Invited review: Pre- and postnatal adipose tissue development in farm animals: from stem cells to adipocyte physiology

Louveau, Isabelle; Perruchot, Marie-Hélène; Bonnet, Muriel; Gondret, Florence

doi:10.1017/s1751731116000872

Cited by 46 publications

(36 citation statements)

References 49 publications

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“…Domestic pig (Sus scrofa) is considered as an attractive large animal model for studies on human obesity in terms of similarities found at the anatomical, physiological, pathological, and genomic levels (Spurlock and Gabler 2008;Stachowiak et al 2016). Knowledge on cellular and molecular mechanisms associated with adipose tissue development is also needed as far as pig production is concerned, since it may affect neonatal survival, postnatal growth efficiency, and health (Louveau et al 2016). Moreover, this species has also been recognized as a model organism for interphase genome organization (Foster et al 2012).…”

Section: Introductionmentioning

confidence: 99%

Nuclear organization during in vitro differentiation of porcine mesenchymal stem cells (MSCs) into adipocytes

Stachecka

Walczak

Kociucka

et al. 2017

Histochem Cell Biol

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for further study, a comparative characteristic of the nuclear organization in BM-MSCs and AD-MSCs was performed. Nuclear substructures were visualized by indirect immunofluorescence (nucleoli, nuclear speckles, PML bodies, lamins, and HP1α) or fluorescence in situ hybridization (telomeres) on fixed cells at 0, 3, 5, and 7 days of differentiation. Comprehensive characterization of these structures, in terms of their number, size, dynamics, and arrangement in three-dimensional space of the nucleus, was performed. It was found that during differentiation of porcine MSCs into adipocytes, changes of nuclear organization occurred and concerned: (1) the nuclear size and shape; (2) reduced lamin A/C expression; and (3) reorganization of chromocenters. Other elements of nuclear architecture such as nucleoli, SC-35 nuclear speckles, and telomeres showed no significant changes when compared to undifferentiated and mature fat cells. In addition, the presence of a low number of PML bodies was characteristic of the studied porcine mesenchymal stem cell adipogenesis system. It has been shown that the arrangement of selected components of nuclear architecture was very similar in MSCs derived from different sources, whereas adipocyte differentiation involves nuclear reorganization. This study adds new data on nuclear organization during adipogenesis using the pig as a model organism.

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Section: Introductionmentioning

confidence: 99%

Nuclear organization during in vitro differentiation of porcine mesenchymal stem cells (MSCs) into adipocytes

Stachecka

Walczak

Kociucka

et al. 2017

Histochem Cell Biol

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“…From a production standpoint, not all the depots have the same value, with the depositing of IM fat, or marbling, being desirable because of its beneficial effects on sensory attributes and hence its decisive role in determining meat quality [21]. In contrast, the accumulation of excess fat in certain depots has an adverse effect by increasing production costs while decreasing product quality [15,22]. For instance, visceral fat is mostly discarded at slaughter, while an excess of SC fat lowers the commercial value of carcasses.…”

Section: Adipose Depots In Domesticated Animalsmentioning

confidence: 99%

“…The adipocytes in white adipose tissue are ordinarily large (in cattle they can reach sizes of up to 180 μm in diameter) [12], and they have few mitochondria, their cytoplasm being almost entirely taken up by a single fat vacuole [13,14]. In addition to its endocrine function, this fatty tissue subtype also plays a structural role, providing mechanical support and protection for certain parts of the body [3,15,16].…”

mentioning

confidence: 99%

Cellularity Description of Adipose Depots in Domesticated Animals

Urrutia¹,

Alfonso²,

Mendizábal³

2018

Adipose Tissue

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Cellularity of adipose tissue in domesticated animals varies not only with species, sex, age and management conditions but also with depot. Differences in depots are important in animal production because of the economic and welfare implications and in humans in relation to obesity. The final amount of fat and its composition depends on the differentiation of mesenchymal multipotent precursor cells into mature adipocytes (adipogenesis) capable of fatty acid and triglyceride synthesis (lipogenesis), both processes being regulated by different key adipogenic and lipogenic genes, some of are well known and have been described. Histologically, differences can be classified as hyperplasia (an increase in adipocyte number) and hypertrophy (an increase in adipocyte size), processes that can produce adipocyte size distributions that are not necessarily Gaussian. A detailed description of the type of adipocyte size distribution can help distinguish the different adipocyte populations within depots and characterise each not only in terms of the size but also the number of the constituting cells. This description can help better understand the development and role of the different depots. It can also help when analysing causal relationships with adipogenic drivers and lipogenic enzymes involved in lipid metabolism.

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“…Thereafter adipose tissue is central to energy metabolism and developmentally programmed alterations in adipose tissue physiology are considered a common phenotypic feature underlying a range of issues that become apparent in postnatal life [3]. In humans these include metabolic, cardiovascular and reproductive disorders [4][5][6], while in meat producing species excess body fat negatively impacts meat quality and hence financial returns to the producer [7,8].…”

Section: Introductionmentioning

confidence: 99%

Ovine prenatal growth-restriction and sex influence fetal adipose tissue phenotype and impact postnatal lipid metabolism and adiposity in vivo from birth until adulthood

Wallace¹,

Milne²,

Aitken³

et al. 2020

PLoS ONE

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Adipose tissue development begins in utero and is a key target of developmental programming. Here the influence of nutritionally-mediated prenatal growth-restriction on perirenal adipose tissue (PAT) gene expression and adipocyte phenotype in late fetal life was investigated in both sexes in an ovine model. Likewise circulating leptin concentrations and non-esterified fatty acid (NEFA) and glycerol responses to glucose challenge were determined in relation to offspring adiposity at key stages from birth to mid-adult life. In both studies' singleton-bearing adolescent sheep were fed control or high nutrient intakes to induce normal or growthrestricted pregnancies, respectively. Fetal growth-restriction at day 130 of gestation (32% lighter) was characterised by greater bodyweight specific PAT mass and higher PAT expression of peroxisome proliferator-activated receptor gamma (PPARɤ), glycerol-3-phosphate dehydrogenase, hormone sensitive lipase (HSL), insulin-like growth factor 1 receptor, and uncoupling protein 1. Independent of prenatal growth, females had a greater bodyweight specific PAT mass, more multilocular adipocytes, higher leptin and lower insulin-like growth factor 1 mRNA than males. Growth-restricted offspring of both sexes (42% lighter at birth) were characterised by higher plasma NEFA concentrations across the life-course (post-fasting and after glucose challenge at 7, 32, 60, 85 and 106 weeks of age) consistent with reduced adipose tissue insulin sensitivity. Circulating plasma leptin correlated with body fat percentage (females>males) and restricted compared with normal females had more body fat and increased abundance of PPARɤ;, HSL, leptin and adiponectin mRNA in PAT at necropsy (109 weeks). Therefore, prenatal nutrient supply and sex both influence adipose tissue development with consequences for lipid metabolism and body composition persisting throughout the life-course.

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Invited review: Pre- and postnatal adipose tissue development in farm animals: from stem cells to adipocyte physiology

Cited by 46 publications

References 49 publications

Nuclear organization during in vitro differentiation of porcine mesenchymal stem cells (MSCs) into adipocytes

Nuclear organization during in vitro differentiation of porcine mesenchymal stem cells (MSCs) into adipocytes

Cellularity Description of Adipose Depots in Domesticated Animals

Ovine prenatal growth-restriction and sex influence fetal adipose tissue phenotype and impact postnatal lipid metabolism and adiposity in vivo from birth until adulthood

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