J Obes Metab Syndr 2022; 31(1): 81-85
Published online March 30, 2022 https://doi.org/10.7570/jomes22013
Copyright © Korean Society for the Study of Obesity.
Hyeon Seok Moon1,2, Hanbin Kim1,2, Bohye Kim1,2, Min-Seon Kim3, Jae Hyun Kim4,* , Obin Kwon1,2,*
Departments of 1Biomedical Sciences and 2Biochemistry and Molecular Biology, Seoul National University College of Medicine, Seoul; 3Division of Endocrinology and Metabolism, Department of Internal Medicine, Diabetes Center, Asan Medical Center, University of Ulsan College of Medicine, Seoul; 4Department of Pediatrics, Seoul National University Bundang Hospital, Seongnam, Korea
Department of Biochemistry and Molecular Biology, Seoul National University College of Medicine, 103 Daehak-ro, Jongno-gu, Seoul 03080, Korea
Jae Hyun Kim
Department of Pediatrics, Seoul National University Bundang Hospital, 82 Gumi-ro 173beon-gil, Bundang-gu, Seongnam 13620, Korea
The first two authors contributed equally to this study.
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Background: We aimed to build mouse models of small for gestational age (SGA), recapitulating failure of catch-up growth and dysregulated metabolic outcomes in adulthood.
Methods: Pregnant C57BL/6 mice were given a protein-restricted diet (PRD; 6% kcal from protein) during pregnancy without (model 1) or with cross-fostering (model 2). Model 3 extended the PRD to the end of the lactation period. Model 4 changed to a 9% PRD without cross-fostering.
Results: Model 1 yielded a reduced size of offspring with a poor survival rate. Model 2 improved survival but offspring showed early catch-up growth. Model 3 maintained a reduced size of offspring after weaning with a higher body mass index and blood glucose levels in adult stages. Model 4 increased the survival of the offspring while maintaining a reduced size and dysregulated glucose metabolism.
Conclusion: Models 3 and 4 are suitable for studying SGA accompanying adulthood short stature and metabolic disorders.
Keywords: Small for gestational age, Growth failure, Glucose metabolism disorders, Obesity
Birth weight is a surrogate marker for an adequate intrauterine environment during pregnancy and both extremes could cause various metabolic consequences.1,2 Small for gestational age (SGA) is defined as having a weight at birth below the bottom 10th percentile of the weight standard, a common complication of pregnancy. Maternal undernutrition is a major problem in underdeveloped countries and pregnancy at an advanced maternal age has become more common over the last decades, which all increase the burden of SGA.1 Subjects with SGA are vulnerable to several metabolic diseases in adulthood, including type 2 diabetes and obesity.3 More than 10% of all individuals born SGA do not complete postnatal catch-up growth and retain a short stature. Therefore, they are commonly recommended to receive growth hormone (GH) treatment to improve their adult height.4 As GH acts as a counterregulatory hormone on insulin, a long-term GH treatment in SGA subjects might worsen the risk of diabetes.3
A proper animal model is required for the study of SGA-related adult complications including catch-up growth failure and dysregulated metabolic outcome. In the present study, we attempted to establish a good SGA mouse model by restricting the amount of protein in the maternal diet during pregnancy and the lactation period.
The C57BL/6 mice (8–9 weeks of age) used in this study were purchased from Jackson Laboratories (Bar Harbor, ME, USA). Mice were housed in a temperature- and humidity-controlled environment. Food and water were available
Female mice were allowed to mate during the dark cycle with males. Upon detection of a vaginal plug on the next day, females were placed on either a normal chow diet (NCD; control group, 24.5% kcal from protein with 63.1% kcal from carbohydrate and 12.4% kcal from fat; #38057, Purina Korea, Seoul, Korea) or a protein-restricted diet (PRD; SGA group; 6.0% or 9.0% kcal from protein with 83.8% or 80.8% kcal from carbohydrate, respectively, and with 10.2% kcal from fat; based on #D02041001, Research Diets, New Brunswick, NJ, USA) during pregnancy and/or lactation periods, as described for each model. Afterwards, NCD was provided to both groups and all offspring. If needed, cross-fostering was conducted between 0 and 6 hours after both biological and adoptive dams had given birth. The procedure consisted of removing the biological mother, placing the litter in a clean cage containing bedding of the adoptive mother, and finally placing the adoptive mother in the cage. Pups were weaned at four weeks of age.
In overnight-fasted mice, following an intraperitoneal injection of 2 g of glucose/kg body mass in 20% glucose solution, the blood glucose level was measured at each time point (0, 15, 30, 60, 120 minutes) through a glucometer (Accu-CHEK Performa; Roche Diagnostics, Mannheim, Germany).
In 4-hour-fasted mice, following an intraperitoneal injection of 0.75 IU of Humulin R (Eli Lilly, Indianapolis, IN, USA) per kg body mass, the blood glucose level was measured at each time point (0, 15, 30, 60, 120 minutes).
Data are expressed as the mean±standard error of the mean. The Student t-test was used to compare the groups. Two-way repeated-measures analysis of variance was used for glucose tolerance test (GTT) and insulin tolerance test (ITT) followed by Bonferroni correction. The log-rank test was used for a survival analysis.
Compared to the NCD control, 6% PRD during pregnancy (model 1) yielded a smaller size of offspring, but most of them were lost due to cannibalism or neglect by the dam (Fig. 1). This problem was partially solved by cross-fostering (model 2), but due to catch-up growth, the offspring recovered their body weights and lengths to the levels of the controls during the pre-weaning period (data not shown). Therefore, model 1 and model 2 may not be suitable for the study of SGA.
In model 3, we extended the period of 6% PRD to the lactation period with cross-fostering. The offspring had smaller body sizes at birth and at 3 weeks and 12 weeks old (Fig. 2A-C), successfully recapitulating the phenotype of failure of catch-up growth. Moreover, the offspring displayed a higher body mass index at 12 weeks and increased fasting blood glucose levels at 16 weeks (Fig. 2C and D). Thus, model 3 successfully induced dysregulated glucose metabolism in the adulthood of the offspring here. However, the extended PRD period significantly reduced the long-term survival rate compared to that in model 2 (Fig. 1C). Thus, model 3 may have a disadvantage with regard to obtaining a sufficient number of offspring. To improve the yield, we increased the protein content of PRD to 9% in model 4 and instead omitted cross-fostering. This model significantly increased the long-term survival rate of the offspring, even without cross-fostering (Fig. 1C). Although the degree of reduction in adult body lengths in model 4 was less than in model 3, the offspring were significantly smaller than the NCD controls (Fig. 2E and I). Thus, this model also recapitulated the phenotype of failure of catch-up growth. Moreover, GTT and ITT studies, performed at 16 and 20 weeks, demonstrated glucose intolerance and insulin resistance in model 4 (Fig. 2F-H).
In this study, we developed two mouse models in order to recapitulate the human SGA phenotypes accompanying failure of catch-up growth and dysregulated metabolic outcomes in adulthood; the strength of model 3 lies in its more significant phenotypes, and that of model 4 is in the better yield without cross-fostering.
Adequate delivery of amino acids from mother to fetus throughout placenta is necessary for proper growth and development. Suggested mechanisms of PRD-induced SGA include impaired uterine secretions, impaired cell signaling in mother and fetus, reduced placental angiogenesis with reduced supply of nutrients from mother to fetus, which all contribute to a vicious cycle.5 Previous reports demonstrated other SGA models using PRD, but the body length results were omitted6,7 or strains other than C57BL/6 were evaluated.8 The final two models are relatively non-invasive and easy to perform without special equipment compared to modeling by surgical procedures during pregnancy9 or a cesarean section.6
Known underlying reasons for SGA include intrinsic fetal factors, placental insufficiency, other maternal disorders and even infection.1 Our models cannot recapitulate all of the etiologies of SGA, limiting their utility. If needed, researchers can use more relevant models for specific purposes, such as hypoxia models10 or modeling with other species.11 As the C57BL/6 mouse is the most widely used genetic strain in the field of metabolic research,12 these models can be adopted properly according to the purpose of translational study of each researcher.
The authors declare no conflict of interest.
This study was supported by a grant from the National Research Foundation of Korea (NRF) funded by the Korean Government (NRF-2020R1A4A3078962 to OK), by grant No. 16-2018-010 from the SNUBH research fund (to JHK), by the Creative-Pioneering Researchers Program through Seoul National University (to OK), and by a grant (to OK, 2019F-4) from the Korean Diabetes Association.
Study concept and design: JHK and OK; acquisition of data: HSM and HK; analysis and interpretation of data: HSM, HK, JHK, and OK; drafting of the manuscript: HSM, HK, JHK, and OK; critical revision of the manuscript: BK and MSK; statistical analysis: HSM and OK; obtaining funding: JHK and OK; and study supervision: JHK and OK.
Online ISSN : 2508-7576Print ISSN : 2508-6235
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