Protein-calorie Restriction Research Articles

Impact of protein intake from a caloric-restricted diet on liver lipid metabolism in overweight and obese rats of different sexes

In addition to being linked to an excess of lipid accumulation in the liver, being overweight or obese can also result in disorders of lipid metabolism. There is limited understanding regarding whether different levels of protein intake within an energy-restricted diet affect liver lipid metabolism in overweight and obese rats and whether these effects differ by gender, despite the fact that both high protein intake and calorie restriction can improve intrahepatic lipid. The purpose of this study is to explore the effects and mechanisms of different protein intakes within a calorie-restricted diet on liver lipid metabolism, and to investigate whether these effects exhibit gender differences. The Sprague-Dawley rats, which were half female and half male, were used to construct a rat model of overweight and obesity attributed to a high-fat diet. They were then split up into five groups: the normal control (NC) group, the model control (MC) group, the calorie-restricted low protein (LP) group, the calorie-restricted normal protein (NP) group, and the calorie-restricted high protein (HP) group. Body weight was measured weekly. Samples of plasma and liver were obtained after eight weeks and analyzed for glucose, triglycerides, cholesterol, and hormones in the plasma as well as the liver fat and factors involved in the liver’s synthesis and degradation. For the male rats, compared to the HP group, the weight of liver fat in the LP and NP group was significantly higher (P < 0.05). However, for the female rats, there was no significant variation among the three calorie-restricted groups (P > 0.05). There was no significant variation in the concentration of total cholesterol (TC), very low density lipoprotein (VLDL), low density lipoprotein (LDL), and high density lipoprotein (HDL) among the three male calorie-restricted groups (P > 0.05), while the TC and VLDL concentrations in the female LP and NP group were significantly higher compared to those in the HP group (P < 0.05). Moreover, the trend of expression in the signaling pathways of adiponectin/phosphorylated AMP-activated protein kinase (p-AMPK) and adiponectin/peroxisome proliferators-activated receptor alpha (PPARα) in the liver was consistent with that of the liver fat content, and leptin acted in the same way as adiponectin. Compared with the three calorie-restricted groups, the expressions of nuclear sterol-regulatory element-binding protein-2 (nSREBP-2) and 3-hydroxy-3-methylglutaryl coenzyme A reductase (HMG-CoA reductase) involved in cholesterol synthesis and low-density lipoprotein receptor (LDLR) and cholesterol 7-alpha hydroxylase (CYP7A1) involved in cholesterol clearance in the MC group were significantly lower (P < 0.05). A 40% energy restriction can significantly reduce the body weight, body fat, liver fat, and the blood concentration of TG in both male and female overweight and obese rats, but it can significantly increase the blood concentration of TC in overweight and obese male rats. At the same time of 40% calorie restriction, increasing dietary protein intake to twice the normal protein intake has a stronger effect on promoting hepatic triglyceride oxidation and reducing liver fat content in the male overweight and obese rats by increasing the levels of adiponectin and leptin in the blood, and can also significantly reduce the plasma cholesterol concentration in the female overweight and obese rats through inhibiting cholesterol synthesis most likely by increasing glucagon level in the blood.

A High Protein Calorie Restriction Diet Alters the Gut Microbiome in Obesity.

Background: High protein calorie restriction diets have shown clinical efficacy for obesity, but the mechanisms are not fully known. The intestinal microbiome is a mediator of obesity and preclinical data support an effect of high protein diet (HPD) on the gut microbiome of obesity, but there are few studies in humans. Methods: To address this, we conducted a dietary intervention trial of 80 overweight and obese subjects who were randomized to a calorie-restricted high protein diet (HPD) (30% calorie intake) or calorie-restricted normal protein diet (NPD) (15%) for 8 weeks. Baseline dietary intake patterns were assessed by the Diet History Questionnaire III. Longitudinal fecal sampling was performed at baseline, week 1, week 2, week 4, week 6, and week 8, for a total of 365 samples. Intestinal microbiome composition was assessed by 16S rRNA gene sequencing. Results: At baseline, microbial composition was associated with fiber and protein intake. Subjects on the HPD showed a significant increase in microbial diversity as measured by the Shannon index compared to those on the NPD. The HPD was also associated with significant differences in microbial composition after treatment compared to the NPD. Both diets induced taxonomic shifts compared to baseline, including enrichment of Akkermansia spp. and Bifidobacterium spp. and depletion of Prevotella spp. Conclusion: These findings provide evidence that weight loss diets alter the gut microbiome in obesity and suggest differential effects of HPDs compared to NPDs which may influence the clinical response to HPD.

Insights From a Short-Term Protein-Calorie Restriction Exploratory Trial in Elective Carotid Endarterectomy Patients.

Open vascular surgery interventions are not infrequently hampered by complication rates and durability. Preclinical surgical models show promising beneficial effects in modulating the host response to surgical injury via short-term dietary preconditioning. Here, we explore short-term protein-calorie restriction preconditioning in patients undergoing elective carotid endarterectomy to understand patient participation dynamics and practicalities of robust research approaches around nutritional/surgical interventions. We designed a pilot prospective, multicenter, randomized controlled study in patients undergoing carotid endarterectomy. After a 3:2 randomization to a 3-day preoperative protein-calorie restriction regimen (30% calorie/70% protein restriction) or ad libitum group, blood, clinical parameters, and stool samples were collected at baseline, pre-op, and post-op days 1 and 30. Subcutaneous and perivascular adipose tissues were harvested periprocedurally. Samples were analyzed for standard chemistries and cell counts, adipokines. Bacterial DNA isolation and 16S rRNA sequencing were performed on stool samples and the relative abundance of bacterial species was measured. Fifty-one patients were screened, 9 patients consented to the study, 5 were randomized, and 4 completed the trial. The main reason for non-consent was a 3-day in-hospital stay. All 4 participants were randomized to the protein-calorie restriction group, underwent successful endarterectomy, reported no compliance difficulties, nor were there adverse events. Stool analysis trended toward increased abundance of the sulfide-producing bacterial species Bilophila wadsworthia after dietary intervention (P = .08). Although carotid endarterectomy patients held low enthusiasm for a 3-day preoperative inpatient stay, there were no adverse effects in this small cohort. Multidisciplinary longitudinal research processes were successfully executed throughout the nutritional/surgical intervention. Future translational endeavors into dietary preconditioning of vascular surgery patients should focus on outpatient approaches.

Regulation of intestinal growth in response to variations in energy supply and demand.

SummaryThe growth of the intestine requires energy, which is known to be met by catabolism of ingested nutrients. Paradoxically, during whole body energy deficit including calorie restriction, the intestine grows in size. To understand how and why this happens, we reviewed data from several animal models of energetic challenge. These were bariatric surgery, cold exposure, lactation, dietary whey protein intake and calorie restriction. Notably, these challenges all reduced the adipose tissue mass, altered hypothalamic neuropeptide expression and increased intestinal size. Based on these data, we propose that the loss of energy in the adipose tissue promotes the growth of the intestine via a signalling mechanism involving the hypothalamus. We discuss possible candidates in this pathway including data showing a correlative change in intestinal (ileal) expression of the cyclin D1 gene with adipose tissue mass, adipose derived‐hormone leptin and hypothalamic expression of leptin receptor and the pro‐opiomelanocortin gene. The ability of the intestine to grow in size during depletion of energy stores provides a mechanism to maximize assimilation of ingested energy and in turn sustain critical functions of tissues important for survival.

The Gcn4 transcription factor reduces protein synthesis capacity and extends yeast lifespan

In Saccharomyces cerevisiae, deletion of large ribosomal subunit protein-encoding genes increases the replicative lifespan in a Gcn4-dependent manner. However, how Gcn4, a key transcriptional activator of amino acid biosynthesis genes, increases lifespan, is unknown. Here we show that Gcn4 acts as a repressor of protein synthesis. By analyzing the messenger RNA and protein abundance, ribosome occupancy and protein synthesis rate in various yeast strains, we demonstrate that Gcn4 is sufficient to reduce protein synthesis and increase yeast lifespan. Chromatin immunoprecipitation reveals Gcn4 binding not only at genes that are activated, but also at genes, some encoding ribosomal proteins, that are repressed upon Gcn4 overexpression. The promoters of repressed genes contain Rap1 binding motifs. Our data suggest that Gcn4 is a central regulator of protein synthesis under multiple perturbations, including ribosomal protein gene deletions, calorie restriction, and rapamycin treatment, and provide an explanation for its role in longevity and stress response.

Protein and Calorie Restriction Contribute Additively to Protection from Renal Ischemia Reperfusion Injury Partly via Leptin Reduction in Male Mice1–3

Background: Short-term dietary restriction (DR) without malnutrition preconditions against surgical stress in rodents; however, the nutritional basis and underlying nutrient/energy-sensing pathways remain poorly understood.Objectives: We investigated the relative contribution of protein restriction (PR) vs. calorie restriction (CR) to protection from renal ischemia reperfusion injury (IRI) and changes in organ-autonomous nutrient/energy-sensing pathways and hormones underlying beneficial effects.Methods: Mice were preconditioned on experimental diets lacking total calories (0–50% CR) or protein/essential amino acids (EAAs) vs. complete diets consumed ad libitum (AL) for 1 wk before IRI. Renal outcome was assessed by serum markers and histology and integrated over a 2-dimensional protein/energy landscape by geometric framework analysis. Changes in renal nutrient/energy-sensing signal transduction and systemic hormones leptin and adiponectin were also measured. The genetic requirement for amino acid sensing via general control non-derepressible 2 (GCN2) was tested with knockout vs. control mice. The involvement of the hormone leptin was tested by injection of recombinant protein vs. vehicle during the preconditioning period.Results: CR-mediated protection was dose dependent up to 50% with maximal 2-fold effect sizes. PR benefits were abrogated by EAA re-addition and additive with CR, with maximal benefits at any given amount of CR occurring with a protein-free diet. GCN2 was not required for functional benefits of PR. Activation and repression of nutrient/energy-sensing kinases, AMP-activated protein kinase (AMPK) and mechanistic target of rapamycin complex 1 (mTORC1), respectively, on PR reflected a state of negative energy balance, paralleled by 13% weight loss and an 87% decrease in leptin, independent of calorie intake. Recombinant leptin administration partially abrogated benefits of dietary preconditioning against renal IRI.Conclusions: In male mice, PR and CR both contributed to the benefits of short-term DR against renal IRI independent of GCN2 but partially dependent on reduced circulating leptin and coincident with AMPK activation and mTORC1 repression.

Genomic lesions and colorectal carcinogenesis: the effects of protein-calorie restriction and inulin supplementation on deficiency statuses.

The present study investigated the effects of restricting protein and calories and supplementation of inulin, a fiber comprising a linear type of polydisperse carbohydrates composed primarily of fructil-fructose bonds (β-(2→1), on the deficiency statuses of animals in which genomic lesion development and colorectal carcinogenesis had been induced. This experiment involved adult male Swiss mice (N = 11/group). The experimental groups were as follows: Negative Control (vehicle), Positive Control, 1,2-dimethylhydrazine (DMH), Inulin, and Associate. DMH, which promoted colorectal cancer, was administered intraperitoneally in 4 20-mg/kg body weight (bw) doses during a 2-week period; inulin was administered orally at a daily dose of 50 mg/kg bw. Each group was bifurcated; half of each group was fed a normal protein diet and the other half was fed a low-protein diet. The results indicated that a correlation existed between malnutrition and an increased frequency of genomic lesions but that malnutrition did not predispose animals to colorectal cancer development. Inulin exhibited genotoxic activity, which requires further investigation, and low anti-genotoxic activity. Moreover, inulin reduced the levels of intestinal carcinogenesis biomarkers in both malnourished and healthy animals. These data suggest that inulin holds therapeutic potential and is a strong candidate for inclusion among the functional foods used for cancer prevention in both properly nourished and malnourished individuals.

Hypoferremia of Fasting in Mice Is Associated with Increased Hepcidin and Decreased Erythroferrone Expression

Background: Protein-calorie restriction in humans is associated with changes in iron metabolism that differ from dietary iron-deficiency. Dietary iron absorption and tissue iron distribution and are regulated by the hepatocellular peptide hormone hepcidin, which mediates a decrease in circulating iron concentrations and increase in cellular iron stores. Hepcidin is upregulated in response to increased serum and tissue iron, upregulated in response to ER-stress via the transcription factor CREB-H, and down-regulated in response to erythroid iron demand via the circulating signaling molecule erythroferrone/myonectin (ERFE). An overnight fast was reported to decrease expression of skeletal muscle ERFE in mice.Objective: The aim of this study was to investigate the regulation of hepcidin in the hypoferremia of fasting.Design/Methods: We analyzed parameters of iron homeostasis in five 5 week old male AKR mice fasted for 18 hours overnight (and allowed access to water) compared with mice with access to chow ad libitum. Serum and tissue iron concentrations were measured. Liver hepcidin mRNA was quantified by real-time RT-PCR and verified by Northern blot analysis. Marrow ERFE and liver CREB-H mRNA expression was quantified by RT-PCR and normalized to beta actin.Results: As anticipated, fasted mice had significantly lower serum iron concentrations (203 vs 321 mcg/dL, P<0.001) and transferrin saturations (64.4 vs 79.6%, P<0.05). Duodenal iron concentrations were increased in fasted mice, 2.3-fold (P<0.01). Histochemical staining demonstrated iron retention in the absorptive enterocytes. Liver (916 vs 735 mcg/g, P=0.1) and splenic (480 vs 414 mcg/g, P=0.001) iron concentrations were modestly higher in the fasted mice. Despite hypoferremia, the fasted mice demonstrated increased liver hepcidin expression (1.9 fold, P < 0.05). Liver CREB-H mRNA expression was increased ~10 fold, P<0.01; however there was no change in liver XBP-1 processing (marker of ER stress). Marrow ERFE expression was downregulated by approximately one third (P<0.01).Conclusions: The fasting state in mice is associated with increased hepcidin expression, iron retention in absorptive enterocytes, and decreased circulating iron. These observations suggest that the hypoferremia of fasting is not consequent to limited iron availability, but rather to hepcidin-mediated retention of iron in the duodenum and storage tissues. They moreover support a role for nutritional state, independent of iron status, as a regulator of hepcidin and mediated by changes in expression of ERFE and CREB-H. DisclosuresNo relevant conflicts of interest to declare.

Trimethoprim-sulfamethoxazole increase micronuclei formation in peripheral blood from weanling well-nourished and malnourished rats

The combination of trimethoprim and sulfamethoxazole (TMP-SMX) is a widely used drug. In spite of this, there are few reports on its genotoxicity, and the results are controversial. Severe malnutrition is a complex condition that increases the susceptibility to infections. Consequently, drugs are extensively used in malnutrition cases. Experimental animal models have been widely used to study the effects of malnutrition. Neonatal rats were experimentally malnourished (UN) during lactation. The UN rats weighed 51.1% less than the well-nourished (WN) controls and had lower concentrations of serum protein and blood lipids. The micronucleus (MN) assay is useful for detecting chromosome damage induced by nutritional deficiencies. In vivo rodent MN assays have been widely used to screen genotoxic agents. In this study, we have evaluated the frequency of spontaneous and TMP-SMX-induced micronuclei in the peripheral blood of weanling (21 days of age) rats using a flow cytometric analysis technique. The spontaneous frequency of micronucleated reticulocytes (MN-RETs) was 2.7 times greater in the UN rats than in the WN rats. In rats that were not treated with TMP-SMX, the percentage of reticulocytes was significantly lower (41.1%) in the UN rats than the WN controls. A therapeutic dose of TMP-SMX (80 mg/kg (TMP), 400 mg/kg (SMX) for 48 hr) increased MN-RETs in the WN and in the UN rats. The data demonstrate the genotoxic effect of this drug. The results indicate that severe protein-calorie restriction and drug treatment enhance DNA damage in rat peripheral blood reticulocytes, potentially increasing the risk of negative effects on health.

Failure of carnitine in improving hepatic nitrogen content in alcoholic and non-alcoholic malnourished rats

AIMS:To investigate the effect of carnitine supplementation on alcoholic malnourished rats' hepatic nitrogen content.METHODS:Malnourished rats, on 50% protein‐calorie restriction with free access to water (malnutrition group) and malnourished rats under the same conditions with free access to a 20% alcohol/water solution (alcohol group) were studied. After the undernourishment period (4 weeks with or without alcohol), both groups were randomly divided into two subgroups, one of them nutritionally recovered for 28 days with free access to a normal diet and water (recovery groups) and the other re‐fed with free access to diet and water plus carnitine (0.1 g/g body weight/day by gavage) (carnitine groups). No alcohol intake was allowed during the recovery period.RESULTS:The results showed: i) no difference between the alcohol/no alcohol groups, with or without carnitine, regarding body weight gain, diet consumption, urinary nitrogen excretion, plasma free fatty acids, lysine, methionine, and glycine. ii) Liver nitrogen content was highest in the carnitine recovery non‐alcoholic group (from 1.7 to 3.3 g/100 g, P<0.05) and lowest in alcoholic animals (about 1.5 g/100g). iii) Hepatic fat content (∼10 g/100 g, P>.05) was highest in the alcoholic animals.CONCLUSION:Carnitine supplementation did not induce better nutritional recovery.

Urea cycle regulation by mitochondrial sirtuin, SIRT5

Mammalian sirtuins have diverse roles in aging, metabolism and disease. Recently we reported a new function for SIRT5 in urea cycle regulation. Our study uncovered that SIRT5 localized to mitochondria matrix and deacetylates carbamoyl phosphate synthetase 1 (CPS1), an enzyme which is the first and rate-limiting step of urea cycle. Deacetylation of CPS1 by SIRT5 resulted in activation of CPS1 enzymatic activity. Indeed, SIRT5-deficient mice failed to up-regulate CPS1 activity and showed hyper ammonemia during fasting. Similar effects are also observed on high protein diet or calorie restriction. These data indicate SIRT5 also has an emerging role in the metabolic adaptation to fasting, high protein diet and calorie restriction.

Overweight is gender-dependent in prenatal protein–calorie restricted adult rats acting on the blood pressure and the adverse cardiac remodeling

Postnatal heart remodeling was studied in rats submitted to prenatal protein–calorie restriction (R). Offspring were divided in four groups: control male (CM) and female (CF) vs. restricted male (RM) and female (RF) and lived 120 days. The offspring blood pressure (BP) and biometry were periodically analyzed. In the euthanasia day, the left ventricular (LV) mass index, the cardiomyocyte nuclei profile number ( N[cmn]) (disector method), the cross-sectional cardiomyocyte area ( A[cm]) and the stereology for intramyocardial arteries (ima) were estimated. Interactions between gender and prenatal nutritional conditions were tested with the two-way ANOVA. RM animals showed higher BP and greater body mass and smaller LV mass index than the other groups. N[cmn] and stereology parameters of ima were smaller, and A[cm] was greater in the R groups rats than in the C groups rats; these structural changes were only dependent of the prenatal nutritional condition but not gender-dependent. In conclusion: hypertension and body and cardiac growth were influenced by the interaction between gender and prenatal nutritional conditions, while cardiac remodeling seems to be only programmed by the adverse intrauterine environment.

Maternal gestational protein-calorie restriction decreases the number of glomeruli and causes glomerular hypertrophy in adult hypertensive rats

This work analyzed the renal function and structure in offspring rats that were submitted to maternal protein-calorie restriction during prenatal or lactation periods. Kidneys from adult offspring were studied. Animals from mothers that were submitted to food restriction were separated in 3 groups: control, prenatal restriction, and lactation restriction. Blood pressure, microalbuminuria, and glomerular filtration rate were determined. Kidney cortical remodeling was analyzed with stereology; volume-weighted glomerular volume and the number of glomeruli were estimated. Adult prenatal restriction offspring showed enhanced microalbuminuria, decreased glomerular filtration rate, and hypertension; their kidneys showed a smaller number of hypertrophied glomeruli than control and lactation restriction animals. Maternal prenatal protein-calorie restriction in rats causes kidney disease in adult offspring, which is characterized by hypertension and renal dysfunction and suggests secondary kidney remodeling because of an impairment of glomerulogenesis.

Protein calorie restriction has opposite effects on glucose metabolism and insulin gene expression in fetal and adult rat endocrine pancreas.

We previously demonstrated that fetuses from undernourished pregnant rats exhibited increased beta-cell mass and hyperinsulinemia, whereas keeping food restriction until adult age caused reduced beta-cell mass, hypoinsulinemia, and decreased insulin secretion. Because these alterations can be related to insulin availability, we have now investigated early and long-term effects of protein calorie food restriction on insulin mRNA levels as well as the possible mechanisms that could modulate the endogenous insulin mRNA content. We used fetuses at 21.5 days of gestation proceeding from food-restricted rats during the last week of pregnancy and 70-day-old rats undernourished from day 14 of gestation until adult age and with respective controls. Insulin mRNA levels, glucose transporters, and total glycolysis and mitochondrial oxidative fluxes were evaluated. We additionally analyzed undernutrition effects on signals implicated in glucose-mediated insulin gene expression, especially pancreatic duodenal homeobox-1 (PDX-1), stress-activated protein kinase-2 (p38/SAPK2), and phosphatidylinositol 3-kinase. Undernourished fetuses showed increased insulin mRNA, oxidative glucose metabolism, and p38/SAPK2 levels, whereas undernutrition until adult age provoked a decrease in insulin gene expression, oxidative glucose metabolism, and PDX-1 levels. The results indicate that food restriction caused changes in insulin gene expression and content leading to alterations in glucose-stimulated insulin secretion. The molecular events, increased p38/SAPK2 levels in fetuses and decreased PDX-1 levels in adults, seem to be the responsible for the altered insulin mRNA expression. Moreover, because PDX-1 activation appears to be regulated by glucose-derived metabolite(s), the altered glucose oxidation caused by undernutrition could in some manner affect insulin mRNA expression.

Protein Calorie Restriction Affects Nonhepatic IGF-I Production and the Lymphoid System: Studies Using the Liver-Specific IGF-I Gene-Deleted Mouse Model

Protein Calorie Restriction Affects Nonhepatic IGF-I Production and the Lymphoid System: Studies Using the Liver-Specific IGF-I Gene-Deleted Mouse Model

Protein calorie restriction affects nonhepatic IGF-I production and the lymphoid system: studies using the liver-specific IGF-I gene-deleted mouse model.

Nutritional status is a critical factor that modulates the responsiveness of the liver to GH and the resulting production of endocrine (mostly liver-derived) IGF-I. Using a conditional Cre/lox P system, we have established a liver-specific IGF-I-deficient mouse model. Despite the reduction in the circulating IGF-I (75%), the growth parameters are normal, except for the reduced spleen size, providing a unique model to study the effect of protein restriction on the autocrine/paracrine GH/IGF-I axis. To determine the effects of protein calorie malnutrition on the spleen, liver-specific IGF-I-deficient mice were assigned to one of four isocaloric diets, differing in the protein content (20, 12, 4, and 0%), for a period of 10 d. A low protein intake decreased the nonhepatic IGF-I secretion into the circulation, whereas it caused an increase in the level of circulating GH. This supports the view that nonhepatic IGF-I production contributes to circulating IGF-I levels. The lack of dietary protein led to an up-regulation of GH and IGF-I receptors expression in the spleen, whereas the IGF-I mRNA remained unchanged, as was demonstrated by flow cytometry and ribonuclease protection assay. B lymphocytes seem to be responsible for the up-regulated GH/IGF-I receptor expression. Northern blot analysis showed an up-regulation of IGF-binding protein-3 mRNA levels, which suggests that the protein deprivation may lead to an increased sequestration of circulating or locally synthesized IGF-I. These results support the hypothesis that the splenic GH/IGF-I axis responds to the nutritional stress caused by a low protein intake, to maintain the tissue homeostasis.

Effects of protein-calorie restriction on mechanical function of hypertrophied cardiac muscle.

To assess the effect of food restriction (FR) on hypertrophied cardiac muscle in spontaneously hypertensive rats (SHR). Isolated papillary muscle preparations of the left ventricle (LV) of 60-day-old SHR and of normotensive Wistar-Kyoto (WKY) rats were studied. The rats were fed either an unrestricted diet or FR diet (50% of the intake of the control diet) for 30 days. The mechanical function of the muscles was evaluated through monitoring isometric and isotonic contractions. FR caused: 1) reduction in the body weight and LV weight of SHR and WKY rats; 2) increase in the time to peak shortening and the time to peak developed tension (DT) in the hypertrophied myocardium of the SHR; 3) diverging changes in the mechanical function of the normal cardiac muscles of WKY rats with reduction in maximum velocity of isotonic shortening and of the time for DT to decrease 50% of its maximum value, and increase of the resting tension and of the rate of tension decline. Short-term FR causes prolongation of the contraction time of hypertrophied muscles and paradoxal changes in mechanical performance of normal cardiac fibers, with worsening of the shortening indices and of the resting tension, and improvement of the isometric relaxation.

Study of the evolution of the placenta and fetal pancreas in the pathophysiology of growth retardation intrauterine due to restricted maternal diet.

Intrauterine growth retard (IUGR) continues to be a significant perinatology problem at the end of this century. The nature of the etiologic agent, the time when the attack occurred during pregnancy and its duration affect the type of IUGR. To study the evolution of fetal pancreas and placenta between the 18th and 21st day of pregnancy in rats submitted to maternal protein-calorie restriction. Randomized controlled trial on laboratory animal. Forty-one normoglycemic pregnant Wistar rats. Rats were divided into six experimental groups according to their access to food and date of cesarean section (18th or 21st day): control with free access to food; diet restricted to 25% introduced on 1st day of pregnancy; and diet restricted to 25% after the 3rd day of pregnancy. Newborn weight, placenta weight, histopathological study (morphological histochemistry). Maternal protein-calorie malnutrition caused intrauterine growth retard (IUGR) after the 18th day of pregnancy. Dietary restriction did not interfere with the morphology of the fetal pancreas and the immunohistochemical study of the placenta showed that glycogen stores were decreased between the 18th and 21st day in the control group and in a diet restricted to 25% from the first day of pregnancy. Dietary restriction after the 3rd day of pregnancy led to low placental glycogen concentrations on the 18th day and disappearance on the 21st day. The pathophysiology of IUGR due to maternal protein-calorie restriction in rats is related to lower placental weight and low placental glycogen stores.

Inherited interstitial nephritis in kdkd mice.

kdkd mice, a mutant subline of CBA/Ca mice, develop a progressive, T cell-mediated, autoimmune interstitial nephritis which leads to renal failure and death of all mice at 20-28 weeks of age. This disease is inherited in an autosomal recessive manner, with complete penetrance, and has been linked to grizzled and waltzer on mouse chromosome 10. Immunologic evaluation of this lesion has demonstrated that histologic disease is initiated by a population of CD8+, H-2Kk-restricted T cells, which recognize an antigen in collagenase-solubilized syngeneic renal tubules. These nephritogenic effector cells can also be demonstrated in non-disease prone CBA/Ca mice. Susceptibility to autoimmune nephritis correlates with distinct expression of regulatory, rather than effector, T cells. Interstitial nephritis in kdkd mice can be inhibited by protein-calorie restriction, infusions of CBA/Ca CD8+ T cells, or monoclonal antibodies of ICAM-1. This murine model most closely resembles medullary cystic disease in humans, which has not historically been considered an autoimmune disease. Mapping of the genes for both medullary cystic disease and the defect in kdkd mice should augment our understanding of mechanisms of organ-specific autoimmunity.

Effects of diabetes and dietary manipulation on rat parotid gland secretory response to sympathetic nerve stimulation

1. 1. The effects of streptozotocin-diabetes, bulk-diet, low protein diet (8%) and protein-calorie malnutrition on parotid gland response to sympathetic nerve stimulation were studied in male Wistar rats. 2. 2. Mean body weights were considerably less in diabetic and protein-calorie malnourished rats than in the other groups, but parotid gland weight was reduced only in animals placed on a low-protein diet. 3. 3. Salivary flow rate (μ1/min/g tissue) and total protein output (mg secreted/g tissue) were reduced in diabetic rats. 4. 4. Salivary composition was altered in diabetes and protein-calorie restriction, and the specifie changes were unique to each condition. 5. 5. Thus, with the possible exception of gland weight the effects of diabetes on parotid gland structure and function are not related to either hyperphagia or nutritional status.