Development of the metanephric kidney. Protein and nucleic acid synthesis

The bigger the better: determining nephron size in kidney

The main functions of the kidney are to excrete metabolic waste products and actively reabsorb essential molecules such as amino acids, ions, glucose and water. In humans, a wide range of genetic disorders exist characterized by wasting of metabolically important compounds. At the cellular level, more than 20 highly specialized renal epithelial cell types located in different segments of the nephron contribute to the reabsorption process. In particular, proximal tubular cells play a crucial role and are uniquely adapted to maximize reabsorption efficiency. They accommodate high numbers of transporters and channels by increasing the apical surface area in contact with the primary filtrate by forming a brush border as well as undergoing hypertrophy and hyperplasia. This adaptation is evolutionarily conserved and is detected in the primitive pronephric kidney of fish and amphibians as well as the metanephric kidney of higher vertebrates. Surprisingly, signaling pathways regulating these three processes have remained largely unknown. Here we summarize recent studies that highlight the early phases of kidney development as a critical juncture in establishing proximal tubule size.

Compensatory cell proliferation in the kidney after unilateral nephrectomy in mice

The compensatory cell proliferation in kidney cortex after unilateral nephrectomy in hair-less mice was evaluated by registration of the mitotic rate, thymidine incorporation into DNA, and labelling indices (LI) over a period of 120 h after surgery. Maximal specific activity of DNA and LI were found at 30-36 h postoperatively and preceded the maximal mitotic rate by 6-12 h. The influence of age, sex and diurnal variations was examined.

Incorporation of 32P into renal phospholipids of mice during postnatal growth

During the first 40 days of life the rate of incorporation of 32P into total phospholipids and into phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine, sphingomyelin, diphosphatidylglycerol, phosphatidic acid and phosphatidylinositol of mouse kidney was by some 25-35% higher than in older animals. Results suggest a different involvement of cellular membranes during of normal and compensatory renal growth.

Distribution and protein synthetic activities of neuronal free and membrane-bound ribosomes during postnatal development of rat cerebral cortex

The distribution and amino acid incorporative activities of free and membrane-bound ribosomes in neuronal perikarya of rat cerebral cortex at successive stages of postnatal development were investigated. The relative proportion of neuronal membrane-bound ribosomes increased significantly between 6 and 18 days of age, reaching 50% of the total ribosomal population around day 18. In contrast to the neuronal fraction, the membrane-bound ribosomes in unfractionated cerebral cortex decreased from 50% at birth to 35% in 18-day-old pups. When tested in a cell-free amino acid incorporation system the activities of both free and membrane-bound ribosomes increased up to day 10 post partum. However, whereas the activity of free ribosomes reached a constant level at this age, that of the membrane-bound fraction continued to rise until 18th day after birth. Crossover experiments employing homologous or heterologous cell sap fractions showed that the preparation from the 18-day-old animals was more efficient in supporting protein synthesis in vitro, if compared with similar preparation from the neonatal animals. This was attributed to an enhanced aminoacylation of transfer RNA in neuronal cell sap of older compared with younger rats. The observed developmental alterations in the distribution and activities of free and membrane-bound ribosomes are discussed in relation to changes that occur in morphology and function of brain during the early postnatal period.

Maturation of growth hormone stimulation of kidney ornithine decarboxylase in the rat

The effect of ovine growth hormone (GH) on kidney ornithine decarboxylase (ODC) was studied in newborn, preweanling and young adult rats. Basal kidney ODC activity was very low from 4 to 22 days after birth but rose 20-fold by day 25; it remained elevated through day 45. GH failed to stimulate ODC in the first two weeks after birth. GH did however stimulate ODC markedly from 20 through 45 days. Kidney ODC was stimulated in the neonate by vasopressin and by isoproterenol, but not by angiotensin II. Liver ODC remained relatively low and stable during development, and was responsive to GH at all ages studied. We conclude that a) the pattern of development of basal kidney ODC appears to be unique to this tissue and may be related to the postnatal maturation of renal morphology and/or function, b) neonatal kidney ODC is unresponsive to certain hormones but is not completely refractory to stimulation. These findings may have implications for the role of hormones in the maturation of the kidney and in the regulation of early renal function.

Renal growth in maternal-fetal axis: clinical and laboratory studies

A hormone (renotropin) is said to play an important role in compensatory renal growth. The role of renotropin in obligatory growth (normal developmental growth) is unknown. It was observed that contralateral renal size in children with unilateral multicystic kidney was found to be normal at birth but became hypertrophied later. The kidneys of twenty-one-day-old fetal rats were significantly smaller than sham controls in animals whose mothers had uninephrectomies at day 8 (26.5 +/- 1.1 mg. versus 18.5 +/- 1.1 mg.). The mothers' kidneys hypertrophied compared with sham controls (1,065 +/- 23 mg. versus 1,347 +/- 78 mg.). It was concluded that renotropin passes the placenta and modifies so-called obligatory renal growth.

Short-lived methylated messenger RNA in mouse kidney

In experiments originally designed to examine selective turnover of methylated "caps" in renal mRNA, we observed that [3H]methyl label decayed from mRNA containing poly(A) with a half-life of 1-2 hr. (Caps are blocked, methylated mRNA sequences of the general structure m7GpppNm p(1 or 2)Np.). To distinguish between metabolism of short-lived mRNA and discriminate turnover of "caps", we compared residual [3H]methyl label in 5' and 3'mRNA fragments prepared from mRNA isolated during the decay period. Hydrolysis of mRNA at 0 degrees with dilute KOH before oligo(dT)-cellulose selection produced 5' mRNA fragments enriched with an alkali-resistant oligonucleotide with a -5 charge; the 3' mRNA fraction was correspondingly reduced in oligonucleotide content. Since methyl label disappeared at the same rate from both fractions, we conclude that mouse kidney contains short-lived mRNA and that the "caps" of these labile mRNAs turn over with the rest of the mRNA molecule.

Accumulation and decay of messenger ribonucleic acid in mouse kidney

The stability of polyadenylated messenger ribonucleic acid(mRNA) from cytoplasmic structures sedimenting faster than 40S was analyzed in normal mouse kidney. Incorporation of radioactivity into poly(A)-containing and poly(A)-lacking cytoplasmic RNAs separated by oligo(dT)-cellulose chromatography was determined after sedimentation of RNA IN SODIUM DODECYL SULFATE CONTAINING SUCROSE DENSITY GRADIENTS. Radioactivity accumulated in poly(A)-containing RNA during the first 6 h and then decayed exponentially. Beginning 8-12h after administering label, two components were evident in the decay curve of poly(A)-containing RNA; the short-lived component (approximately 57% of newly synthesized molecules) had an apparent half-life of 6h, and the second class (approximately 43% of new mRNA) was more stable, decaying with a 24-h half-life. These studies provide the basis for examining the regulation of mRNA stability during compensatory renal hypertrophy.

Physical aspects and cytoplasmic distribution of messenger RNA in mouse kidney

As a prerequisite to examining mRNA metabolism in compensatory renal hypertrophy, polyadenylated RNA has been purified from normal mouse kidney polysomal RNA by selection on oligo(dT)-cellulose. Poly(A)-containing RNA dissociated from polysomes by treatment with 10 mM EDTA and sedimented heterogeneously in dodecyl sulfate-containing sucrose density gradients with a mean sedimentation coefficient of 20 S. Poly(A) derived from this RNA migrated at the rate of 6-7 S RNA in dodecyl sulfate-containing 10% polyacrylamide gels. Coelectrophoresis of poly(A) labeled for 90 min with poly(A) labeled for 24 h indicated the long-term labeled poly(A) migrated faster than pulse-labeled material. Twenty percent of the cytoplasmic poly(A)-containing mRNA was not associated with the polysomes, but sedimented in the 40-80 S region (post-polysomal). Messenger RNA from the post-polysomal region had sedimentation properties similar to those of mRNA prepared from polysomes indicating post-polysomal mRNA was not degraded polysomal mRNA. Preliminary labeling experiments indicated a rapid equilibration of radioactivity between the polysomal and post-polysomal mRNA populations, suggesting the post-polysomal mRNA may consist of mRNA in transit to the polysomes.

Changes in free and membrane-bound ribosomes during the development of chick liver. A new cell-fractionation approach

A major difficulty in studying quantitative changes in free and membrane-bound ribosomes in a tissue under different physiological conditions is that membrane-bound ribosomes are not usually recovered quantitatively in a conventional microsomal fraction. This problem was resolved for developing chick liver by determining the conditions for the isolation of a microsomal fraction containing the highest practicable yield of rough vesicles, and then separating it into free-ribosome- and rough-vesicle-containing fractions. With the aid of a marker enzyme for the microsomal membranes and the RNA content of the recovered membrane-bound ribosomes, it was possible to correct for the recovery of rough vesicles and hence to determine the concentration of membrane-bound ribosomes in the homogenate. Despite the fact that morphological studies have suggested that most of the cellular ribosomes are not bound to membrane in chick liver cells at the earliest developmental age studied (6 days of egg incubation), 49% of the total ribosomes were found to be membrane-bound by using the new fractionation technique. This fraction increased (to 66%) during development. The discrepancy between the cell-fractionation and morphological approaches could not be attributed to artifacts of the separation method but rather to difficulties inherent in the morphological approach.

The effect of malnutrition on the pattern of growth in the rat kidney and the renal response to acidosis

1. The kidneys of normal rats were analysed for water, fat, protein, RNA and DNA, at 10, 21 and 36 d after birth. The effects on growth caused by two types of malnutrition were investigated.

2. An increase in the RNA:DNA ratio was demonstrated between 10 and 36 d, contrary to previous evidence that this ratio is fixed at birth.

3. Energy deficiency during the first 21 d of life resulted mainly in fewer kidney cells, whereas protein-energy deficiency between 21 and 36 d resulted mainly in a smaller cellular content of RNA and protein.

4. In response to metabolic acidosis, both groups of malnourished rats increased urinary excretion of ammonia and there was enhanced gluconeogenesis in vitro; the basal rate of gluconeogenesis was lower in the protein-energy-deficient rats than in the controls.

5. Protein-energy-deficient rats did not exhibit the renal hypertrophy shown by the control rats in response to acidosis.

Protein and nucleic acid metabolism in organs from mice selected for larger and smaller body size

Studies of the growth and composition of Q-strain mice selected over 20 generations for high and low body weight at 6 weeks of age, and their unselected controls, were made on livers and kidneys of males from the five selection replicates A, B, C, D and F. Differences in growth rate between Large and Small QD mice were confirmed from 2 to 9 weeks of age, but were greatest in the third, fourth, sixth and seventh weeks. Total amounts of dry matter, protein, free amino acids, bulk RNA and ribosomes were increased or decreased from control values in proportion to organ weight. A less-perfect relationship between DNA content and organ weight suggested that some small changes in average cell mass had accompanied the main change in cell number in organs from the selected lines. Absorbance profiles of polyribosomes from both organs were identical in selected and control mice: selection had not operated on the proportion of single (currently inactive) ribosomes. Attempts to relate the observed differences in growth rate in QD mice to differences in the rate of protein synthesis produced an unexpected result: incorporation of radioactively labelled amino acids was consistently higher in the organs of the Small mice. Measurements of rates of protein turnover, and calculated rates of protein degradation, suggested that protein might also be degraded more rapidly in the small mice.

Compensatory renal growth after unilateral nephrectomy in the new-born rat

1. The right kidney in a series of control rats aged between 5 days and 115 days was weighed. The kidney weight/body weight ratio was greater in young than in older rats, but decreased linearly with increasing age.2. After unilateral nephrectomy of rats 5 days old, the remaining kidney underwent compensatory growth. The rate and extent of this growth were greater than in adult rats.3. The concentrations of RNA and DNA in the renal cortex and medulla of rats 5 days old were higher than in adult animals. The concentrations of the two nucleic acids fell with age, and reached adult levels after approximately 6 weeks.4. After unilateral nephrectomy of rats 5 days old, the concentrations of RNA and DNA in the medulla were not significantly different from those in control animals. In the cortex, however, there was a delayed increase in the RNA/DNA ratio, which reached a level some 12% higher than that in control rats. This increase was smaller than that observed in unilaterally nephrectomized adult rats.5. The cortical Q(O2) of the remaining kidney of unilaterally nephrectomized new-born rats was elevated by some 20% within 1 day of unilateral nephrectomy. Cortical Q(O2)'s remained higher than those of control animals for 3-4 weeks.6. Since after unilateral nephrectomy, the increase in renal mass in new-borns was greater than that in adults, whereas the degree of cortical cellular hypertrophy (as estimated by the RNA/DNA ratio) was smaller than in adults, it is likely that in new-born animals a significant contribution to compensatory growth comes from cellular hyperplasia.

Membrane-bound ribosomes in kidney: methods of estimation and effect of compensatory renal growth

Membrane-bound ribosomes are thought to secrete protein for export and free ribosomes to secrete protein for intracellular use. The proportion of the total ribosomes that is bound to membranes in normal mouse kidneys has been estimated by three different methods, and the results have been compared with those obtained by a fourth method used by us previously. The most valid estimates appear to be those obtained (a) by comparison of radioactivity in peaks representing free and membrane-bound ribosomes on linear sucrose gradients after labeling for 24 hr with (14)C-orotic acid, and (b) by measurements of optical density in free and bound ribosomes that had been separated by centrifugation on discontinuous gradients of 0.5 M/2.0 M sucrose. Analyses by these methods show that about 20-25% of the ribosomes in a postnuclear supernatant prepared from mouse kidneys, but only 10-15% of the ribosomes in a post-mitochondrial supernatant, are membrane-bound. About 75% of the bound ribosomes sediment as polysomes of many different sizes. The proportion of membrane-bound ribosomes and their aggregation into polysomes were unchanged in kidneys undergoing compensatory hypertrophy after removal of the opposite kidney. These experiments show that, unlike liver, kidney has a predominance of free ribosomes compared to bound ribosomes; those ribosomes that are membrane-bound do not become free during compensatory renal growth.