Adaptation to a diet low in protein: effect of complex carbohydrate upon urea kinetics in normal man

1992 ◽  
Vol 82 (2) ◽  
pp. 191-198 ◽  
Author(s):  
M. Langran ◽  
B. J. Moran ◽  
J. L. Murphy ◽  
A. A. Jackson
Keyword(s):  
The Body ◽  
Protein Diet ◽  
Low Protein Diet ◽  
Urea Nitrogen ◽  
Low Protein ◽  
Urea Production ◽  
Urea Kinetics ◽  
Normal Man ◽  
Faecal Weight ◽  
Formula Diets

1. Urea kinetics were measured by using prime/intermittent oral doses of [15N15N]urea in five healthy men taking formula diets adequate in energy and containing either 70 or 35 g of protein/day. In some studies the low-protein diet was supplemented with non-starch polysaccharides in the form of ispaghula husk or ripe bananas. 2. On the 70 g of protein/day diet urea production was 132% of intake. Only 54% of the urea produced was excreted in the urine with 46% being salvaged in the colon; 90% of the salvaged nitrogen was retained in the metabolic nitrogen pool. 3. On the 35 g of protein/day diet the small decrease in urea production rate compared with that on the 70 g of protein/day diet was not significant, but only 36% of the urea produced was excreted in urine, with the majority, 64%, being salvaged. 4. The extent of urea-nitrogen salvaging on the 35 g of protein/day diet was similar in magnitude to the decrease in nitrogen intake, with the effect that the sum of intake and salvaged nitrogen did not differ between the 35 and the 70 g of protein/day diets. This implies that quantitative control is exerted over the rate at which urea nitrogen is salvaged. 5. The addition of non-starch polysaccharides to the 35 g of protein/day diet had a demonstrable effect upon faecal weight and composition, but did not exert any significant influence upon urea kinetics. 6. It is concluded that large changes in the rate of urea production are not necessary for adaptation to a low-protein diet, rather the salvaging of urea nitrogen in the lower bowel appears to be an important mechanism through which the body adapts to a low-protein diet. The salvaging of urea nitrogen by the colon makes an important contribution to the conservation of body nitrogen.

Salvage of Exogenous Urea Nitrogen Enhances Nitrogen Balance in Normal Men Consuming Marginally Inadequate Protein Diets

1996 ◽  
Vol 90 (3) ◽  
pp. 215-225 ◽  
Author(s):  
Tracey S. Meakins ◽  
Alan A. Jackson
Keyword(s):  
Nitrogen Balance ◽  
Urea Hydrolysis ◽  
The Body ◽  
Protein Diet ◽  
Low Protein Diet ◽  
Urea Nitrogen ◽  
Low Protein ◽  
Significant Difference ◽  
Normal Men ◽  
Protein Diets

1. Urea kinetics were measured in six healthy men using prime/intermittent oral doses of [15N15N] urea, after five days consuming one of four diets which varied in their nitrogen content: a reference diet (REF, 70 g of protein and 11.2 g of N); a low-protein diet (LP, 30 g of protein and 4.8 g of N); a low-protein diet with 6.9 g of urea added (LP-U1, 30 g of protein and 8 g of N); a low-protein diet with 13.7 g of urea added (LP-U2, 30 g of protein and 11.2 g of N). 2. Apparent nitrogen balance on the REF diet was significantly better than on the LP or the LP-U1 diets. The addition of the higher level of urea in the LP-U2 diet enhanced apparent nitrogen balance compared with the LP or LP-U1 diets, and was not different to apparent nitrogen balance on the REF diet. 3. On the LP, LP-U1 and LP-U2 diets, the rate of endogenous urea production was not different, and was about 60% of that on the REF diet, a statistically significant difference. The addition of a dietary supplement of urea increased the rate of urea appearance in the urea pool in direct relation to the dose of urea taken. There was no difference in the rate of appearance between the REF and LP-U2 diets, for both of which the rate of appearance was significantly greater than on the LP diet. 4. The excretion of urea in urine on the LP diet was 62% of that on the REF diet, a significant difference. There was no significant difference in the rate of urea excretion between the REF, LP-U1 and LP-U2 diets. 5. The rate of urea hydrolysis by the colonic microflora on the REF diet was more than twice that on the LP or LP-U1 diets. Supplementation with urea at the higher level, LP-U2, significantly increased hydrolysis to the same level as on the REF diet. Most of the nitrogen derived from urea hydrolysis was retained in the metabolic pool (>80%), with no difference in the rate of retention between the REF and LP-U2 diets, both greater than the LP or LP-U1 diets. 6. The dietary supplements of urea increased the size of the body urea pool significantly. Renal clearance of urea was highest on the REF diet and decreased 13–29% on the low-protein diets. Bowel clearance was highest on the REF diet and decreased 46–55% on the low-protein diets. Neither urinary excretion of urea nor urea hydrolysis in the bowel were related simply to the concentration of urea in blood. Urea hydrolysis related most closely to the rate of appearance of urea in the urea pool. 7. The salvage of urea nitrogen was increased on the highest level of supplementation, but the overall sensitivity of the system was low, suggesting that other factors might be limiting for effective urea hydrolysis and the salvage of urea nitrogen.

scholarly journals The growth and development of rats given a low-protein diet

1972 ◽  
Vol 27 (3) ◽  
pp. 527-536 ◽  
Author(s):  
J. W. T. Dickerson ◽  
P. C. R. Hughes ◽  
P. A. McAnulty
Keyword(s):  
Body Weight ◽  
Brain Stem ◽  
Dna Content ◽  
The Body ◽  
Protein Diet ◽  
Low Protein Diet ◽  
Casein Diet ◽  
Control Value ◽  
Low Protein ◽  
The Brain

1. Weanling (24-d-old) rats of a black and white hooded strain were allowed free access for 28 d to a diet containing 5% casein supplemented with methionine, and sucrose as the carbohydrate. Controls were fed on a 25% casein diet with a corresponding reduction in sucrose. Animals given the deficient diet were killed either at 52 d of age or after subsequent rehabilitation on the 25% casein diet when aged 140 d. These animals were compared with controls killed at these two ages and at the start of the experiment.2. The skeletons were X-rayed, skeletal maturity was determined according to a scoring system, and various bones were measured. The forebrain and cerebellum were analysed for cholesterol and DNA and the brain stem for cholesterol only. The DNA content of the paired quadriceps muscles and the livers was also determined.3. On the low-protein diet the body-weight rose by 7 g compared with the control value of 115 g. On rehabilitation, the body-weight of the previously malnourished group showed the expected growth spurt, but failed to attain that of the controls at 140 d.4. With the exception of the pelvis width, all the bones grew a little during the period on the low-protein diet. After rehabilitation, the hind limb, pelvis, iliac and spine lengths and the bi-iliac width remained smaller than these measurements in the corresponding controls, whereas there was no difference in the length of the fore limb, width of the pelvis or in the bone maturity score.5. The forebrains and cerebellums of the malnourished rats did not increase in weight, whereas some increase occurred in the brain stem. The concentration of cholesterol in the forebrains of the deficient animals was the same as that in controls of the same age, but on rehabilitation the concentration did not rise to the control value. The concentration of cholesterol in the cerebellum and brain stem of the deficient rats was lower than in controls of the same age but, whereas that in the cerebellum attained an almost normal level on rehabilitation, that in the brain stem remained significantly lower. The low-protein diet prevented the normal increase in cerebellum DNA and the amount remained low in the rehabilitated animals.6. The experimental diet caused a complete cessation of growth of the quadriceps muscles, and even after rehabilitation they weighed less than their controls. The DNA content, however, was not significantly lower.7. The low-protein diet did not permanently affect either the weight or DNA content of the liver.

The effect of dietary protein intake on factors associated with male infertility: A systematic literature review and meta-analysis of animal clinical trials in rats

2020 ◽  
Vol 26 (1) ◽  
pp. 53-64
Author(s):  
Peter Kelechi Ajuogu ◽  
Mohammed AK Al-Aqbi ◽  
Robert A Hart ◽  
Mitchell Wolden ◽  
Neil A Smart ◽  
...  
Keyword(s):  
Body Weight ◽  
Male Infertility ◽  
Seminal Vesicle ◽  
Serum Testosterone ◽  
The Body ◽  
Protein Diet ◽  
Endocrine Function ◽  
Low Protein Diet ◽  
Factors Associated ◽  
Low Protein

Background: Studies have shown that the amount of protein in the diet affects the hypothalamic-pituitary-testis axis and sub-optimal quantity reduces male fertility potential in both animals and humans. However, individual research reports on the factors associated with male infertility are collectively uncharacterized. Aim: We systematically reviewed, and meta-analysed animal (rats) studies on the effect of low protein diet on factors associated with male infertility. Methods: PubMed Central, EMBASE and Scopus databases were searched from inception to 30 March 2019 for the study concepts and related keywords in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) protocol. Data on the outcome measures were extracted and pooled across trials using random-effects model and expressed as mean differences (MD) at a 95% confidence interval (CI). Results: Twelve trials identified from 3327 studies, met our inclusion criteria in the comparison of a low protein diet (2–10% protein) vs control protein diet (17–23% protein). The results showed that a low protein diet caused a significant reduction in the body weight ( P = 0.0001) testis weight ( P = 0.0001), seminal vesicle weight ( P = 0.0003), epididymis weight P = 0.02), serum testosterone ( P = 0.001) and follicle-stimulating hormone (FSH) concentrations ( P = 0.04) compared with the control treatments. No effect on luteinizing hormone (LH) plasma concentration ( P = 0.13) was observed. Conclusion: This study revealed that low protein diet caused significant reductions in body weight, testis, epididymis and seminal vesicle weights, serum testosterone and FSH concentration in rats. We infer that sub-optimal protein consumption reduces the gonadal and endocrine function, and consequently male infertility.

Plasma urea nitrogen as an indicator of protein quality. I. Factors affecting the concentration of urea in the blood of the preruminant lamb

1976 ◽  
Vol 27 (1) ◽  
pp. 109 ◽  
Author(s):  
RD Kirk ◽  
DM Walker
Keyword(s):  
Protein Content ◽  
Protein Concentration ◽  
Protein Quality ◽  
Protein Diet ◽  
Low Protein Diet ◽  
Dry Matter Content ◽  
Urea Nitrogen ◽  
Plasma Urea ◽  
Low Protein ◽  
Gross Energy

Preruminant male crossbred lambs, aged between 2 days and 5 weeks, were given milk replacers of low (0.10 of total energy as protein) or medium (0.28) protein content. Plasma urea nitrogen (PUN) values were unaffected by: the time of blood sampling within 9 hr after feeding; the age of the lamb, between 3 and 33 days; the lamb's intake of the medium protein diet (range, 500–1180 kJ gross energy/day per kg0.73 storage of plasma samples at –15°C for 5 months before analysis; fasting of lambs for 4 days; feeding of lambs on a nitrogen-free diet for 7 days. PUN values were significantly increased by: an increase in the dietary protein concentration; a reduction in the lamb's intake of the low protein diet below 840 kJ gross energy/day per kg0.73 (negative nitrogen balance); an increase in the dry matter content of the medium protein diet from 0.10 to 0.25; the addition of urea to the low protein diet (peak values 4–6 hr after feeding). PUN values estimated on successive days reflected a change in the protein content of the diet within 3–4 days, regardless of whether the change in protein concentration was from low to medium, or medium to low. It is concluded that PUN values can be used to evaluate protein quality only when experimental conditions are strictly controlled. Blood samples taken without regard to the above factors may give misleading results.

Body composition studies with the milk-fed lamb. II. The effect of the age of the lamb and the protein content of the diet on the chemical composition of the body and its organs

1970 ◽  
Vol 75 (2) ◽  
pp. 279-285 ◽  
Author(s):  
K. T. Jagusch ◽  
B. W. Norton ◽  
D. M. Walker
Keyword(s):  
Chemical Composition ◽  
Protein Content ◽  
High Protein Diet ◽  
The Body ◽  
High Protein ◽  
Protein Diet ◽  
Low Protein Diet ◽  
Chemical Components ◽  
Available N ◽  
Low Protein

SUMMARYEighteen male cross-bred lambs (aged 2–5 days) in two equal groups were given artificial milk diets of either low- or high-protein content; subgroups of three lambs were slaughtered after 2, 4 and 6 weeks on experiment. The composition of the change in empty body weight (E.B.W.), and the chemical composition of the change in weight of the separate compartments and organs, were determined by the comparative slaughter method.Lambs given the high-protein diet made significant gains in weight and in all chemical components in all periods. The composition of their E.B.W. was closely related to E.B.W. regardless of age. Lambs given the low-protein diet made only small gains in weight in 6 weeks, of which 76% was fat. The chemical composition of their E.B.W. was closely related to E.B.W. within each age group. The net gain of protein of these lambs in 6 weeks represented only 1% of the total weight gain, and over 50% of the protein gain was in wool. The skin and blood lost protein during the first 2 weeks, and failed to recover this loss during the remaining 4 weeks. Other organs lost protein initially but recovered this loss between 2 and 6 weeks.It was concluded that the initial loss of protein represented the labile protein reserves of the lamb, and the subsequent recovery was an adaptation to the low-protein diet. Furthermore, the results with both diets indicated that the skin and blood were the most inefficient of the organs in the body in utilizing the available N during a period of protein deficiency, or during a period of abundance in the dietary supply of N.

scholarly journals BLOOD PLASMA PROTEIN REGENERATION AS INFLUENCED BY FASTING, INFECTION, AND DIET FACTORS

1938 ◽  
Vol 67 (5) ◽  
pp. 675-690 ◽  
Author(s):  
S. C. Madden ◽  
W. E. George ◽  
G. S. Waraich ◽  
H. Whipple
Keyword(s):  
Blood Plasma ◽  
Plasma Protein ◽  
Building Material ◽  
Protein Production ◽  
Basal Diet ◽  
The Body ◽  
Protein Diet ◽  
Low Protein Diet ◽  
Body Protein ◽  
Low Protein

When blood plasma proteins are depleted by bleeding, with return of the washed red cells (plasmapheresis) it is possible to bring dogs to a steady state of hypoproteinemia and a uniform plasma protein production on a basal low protein diet. These dogs are clinically normal with normal appetite, no anemia and normal nitrogen metabolism. These dogs become test subjects by which various factors relating to plasma protein production may be tested. The normal dog (10 to 13 kg.) has a substantial reserve store of plasma protein building material (10 to 60+ gm.) which requires 2 to 6 weeks plasmapheresis for its complete removal. After this period the dog will produce uniform amounts of plasma protein each week on a fixed basal diet. Dogs previously depleted by plasmapheresis and then permitted to return to normal during a long rest period of many weeks, may show much higher reserve stores of protein building material in subsequent periods of plasma depletion (see Table 1). Under uniform conditions of low protein diet intake when plasmapheresis is discontinued for 2 weeks the plasma protein building material is stored quantitatively in the body and can subsequently be recovered (Table 4) in the next 2 to 3 weeks of plasmapheresis. Given complete depletion of plasma protein building reserve stores the dog can produce very little (2± gm. per week) plasma protein on a protein-free diet. This may be related to the wear and tear of body protein and conservation of these split products. Abscesses produced in a depleted dog during a fast may cause some excess production of plasma protein which is probably related to products of tissue destruction conserved for protein anabolism. Gelatin alone added to the basal diet causes very little plasma protein production but when supplemented by tryptophane gives a large protein output, while tryptophane alone is inert.

scholarly journals Fetal and neonatal exposure to AZT and low-protein diet affects glucose homeostasis: a model with implications for AIDS prevention

2005 ◽  
Vol 289 (6) ◽  
pp. E1115-E1118 ◽  
Author(s):  
K. Morten ◽  
P. Field ◽  
N. Ashley ◽  
K. A. Williams ◽  
D. Harris ◽  
...  
Keyword(s):  
Birth Weight ◽  
Litter Size ◽  
Glucose Homeostasis ◽  
Mitochondrial Function ◽  
Fasting Blood Glucose ◽  
The Body ◽  
Protein Diet ◽  
Low Protein Diet ◽  
Nutritional Deprivation ◽  
Low Protein

Zidovudine (AZT) lowers the perinatal transmission of HIV but can impair mitochondrial function by depleting mitochondrial DNA (mtDNA). AZT therapy and perinatal nutritional deprivation affect the body fat distribution, which influences glucose tolerance. We sought to model intrauterine exposure to AZT in humans to determine whether it interacts with low-protein diet (LPD) to impact on birth weight and glucose homeostasis in the offspring. Pregnant dams and their offspring were given AZT, an LPD, or AZT and an LPD (LPD + AZT). AZT reduced mtDNA copy number in liver and birth weight in the offspring and increased their fasting glucose and insulin ( P = 0.021, 0.03, 0.001, and 0.011 respectively) at 6–8 wk of age. LPD decreased litter size and birth weight ( P = 0.01 and 0.012). In the LPD + AZT group, birth weight and litter size were reduced compared with untreated controls, and fasting blood glucose and insulin were raised. There was a significant interaction between LPD and AZT on fasting insulin levels ( P = 0.025). Islet size was not significantly affected, but the mean β-cell area/islet was reduced in the LPD + AZT group compared with controls ( P < 0.05). Early exposure to AZT interacts with LPD to impair fetal development in this model. This combination appeared to impair the supply of insulin and, hence, glucose homeostasis, perhaps as a result of impaired mitochondrial function. Although it is not certain that this can be extrapolated to humans, maternal nutritional deprivation combined with AIDS therapy could influence both birth weight and onset of diabetes.

Limits of adaptation to a diet low in protein in normal man: urea kinetics

1992 ◽  
Vol 83 (1) ◽  
pp. 103-108 ◽  
Author(s):  
M. Danielsen ◽  
A. A. Jackson
Keyword(s):  
Production Rate ◽  
Nitrogen Balance ◽  
Healthy Men ◽  
Nitrogen Pool ◽  
Low Protein ◽  
Urea Production ◽  
Urea Kinetics ◽  
Normal Man ◽  
Oral Doses ◽  
Protein Diets

1. Urea kinetics were measured using prime/intermittent oral doses of [15N15N]urea in six healthy men taking diets adequate in energy and containing either 74 or 30 g of protein/day. 2. On 74 g of protein/day, urea production (199 mg of N day−1 kg−1) was 121% of intake, with 60% of the urea produced being excreted in the urine and 40% being salvaged in the colon; 69% of the salvaged nitrogen was retained in the metabolic nitrogen pool. 3. Nitrogen balance was not maintained on 30 g of protein/day. There was a significant decrease in the urea production rate (123 mg of N day−1 kg−1) and 54% of production was excreted in urine, with 46% being salvaged. 4. The pattern of urea production and salvaging on 30 g of protein/day was different to that seen in an earlier study on 35 g of protein/day, with a significant decrease in both production (71%) and salvaging (50%). 5. These data reinforce the conclusions drawn from an earlier study, that the salvaging of urea nitrogen by the colon is an integral part of the process of adaptation to low protein diets. The salvage system appears to fail on an intake of 30 g of protein/day and nitrogen is no longer conserved in sufficient amounts for balance to be maintained. 6. The changes seen in urea kinetics reinforce the conclusion based upon nitrogen balance that the minimum physiological requirement for protein in normal adult man lies between 30 and 35 g of protein/day.

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