The Potential Impact of Animal Science Research on Global Maternal and Child Nutrition and Health: A Landscape Review

Odle, Jack; Jacobi, Sheila K.; Boyd, R. D.; Bauman, Dale E.; Anthony, Russell V.; Bazer, Fuller W.; Lock, A.L.; Serazin, Andrew C.

doi:10.3945/an.116.013896

Cited by 19 publications

(22 citation statements)

References 117 publications

(142 reference statements)

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“…In addition, we have indicated a role for DHA in epigenetic regulation, which adds to current knowledge. Using pigs as an agrimedical model ( 15 ), this experiment has laid a foundation for understanding the implications of maternal nutrient restriction and possible nutrition therapy options for supporting fetal growth and development despite nutritional inadequacy. Because swine are a litter-bearing species, there was an advantage in being able to compare LBW to NBW littermates.…”

Section: Discussionmentioning

confidence: 99%

“…Swine are litter bearing ( 14 , 15 ), and so nutrients delivered to the mother are distributed differently to the fetuses depending on their location along the uterine horn. This causes littermates to develop unique physiologic phenotypes, allowing for assessment of differences influenced specifically by nutritional availability, while minimizing differences influenced by genetics.…”

Section: Introductionmentioning

confidence: 99%

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Supplementation of Maternal Diets with Docosahexaenoic Acid and Methylating Vitamins Impacts Growth and Development of Fetuses from Malnourished Gilts

Lima

Lin

Jacobi

et al. 2018

Current Developments in Nutrition

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BackgroundLike many species, pregnant swine mobilize and repartition body nutrient stores during extreme malnutrition to support fetal development.ObjectiveThe objective of this study was to model chronic human maternal malnutrition and measure effects of methylating-vitamins (MVs, containing choline, folate, B-6, B-12, and riboflavin) and docosahexaenoic acid (DHA) supplementation on fetal growth and development.MethodsPregnant gilts (n = 24) were either fully nourished (2.0 kg/d) with a corn-plus-isolated-soy-protein basal diet (control) supplemented with MVs and DHA or nourishment was restricted throughout gestation. Basal diet fed to malnourished gilts was reduced progressively from 50% to 70% restriction (1.0 to 0.6 kg/d) and was supplemented following a 2 (±MVs) x 2 (±DHA) factorial design. Full-term c-sections were performed to assess impacts on low and normal birth weight (LBW/NBW) fetuses (n = 238).ResultsBody weight gain of malnourished gilts was 10% of full-fed control dams (P < 0.05), but offspring birth weight, length, girth, and percentage of LBW fetuses were not different between treatments. The number of pigs per litter was reduced by 30% in malnourished control dams. Fetal brain weights were reduced by 7% compared to positive controls (P < 0.05). Micronutrient supplementation to malnourished dams increased fetal brain weights back to full-fed control levels. Dams with DHA produced offspring with higher DHA concentrations in brain and liver (P < 0.05). Plasma choline concentration was 4-fold higher in fetuses from unsupplemented malnourished dams (P < 0.0001). Global DNA methylation status of fetuses from restricted dams was higher than in control fetuses, including brain, liver, heart, muscle, and placenta tissues (P < 0.05). Addition of DHA increased methylation in LBW fetal brains (P < 0.05).ConclusionsDespite the mobilization of maternal stores, malnourished litters displayed reduced brain development that was fully mitigated by micronutrient supplementation. Severe maternal malnutrition increased global DNA methylation in several fetal tissues that was unaltered by choline and B-vitamin supplementation.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Supplementation of Maternal Diets with Docosahexaenoic Acid and Methylating Vitamins Impacts Growth and Development of Fetuses from Malnourished Gilts

Lima

Lin

Jacobi

et al. 2018

Current Developments in Nutrition

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“…During pregnancy, adequate protein intake is recommended to ensure that the additional nitrogen demands of both mother and fetus are met since an increase in protein turnover to meet the requirements for rapid embryo growth occurs at this stage [9]. Based on these findings, the protein restriction model is one of the most well-characterized models of early growth restriction [6,10,11].…”

Section: Introductionmentioning

confidence: 99%

Maternal Protein Restriction Differentially Alters the Expression of AQP1, AQP9 and VEGFr-2 in the Epididymis of Rat Offspring

Cavariani

Santos

Pereira

et al. 2019

IJMS

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Background: Maternal protein restriction causes sperm alterations in the offspring, most of which are associated with epididymal functions. Because fluid reabsorption/secretion dynamics in the epididymal environment play important roles in the process of sperm maturation and concentration, we investigated the effects of maternal protein restriction on the expression of aquaporins (AQP1 and AQP9), vascular endothelial growth factor (VEGFa), and its receptor VEGFr-2 in different stages of postnatal epididymal development. Methods: Pregnant rats were divided into groups that received normoprotein (17% protein) and low-protein diets (6% protein) during gestation and lactation. After weaning, male rats only received the standard diet and were euthanized at the predetermined ages of 21, 44 and 120 days. Results: Maternal protein restriction decreased AQP1 and AQP9 expression in the initial segment and caput epididymis compared to the increased expression of these proteins observed in the corpus and cauda at all ages. Although protein restriction reduced the microvasculature density (MVD) on postnatal day (PND) 21 and 44, the MVD was unaltered on PND 120. Conclusions: Maternal protein restriction changed the structure or function of the offspring’s epididymis, specifically by affecting fluid dynamics and vasculogenesis in important stages of epididymis development.

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“…Myostatin has been recognized as the only negative regulator of muscle growth and development in animals, since Mcpherron et al (1997) firstly reported the mutagenic effect of Myostatin gene (or MSTN) in cattle. Myostatin has been identified as a negative regulator of skeletal muscle mass and inactivating mutations in the MSTN gene are responsible for the development of a hypermuscular phenotype, because Myostatin(−/−) mutant mice exhibit a generally and significantly increased skeletal muscle mass in which muscle atrophy occurs (Mcpherron et al, 1997;Kawada et al, 2001;Mcfarlane et al, 2006;Chelh et al, 2009), Myostatin is also regarded to play important roles in the maintenance of muscle homeostasis and regeneration (Mcpherron et al, 1997;Kawada et al, 2001;Mcfarlane et al, 2006;Chelh et al, 2009;Odle et al, 2017;Rossi et al, 2016). If Myostatin is knocked out in laboratory animals, the animal mutation would affect both the growth and development of adipose tissues and skeletal muscle tissues.…”

Section: Myostatinmentioning

confidence: 99%

“…Furthermore, the genetic regulation of myogenesis and muscular development and growth of animal muscle tissues is a highly complex and comprehensive successive process, which is affected by many genetic and physiological and environmental influencing factors, such as the genotype and/or haplotype and gender of animal species and/or strains (genetics), endocrine status (physiology), dietary feed level (nutrition), living and feeding environment and other internal and external factors. The effects of genetics and physiology and nutrition and other factors on the growth and development of animal muscle mass are finally implemented through the functional integration of myogenic regulatory factors and their receptors (Odle et al, 2017;Rossi et al, 2016). Fig.…”

Section: Introductionmentioning

confidence: 99%

A Review on the Genetic Regulation of Myogenesis and Muscle Development

Liu¹

2019

American Journal of Biochemistry and Biotechnology

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Myogenesis of muscle tissues is known as a very complex and delicate process including many cellular differentiation and development events in animals. Here, the courses of cellular fate determination and terminal differentiation of muscle cells are systematically elaborated and the genetic regulatory network of muscle genesis is well conceived in animal organic growth and development through literature retrieval. Furthermore, the principal roles of myogenic regulatory factors, Myostatin, fibroblast growth factor, insulin-like growth factor and other muscular regulatory factors interrelated and reported in the myogenesis relevant studies are also reviewed. In addition, the interactions of these muscular specific factors and their possible relevant regulative pathways and interactions among them are included and developed too.

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The Potential Impact of Animal Science Research on Global Maternal and Child Nutrition and Health: A Landscape Review

Cited by 19 publications

References 117 publications

Supplementation of Maternal Diets with Docosahexaenoic Acid and Methylating Vitamins Impacts Growth and Development of Fetuses from Malnourished Gilts

Supplementation of Maternal Diets with Docosahexaenoic Acid and Methylating Vitamins Impacts Growth and Development of Fetuses from Malnourished Gilts

Maternal Protein Restriction Differentially Alters the Expression of AQP1, AQP9 and VEGFr-2 in the Epididymis of Rat Offspring

A Review on the Genetic Regulation of Myogenesis and Muscle Development

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