SummaryMalnutrition continues to be a major public health problem throughout the developing world. Nutritional deficiencies may be the most common cause of secondary immunodeficiency states in humans. It has been suggested that nutritional imbalances can induce apoptosis in a variety of cell types. The purpose of this study was to examine the effect of severe malnutrition on cell subsets and the frequency of spontaneous and/or dexamethasone-induced cell death in vivo in the thymus and spleen from severely malnourished, lactating rats. Apoptosis frequency was estimated by flow cytometry using annexin-V and terminal transferase-mediated dUTP nick-end labelling assay assays. The results obtained in the present study indicate that malnutrition is associated with a significant increase of spontaneously apoptotic cells in the thymus (9·8-fold) and spleen (2·4-fold). Increase in apoptosis was associated largely with CD4 + CD8 + double-positive thymocytes. Unexpectedly, similar frequencies of spontaneous apoptosis of these cells were found in both wellnourished and malnourished rats. In contrast, consistent increases in the apoptosis of CD4 -CD8 -double-negative thymocytes were observed in malnourished rats. In addition, single-positive CD8+ and single-positive CD4 + thymocytes had higher frequencies of apoptosis in malnourished rats. The frequency of total dexamethasone-induced apoptosis was found to be similar in both groups of animals. Nevertheless, in malnourished dexamethasonetreated animals, the percentage of apoptotic double-negative thymocytes was significantly higher than in well-nourished animals, while the rate of apoptosis was lower among double-positive cells. In general, the thymus appears more sensitive to the effects of malnutrition and dexamethasone than the spleen. Furthermore, double-negative thymocytes appear to be the most affected.Keywords: apoptosis, cell death, lymphoid atrophy, malnourished, spleen, thymus
SUMMARYThe aim of this study was to determine if the distribution in vivo of CD4 1 CD45RA 1 /CD45RO 2 (naive), CD4 1 CD45RA 1 /CD45RO 1 (Ddull) and CD4 1 CD45RO 1 (memory) lymphocytes differs in malnourished infected and well-nourished infected children. The expression of CD45RA (naive) and CD45RO (memory) antigens on CD4 1 lymphocytes was analysed by flow cytometry in a prospectively followed cohort of 15 malnourished infected, 12 well-nourished infected and 10 well-nourished uninfected children. Malnourished infected children showed higher fractions of Ddull cells (11´4^0´7%) and lower fractions of memory cells (20´3^1´7%) than the well-nourished infected group (8´8^0´8 and 28´1^1´8%, respectively). Well-nourished infected children showed increased percentages of memory cells, an expected response to infection. Impairment of the transition switch to the CD45 isoforms in malnourished children may explain these findings, and may be one of the mechanisms involved in immunodeficiency in these children.
SummaryThe mechanisms involved in impaired immunity in malnourished children are not well understood. T cells in MNI children may represent an ineffective response to infection. Levels of effector T cells in children with gastrointestinal infections versus those suffering from respiratory infections were also significantly different within the WNI group. While WNI children with gastrointestinal infections had higher absolute and relative values of CD8+ , and CD8 + CD28 -T subsets, by those with respiratory infections had higher values of CD4 + lymphocytes. However, due to the small number of subjects examined, our results in WNI children should be interpreted with caution and confirmed using a larger sample size. Our data suggest that altered expression of CD62L and CD28 receptors may contribute to impaired T cell function observed in MNI children.
The aim of this study was to assess DNA repair capacity in lymphocytes of children with protein calorie malnutrition using the single-cell gel electrophoresis (comet) assay. Repair capacity was assessed by estimating the relative decrease of DNA migration length 5, 15, 30, and 60 min after hydrogen peroxide treatment, in three groups of children: well-nourished (WN), well-nourished infected (WN-I), and malnourished infected (MN-I). In addition, the DNA migration length was evaluated in all groups before and after peroxide treatment. Comparison of mean migration lengths observed in WN and WN-I children showed significant differences at all times tested; between WN-I and MN-I differences were also observed, except after hydrogen peroxide exposure. This implies that lymphocytes of WN-I and MN-I children were equally sensitive to hydrogen peroxide. Nevertheless, the MN-I group clearly shows the greatest overall percentage of damaged cells at all times tested. In relation to repair capacity, at 5 min it was approximately 30% in both groups of well-nourished children, but only 20% in MN-I; 15 min after exposure, repair capacity increased to 51% in well-nourished children but only to 31% in MN-I; and at 60 min this capacity increased to 82% in well-nourished but only to 55% in MN-I. These data indicate that lymphocytes of malnourished children show a decreased capacity to repair hydrogen peroxide-induced DNA damage compared to that of well-nourished controls. This reflects that only malnutrition is associated with decreased DNA repair capacity. Additionally, the data confirm that severe infection and malnutrition are two factors clearly associated with increased DNA damage.
Severe malnutrition is widely distributed throughout the world and exhibits a high prevalence in developing countries. Experimental malnutrition models have been useful to study the effects of malnutrition at early ages. The purpose of this study was to determine if severe malnutrition induced during lactation in rats increases DNA damage in spleen, peripheral blood, and bone marrow cells, as well as in isolated lymphocytes or lymphoid cells from the same tissues. These cells were obtained from malnourished rats at weaning (21 days of age). DNA damage was estimated by using the alkaline single cell electrophoresis assay. The results obtained in this study indicate that malnutrition is associated with a significant increase in DNA damage in all cell types that were studied in malnourished rats. The analysis of the length of DNA migration and dispersion coefficient showed that some cell types were more susceptible to DNA damage related with malnutrition. The damage observed could be due to the deficiency of several essential nutrients required for protein synthesis that are associated with DNA integrity, impaired DNA repair mechanisms, and/or to the unavailability of molecules necessary to protect the cells against DNA oxidative damage. This damage may produce negative effects for the further development of the organism, since bone marrow is the main site of hematopoiesis and spleen is an important lymphopoietic organ. Also, the increased level of DNA damage in peripheral blood lymphocytes and leukocytes could be related to negative effects such as a deficient immune response.
Severe malnutrition caused by deficiencies in protein, calorie, and micronutrient intake is widely distributed throughout the world and is a particular problem in developing countries. Animal models have been useful for studying the effects of malnutrition under different experimental conditions. In this study, we have evaluated the effect of malnutrition on the frequency of spontaneous and mitomycin C (MMC)-induced micronuclei in the peripheral blood of rats measured using a flow cytometric analysis technique. Neonatal rats were experimentally malnourished during lactation and assayed at weaning (21 days of age). The malnourished rats weighed 49.2% less than well-nourished controls and had lower concentrations of serum protein, triglycerides, and cholesterol. In rats not treated with MMC, the frequency of micronucleated reticulocytes (MN-RETs) was 1.6 times greater in malnourished rats than in well-nourished rats (0.48% +/- 0.16% vs. 0.31% +/- 0.09%). The mean MN-RET frequency measured 32 hr after treatment with single i.p. doses of 0.5, 0.75, or 1.0 mg/kg of MMC was 0.60 +/- 0.10 vs. 0.84 +/- 0.14, 1.21 +/- 0.52 vs. 2.36 +/- 0.47, and 2.50 +/- 0.06 vs. 4.64 +/- 1.14 for well-nourished vs. malnourished rats, respectively. Statistical comparisons indicate significant differences between the two groups of rats at all doses tested. Malnourishment and MMC treatment had no significant effects on the frequencies of RETs or micronucleated normochromatic erythrocytes. The data indicate that protein-calorie malnutrition during lactation is associated with increased frequencies of MN-RETs, which are indicative of chromosome damage. These findings suggest that malnutrition could result in greater susceptibility to environmental damage.
The purpose of this ex vivo study was to determine if severe malnutrition increases the frequency of micronuclei in spleen lymphocytes of experimentally malnourished rats during lactation. Micronucleus frequencies were analyzed in binucleate cells produced by the cytokinesis block method. The overall micronucleus frequency was significantly higher in binucleate cells from malnourished rats (21.30/1000) as compared to that observed in control rats (11.50/1000). The number of binucleate cells with more than one micronucleus was also higher in malnourished rats than in controls (3.10/1000 vs. 1.20/1000). These results indicate that severe malnutrition produces cellular damage in vivo, as was evidenced by the increased micronucleus frequency in rat spleen lymphocytes in vitro. This damage may produce negative effects for the further development of the organism, since the spleen is an important lymphopoietic organ in rodents.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.