Analysis of structure and gene expression in developing kidneys of male and female rats exposed to low protein diets in utero

Wood-Bradley, Ryan J; Henry, Sarah; Barrand, Sanna; Giot, Anais; Eipper, Luke; Bertram, John F.; Cullen‐McEwen, Luise A.; Armitage, James A.

doi:10.1002/ar.24417

Cited by 5 publications

(6 citation statements)

References 52 publications

(63 reference statements)

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“…In these models of maternal food restriction, the maternal body weight and thus leptin were reduced, suggesting that leptin may regulate branching morphogenesis via a Gdnf /Ret pathway. Of interest, a previous study has shown that there are sex-specific differences in Gdnf in mice [33], which was not observed in our study in rats. Furthermore, in this study in mice, a maternal low-protein diet did not alter Gdnf mRNA [33].…”

Section: Discussioncontrasting

confidence: 87%

Maternal Diet High in Linoleic Acid Alters Renal Branching Morphogenesis and mTOR/AKT Signalling Genes in Rat Fetal Kidneys

McClelland,

Holland,

Shrestha

et al. 2024

IJMS

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Linoleic acid (LA), an n-6 polyunsaturated fatty acid (PUFA), is obtained from the maternal diet during pregnancy, and is essential for normal fetal growth and development. A maternal high-LA (HLA) diet alters maternal and offspring fatty acids, maternal leptin and male/female ratio at embryonic (E) day 20 (E20). We investigated the effects of an HLA diet on embryonic offspring renal branching morphogenesis, leptin signalling, megalin signalling and angiogenesis gene expression. Female Wistar Kyoto rats were fed low-LA (LLA; 1.44% energy from LA) or high-LA (HLA; 6.21% energy from LA) diets during pregnancy and gestation/lactation. Offspring were sacrificed and mRNA from kidneys was analysed by real-time PCR. Maternal HLA decreased the targets involved in branching morphogenesis Ret and Gdnf in offspring, independent of sex. Furthermore, downstream targets of megalin, namely mTOR, Akt3 and Prkab2, were reduced in offspring from mothers consuming an HLA diet, independent of sex. There was a trend of an increase in the branching morphogenesis target Gfra1 in females (p = 0.0517). These findings suggest that an HLA diet during pregnancy may lead to altered renal function in offspring. Future research should investigate the effects an HLA diet has on offspring kidney function in adolescence and adulthood.

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Section: Discussioncontrasting

confidence: 87%

Maternal Diet High in Linoleic Acid Alters Renal Branching Morphogenesis and mTOR/AKT Signalling Genes in Rat Fetal Kidneys

McClelland,

Holland,

Shrestha

et al. 2024

IJMS

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“…45 This statistical method has been used by various investigators to account for the potential within-litter bias. [46][47][48][49][50][51][52][53] This statistical analysis was used to reduce confounding due to over-representation of a particular litter in the data. Therefore, herein we report findings from an n (litter) of 4-18, which represents between 2 and 79 animals.…”

Section: Discussionmentioning

confidence: 99%

“…Our previous study exploring the impact of maternal protein intake during gestation revealed that at E20 LP offspring were heavier than control offspring. 53 It is unclear whether this result is indicative of a change in gestational length. Therefore, future studies may wish to further explore the role of maternal protein intake on gestational length.…”

Section: Limitation Of Studymentioning

confidence: 99%

Cardiovascular and renal profiles in rat offspring that do not undergo catch-up growth after exposure to maternal protein restriction

Wood-Bradley

Henry

Evans

et al. 2023

J Dev Orig Health Dis

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Maternal protein restriction is often associated with structural and functional sequelae in offspring, particularly affecting growth and renal-cardiovascular function. However, there is little understanding as to whether hypertension and kidney disease occur because of a primary nephron deficit or whether controlling postnatal growth can result in normal renal-cardiovascular phenotypes. To investigate this, female Sprague-Dawley rats were fed either a low-protein (LP, 8.4% protein) or normal-protein (NP, 19.4% protein) diet prior to mating and until offspring were weaned at postnatal day (PN) 21. Offspring were then fed a non ‘growth’ (4.6% fat) which ensured that catch-up growth did not occur. Offspring growth was determined by weight and dual energy X-ray absorptiometry. Nephron number was determined at PN21 using the disector-fractionator method. Kidney function was measured at PN180 and PN360 using clearance methods. Blood pressure was measured at PN360 using radio-telemetry. Body weight was similar at PN1, but by PN21 LP offspring were 39% smaller than controls (Pdiet < 0.001). This difference was due to proportional changes in lean muscle, fat, and bone content. LP offspring remained smaller than NP offspring until PN360. In LP offspring, nephron number was 26% less in males and 17% less in females, than NP controls (Pdiet < 0.0004). Kidney function was similar across dietary groups and sexes at PN180 and PN360. Blood pressure was similar in LP and NP offspring at PN360. These findings suggest that remaining on a slow growth trajectory after exposure to a suboptimal intrauterine environment does not lead to the development of kidney dysfunction and hypertension.

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“…In a rabbit model of maternal hypertension, Monash colleague and collaborator Prof. Kate Denton describes methodologies for the in utero high‐resolution ultrasound assessment of fetal growth trajectories, including helpful assessments of fetal kidney size (Coombs, Walton, Maduwegedera, Flower, & Denton, 2020). Additionally, in a study of maternal low protein diet in rats, collaborator Prof. James Armitage and former PhD student Dr. Ryan Wood‐Bradley add insight to the mechanisms underlying low nephron endowment in affected offspring, showing molecular and structural changes in the fetal kidneys from embryonic day E17.25 (Wood‐Bradley et al, 2020). Notably, members of John's current research team, including research fellow Dr. Luise Cullen‐McEwen, present in this issue the first reported evidence of developmental programming of podocyte endowment (Gonçalves et al, 2020); in a mouse model of maternal hypoxia, low podocyte (and nephron) numbers were evident in male, but not female, offspring, further indicating that renal disease susceptibility may be sex‐specific.…”

Section: Renal Developmental Programmingmentioning

confidence: 99%

Introduction to a special issue on kidney development and disease

Sutherland

2020

The Anatomical Record

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Enriching our understanding of the anatomy of the kidneys, in development, health, and disease, has been the primary focus of Professor John Bertram's distinguished research career to date. Among other notable achievements, his landmark analyses of nephron number in over 400 human kidneys (the Monash Series), and his refinement of stereological techniques for renal structural analyses, have proven him an international leader in renal anatomy research. In this Special Issue, we (some of John's collaborators, colleagues, and former students) celebrate John's career with a series of 20 review and original research articles relevant to his expertise: (a) renal anatomy, physiology, and pathology, (b) kidney development, podocyte biology, and applications of renal stem cells, (c) renal developmental programming, and (d) contemporary methodologies in renal research; his accomplishments as a Head (Chair) of an Anatomy Department are also illustrated. We hope that this collection will serve as both an important resource, and a source of inspiration, to renal anatomy researchers and educators alike.

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Analysis of structure and gene expression in developing kidneys of male and female rats exposed to low protein diets in utero

Cited by 5 publications

References 52 publications

Maternal Diet High in Linoleic Acid Alters Renal Branching Morphogenesis and mTOR/AKT Signalling Genes in Rat Fetal Kidneys

Maternal Diet High in Linoleic Acid Alters Renal Branching Morphogenesis and mTOR/AKT Signalling Genes in Rat Fetal Kidneys

Cardiovascular and renal profiles in rat offspring that do not undergo catch-up growth after exposure to maternal protein restriction

Introduction to a special issue on kidney development and disease

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