Proteinase-activated receptor-2 (PAR2) on blood pressure and electrolyte handling in the late pregnant rat

Adaptive Changes in single-nephron GFR, Tubular Morphology, and Transport in a Pregnant Rat Nephron: Modeling and Analysis

Normal pregnancy is characterized by massive increases in plasma volume and electrolyte retention. Given that the kidneys regulate homeostasis of electrolytes and volume, the organ undergoes major adaptations in morphology, hemodynamics, and transport to achieve the volume and electrolyte retention required in pregnancy. These adaptations are complex, sometimes counterintuitive, and not fully understood. In addition, the demands of the developing fetus and placenta change throughout the pregnancy. For example, during late pregnancy, K⁺ retention and thus enhanced renal K⁺ reabsorption is required despite many kaliuretic factors. The goal of this study is to unravel how known adaptive changes along the nephrons contribute to the ability of the kidney to meet volume and electrolyte requirements in mid- and late pregnancy. We developed computational models of solute and water transport in the superficial nephron of the kidney of a rat in mid- and late pregnancy. The mid-pregnant and late-pregnant rat superficial nephron models predict that morphological adaptations and increased activity of the sodium hydrogen exchanger 3 (NHE3) and epithelial sodium channel (ENaC) are essential for enhanced Na⁺ reabsorption observed during pregnancy. Model simulations showed that for sufficient K⁺ reabsorption, increased H ⁺-K ⁺-ATPase activity and decreased K⁺ secretion along the distal segments is required in both mid- and late-pregnancy. Furthermore, certain known sex differences in renal transporter pattern (e.g., the higher NHE3 protein abundance but lower activity in the proximal tubules of virgin female rats compared to male) may serve to better prepare the female for the increased transport demand in pregnancy.

Time course of renal sodium transport in the pregnant rat

Progressive sodium retention and cumulative plasma volume expansion occur to support the developing fetus during pregnancy. Sodium retention is regulated by individual tubular transporters and channels. An increase or decrease in any single transporter could cause a change in sodium balance. Understanding the time-course for changes in each sodium transporter during pregnancy will enable us to understand progressive sodium retention seen in pregnancy. Here, we examined the activity of the major apical sodium transporters found in the nephron using natriuretic response tests in virgin, early pregnant, mid-pregnant, and late pregnant rats. We also measured renal and serum aldosterone levels. We found that furosemide sensitive sodium transport (NKCC2) is only increased during late pregnancy, thiazide sensitive sodium transport (NDCBE/pendrin) is increased in all stages of pregnancy, and that benzamil sensitive sodium transport (ENaC) is increased beginning in mid-pregnancy. We also found that serum aldosterone levels progressively increased throughout gestation and kidney tissue aldosterone levels increased only during late pregnancy. Here we have shown progressive turning on of specific sodium transport mechanisms to help support progressive sodium retention through the course of gestation. These mechanisms contribute to the renal sodium retention and plasma volume expansion required for an optimal pregnancy.