletal muscle due to the nonenzymatic hydrolysis of creatine. The rate of creatinine production is generally constant and proportional to muscle mass. In a normal, healthy state, glomerular filtration is nearly complete so that very low levels of creatinine remain in the blood. Using creatinine clearance (C-Cr) as an index of renal function, GFR is calculated by the following equation:

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