The histology of developing porcine adipose tissue

At each of the following days after conception (45, 60, 75, 90 and 105), pig fetuses were removed from sows representing lean and fat stains. From two additional litters, postnatal pigs were sacrificed at 1, 3, 6, 9, 12, 15, 18 and 21 d. Pelikan dye was injected into fetuses and pigs. The whole of the dorsal subcutaneous tissue, including some underlying muscle, was removed. Tissue was fixed into paraffin blocks or was frozen. Paraffin and frozen sections were stained and examined for stromal-vascular and cellular changes during growth. Organized stromal-vascular changes occurred during a period of adipocyte formation from 45 d gestation until 9 d postnatally. At 45 d gestation, the subcutaneous tissue contained many short unorganized connective tissue fibers. Gradually, these fibers became more organized in a ventral to dorsal and caudal to cranial gradient, so that by 1 d postnatally, they formed complete lobules around all existing fat cell clusters. The presumptive adipose space of the complete lobules contained delicate strands of connective tissue and reacted metachromatically for mucin. Connective tissue around lobules became progressively thinner throughout the remaining postnatal ages. Vascularity of the subcutaneous tissue increased as the stromal became organized. Lipid was not present in the subcutaneous tissue at 45 d gestation, but some deposition was apparent in the inner layer at 60 d. Between 60 d gestation and 9 d postnatally, fat cells filled both subcutaneous layers in a ventral to dorsal formation. Presumptive adipose lobules were the source of adipocytes and capillaries of developing fat cell clusters. Adipocytes from fetuses through 1-d postnatal pigs were multilocular, while unilocular fat cells were first observed at 3 d. At 9 d, multilocular adipocytes were found singly or in groups within unilocular fat cell lobules.     

Cellular and enzyme-histochemical aspects of adipose tissue development in obese (Ossabaw) and lean (crossbred) pig fetuses: an ontogeny study

The cellular and enzyme-histochemical differentiation of subcutaneous adipose tissue was studied in lean and obese pig fetuses at several ages. Positive reactions for a variety of cytosolic and organellar enzyme markers indicate metabolic competence of fetal adipocytes despite their small size (12 to 15 microns). Reactions for several enzymes decreased with fetal age and may be associated with a qualitative change in activity of adipocyte organelles. Age-associated increases in two lipogenic enzymes were observed in obese adipocytes. Observations on developing cells around hair follicles in the younger fetuses indicated significant temporal lags between the appearance of detectable enzyme activities in adipocytes. Enzyme activities in order of appearance were: dehydrogenases (cytosolic and mitochondrial), lipoprotein lipase and esterase. Esterase activity and several other enzymes were never observed in lipid positive cells that were not spherical. A proportion of hair follicle associated adipocytes in 110-d-old lean fetuses were histochemically and morphologically similar to brown adipocytes in the young rat. There was no evidence for brown adipocyte like cells in obese fetuses. Finally, comparison of the enzyme-histochemical differentiation of lean and obese fetal adipocytes indicates that fetal adipocytes become sensitive to external stimuli between 70 and 90 d of gestation.     

The interaction of hydrocortisone and thyroxine during fetal adipose tissue differentiation: CCAAT enhancing binding protein expression and capillary cytodifferentiation.

Late-term fetal pigs from genetically obese dams have elevated levels of thyroid hormones and glucocorticoids, depressed levels of GH, larger fat cells and elevated lipogenesis than do fetal pigs from lean dams. We investigated the influence of elevated levels of thyroid hormones and glucocorticoids per se on adipose tissue traits by chronically treating hypophysectomized (hypox; d 70) fetal pigs between d 90 and 105 of gestation with either thyroxine (T4), hydrocortisone (HC), or the combination of T4 + HC. Treatment with T4 and T4 + HC increased serum T4 and IGF-I levels and enhanced skin and hair development. Treatment with HC and T4 + HC increased serum HC levels, fat cell size, and inner subcutaneous adipose tissue thickness. Quantitative analysis of stained adipose tissue sections indicated that T4 + HC treatment increased lipid accretion and fat cell cluster development more than did either hormone alone. The T4 + HC markedly increased apparent fat cell number, because there was only a 19% increase in fat cell size. A hypox-induced deficit in cytodifferentiation of capillaries associated with adipocytes was not influenced by T4, but was partially normalized by treatment with HC and T4 + HC. Immunocytochemical and Western blot analyses showed no influence of hormonal treatment on expression of three CCAAT enhancing binding protein (C/EBP) isoforms. However, expression of C/EBPdelta in adipose tissue was markedly reduced in control fetal pigs compared with hypox fetal pigs. These studies indicate that concurrent action of glucocorticoids and thyroid hormones may be the critical aspect of endocrine regulation of fetal adipogenesis.     

Maternal obesity upregulates fatty acid and glucose transporters and increases expression of enzymes mediating fatty acid biosynthesis in fetal adipose tissue depots

Maternal nutrient restriction leads to alteration in fetal adipose tissue, and offspring from obese mothers have an increased risk of developing obesity. We hypothesized that maternal obesity increases fetal adipogenesis. Multiparous ewes (Columbia/Rambouillet cross 3 to 5 yr of age) carrying twins were assigned to a diet of 100% (Control; CON; n = 4) or 150% (Obese; OB, n = 7) of NRC maintenance requirements from 60 d before conception until necropsy on d 135 of gestation. Maternal and fetal plasma were collected and stored at -80°C for glucose and hormone analyses. Fetal measurements were made at necropsy, and perirenal, pericardial, and subcutaneous adipose tissues were collected from 7 male twin fetuses per group and snap frozen at -80°C. Protein and mRNA expression of fatty acid translocase [cluster of differentiation (CD) 36], fatty acid transport proteins (FATP) 1 and 4, insulin-sensitive glucose transporter (GLUT-4), fatty acid synthase (FASN), and acetyl-coA carboxylase (ACC) was evaluated. Fetal weight was similar, but fetal carcass weight (FCW) was reduced (P < 0.05) in OB versus CON fetuses. Pericardial and perirenal adipose tissue weights were increased (P < 0.05) as a percentage of FCW in OB versus CON fetuses, as was subcutaneous fat thickness (P < 0.001). Average adipocyte diameter was greater (P < 0.01) in the perirenal fat and the pericardial fat (P = 0.06) in OB fetuses compared with CON fetuses. Maternal plasma showed no difference (P > 0.05) in glucose or other hormones, fetal plasma glucose was similar (P = 0.42), and cortisol, IGF-1, and thyroxine were reduced (P ≤ 0.05) in OB fetuses compared with CON fetuses. Protein and mRNA expression of CD 36, FATP 1 and 4, and GLUT-4 were increased (P ≤ 0.05) in all fetal adipose depots in OB versus CON fetuses. The mRNA expression of FASN and ACC was increased (P < 0.05) in OB vs. CON fetuses in all 3 fetal adipose tissue depots. Fatty acid concentrations were increased (P = 0.01) in the perirenal depot of OB versus CON fetuses, and specific fatty acid concentrations were altered (P < 0.05) in subcutaneous and pericardial adipose tissue because of maternal obesity. In conclusion, maternal obesity was associated with increased fetal adiposity, increased fatty acid and glucose transporters, and increased expression of enzymes mediating fatty acid biosynthesis in adipose depots. These alterations, if maintained into the postnatal period, could predispose the offspring to later obesity and metabolic disease.     

Sera-controlled preadipocyte growth in culture: an ontogeny study with sera from lean and obese pigs

Genetically lean and obese swine were used to investigate the control of preadipocyte growth in culture by porcine serum. Sera were collected from fetuses from obese and lean strains at 70, 90 and 110 d of gestation. Postnatal serum samples were collected from both lines of pigs at 23 to 27 kg. Rat preadipocytes were isolated and grown in culture. Preadipocyte and stromal-vascular cell proliferation was greater in cultures grown in sera obtained postnatally than in cultures grown in sera from fetuses. Sera from lean and obese fetuses were equipotent in promoting cell proliferation. Glycerol-phosphate dehydrogenase (GPDH) activity was higher in cultures fed serum from obese pigs and fetuses than in cultures fed serum from lean pigs and fetuses. Cultures grown in serum from obese fetuses and pigs had soluble protein levels similar to cultures grown with serum from lean pigs and fetuses. These results demonstrate that serum from genetically obese swine, in the pre-obese (fetal) and obese (postnatal) state, caused increased adipogenic activity in adipocytes in culture.     

The development of the inner layer of backfat in fetal and young pigs

The development of the innermost layer of backfat was studied histologically and histochemically in fetuses from Yorkshire sows at 45, 60, 65, 75, 85, 90, 105, 110, and 112 d of gestation. Samples were also obtained from fetuses at 110 d of gestation from Ossabaw sows and from sows selected for high (obese) or low (lead) backfat thickness. Fetuses from some sows were decapitated at 45 d of gestation and samples were obtained from these fetuses at 110 d of gestation. The inner layer develops before 75 d of gestation and has stromal-vascular characteristics that clearly distinguish it from the middle layer of backfat. For instance, a well organized and dense collagen matrix immediately surrounds small fat cell clusters in the inner layer. Most fat cell cluster capillaries (in the inner layer) reacted strongly for ATPase histochemically and are histologically immature. The inner layer morphology and cell size was similar in Ossabaw, obese and lean fetuses. The number of PAS (Periodic Acid Schiff) positive cells were dependent on fetal strain. The number was highest in obese fetuses and lowest in Ossabaws. Comparison of decapitated fetuses and weight-matched controls indicated that the inner layer was most affected by decapitation. A decreased organization and amount of collagen was associated with larger fat cell clusters in decapitated fetuses, and most fat cell cluster capillaries reacted little for ATPase histochemically and were histologically mature. The range in inner-layer fat cell diameter was wider in decapitated fetuses (11 to 55 micron) than in control fetuses (11 to 30 micron). These results demonstrate that the characteristics of the inner layer are clearly different from the other layers and that the amount and organization of collagen was inversely associated with the size of fat cell clusters and fat cells and with the maturity of the adipocyte-associated capillaries.     

Lipogenesis and pancreatic insulin release in fetal pigs

Body composition, liver and adipose lipogenesis, and pancreatic insulin release were examined in intact and decapitated fetal pigs on d 110 of gestation. Decapitation was on d 45 of gestation. Decapitated fetuses deposited more body lipid and less body ash compared with intact fetuses. Body weight, water, dry matter and protein remained similar in intact and decapitated fetuses. Hepatic fatty acid esterification and synthesis were two- and threefold greater, respectively, in decapitated than in intact fetuses. Fatty acid synthesis in subcutaneous adipose tissue of decapitated fetuses was three times greater than values obtained in intact fetuses. The data supported the concept that substrate availability from the dam was not the rate-limiting step in fetal pig lipid synthesis and storage. High growth hormone levels in normal fetal pigs may be responsible for inhibiting lipogenesis, while fetal decapitation would remove this inhibition and be associated with greater lipid deposition. However, pancreatic insulin release was greater in decapitated than in intact fetuses; an indication that elevated lipid deposition may also be due to greater fetal insulin secretion.     

Glycerolipid biosynthesis in porcine adipose tissue in vitro: effect of adiposity and depot site

To compare genetic differences in glycerolipid biosynthesis, rates were determined in s.c. adipose tissue of lean and obese pigs at 28, 60 and 110 d of age. To compare depot-specific differences, glycerolipid biosynthetic rates were determined in outer s.c., middle s.c., perirenal and omental adipose tissues obtained from 105-kg contemporary pigs. Rates were determined with a 700 x g infranatant fraction of an adipose tissue homogenate by measuring glycerophosphate incorporation into total lipids (mostly phosphatidic acid) during 4 min. This assay represents entrance of substrates into the glycerolipid synthesis pathway or glycerophosphate acyltransferase (GPAT) activity. Rates measured for 60 min represent maximal synthesis of glycerolipid (more triacylglycerol than phosphatidic acid) or lipid synthesis capacity (LSC). Adipocyte diameter and volume were greater for adipose tissue of obese than of lean pigs both at 60 and 110 d. When expressed per cell, activity of GPAT and LSC were similar for lean and obese pigs at 28 d. At 60 d and 110 d, LSC was greater for obese than for lean pigs; GPAT activity was greater at 60 but not at 110 d in obese than in lean pigs. Expressed on a cell basis, GPAT activity was highest in omental and outer s.c., intermediate in perirenal and lowest in middle s.c. adipose tissue depots. Lipid synthesis capacity was highest in perirenal and lowest in outer and middle s.c. depots. Our results indicate that the LSC assay was more closely related to the accretion of fat in vivo than to GPAT activity.     

Adipocyte development in primary rat cell cultures, effect of cell density and serum source

The development of adipocytes was studied in primary cultures of rat adipose tissue stromal-vascular cells on collagen-coated glass coverslips. The effects of cell density and serum source on lipoprotein lipase (LPL), esterase and lipid histochemistry were evaluated. With a mixture of fetal calf serum (FCS; 2%), horse serum (2%) and pig serum (PS; 10%), large and loosely arranged clusters of adipocytes developed with time through an increase in cell number and size. An inverse relationship was observed between cell size and the number of adipocytes in a cluster. Lower cell densities were associated with large cells and the densest areas contained smaller cells. Unilocular adipocytes were observed by d 13 after plating and were generally absent from the densest area of the coverslips. Histochemically detectable LPL activity was demonstrable before lipid deposition in adipocyte clusters. A comparison of FCS (10%) and PS (10%) as the only serum sources indicated higher level of adipocyte esterase activity and lipid deposition in PS cultures. Cultures of cells from weanling (21 to 28 d old) and old (18 mo) rats were similar, whereas cells from younger rats (2 to 4 d old) formed denser cultures that contained fewer adipocytes. These adipocytes were small (less than 30 micron) and morphologically homogeneous (all multilocular). When cells from the very young rats (2 to 4 d old) were plated at low densities, an inverse relationship between cell size and number of cells in a cluster was also observed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sera from pigs infected with Sarcocystis suicanis and cachectin decrease preadipocyte differentiation in primary cell culture

The macrophage-secreted hormone cachectin depressed lipoprotein lipase activity and lipogenic enzymes in adipose cells. Cachectin reduced differentiation of preadipocytes in cultures of stromal-vascular cells from rat adipose tissue. Differentiation was measured by two methods of estimating lipid accumulation. Adipocytes were separated from the stromal-vascular cells by centrifugation and staining (oil red 0) for intracellular lipid. Lipolytic activity was measured by using esterase histochemistry. Sera from pigs that were infected with Sarcocystis suicanis showed cachectin-like activity compared with sera collected from the same animals before infection. Cachectin and sera collected from infected animals specifically decreased fat cell number without decreasing the stromal-vascular cell number.     

Fat depot‐specific effects of body fat distribution and adipocyte size on intramuscular fat accumulation in Wagyu cattle

Ectopic fats have been recognized as a new risk factor for metabolic syndrome. In obese humans, ectopic fat accumulations are affected by body fat distribution. Intramuscular adipose tissue is categorized as one of the ectopic fats. Japanese black cattle (Wagyu) are characterized by the ability to accumulate high amounts of intramuscular adipose tissue. In Japan, the marbling level is indicated by the beef marbling standard number (BMS No.), which reflects the intramuscular fat content of longissimus muscle. We hypothesized that the intramuscular fat accumulation is affected by the body fat distribution in Wagyu cattle. In this study, we showed that the BMS No. was not correlated with the subcutaneous and visceral adipocyte diameter. In contrast, the BMS No. was positively correlated with intramuscular adipocyte diameter. These results indicate that the intramuscular adipocyte diameter of Wagyu is hypertrophied with an increase in the intramuscular fat accumulation. In addition, we showed that the BMS No. was positively correlated with the subcutaneous fat percentage. In contrast, the BMS No. was negatively correlated with the visceral fat percentage. These results indicate that highly marbled Wagyu cattle have a higher percentage of subcutaneous fat and a lower percentage of visceral fat.     

Fetal hypophysectomy causes a decrease in preadipocyte growth and insulin like growth factor-1 in pigs

Fetal pigs in one uterine horn of each of five gilts were hypophysectomized (HX) in utero by electrical cauterization at 72-74 days of gestation and sera collected at 110 days of gestation. Sera from HX fetuses had lower levels of insulin-like growth factor-1 compared to control littermates (P less than .05). Sera were tested for their effects on primary cultures of stromal-vascular cells from adipose tissue. The soluble protein concentration/dish was lower when pig cells were cultured in sera from HX fetuses compared to sera from control fetuses (P less than .01). Sera from HX fetuses inadequately supported growth of stromal-vascular cells so subsequent experiments utilized pooled sera from normal and HX adult pigs. Sera from HX and control fetuses were mixed with sera from the two adult pools and tested for incorporation of tritiated thymidine into rat preadipocytes and the appearance of adipocytes (determined histochemically) in pig stromal-vascular cultures. In cultures fed sera from HX fetuses there was a lower (P less than .05) number of pig fat cells/culture and a lower level (P less than .06) of preadipocyte proliferation in rat cell cultures when compared to control fetal sera. Fetal pig serum contains factors (adipogenic) which promote the proliferation and differentiation of adipocytes in culture. Serum from HX fetuses has a lower level of adipogenic factors.     

Adipose tissue lipolytic rate in genetically obese and lean swine

In vitro lipolytic rate was determined in adipose tissue from genetically obese and lean pigs. There were about 20 pigs/genetic strain at 25 and 80 kg and 10 pigs/strain at 50 kg body weight. When expressed on a cellular basis, the in vitro adipose tissue basal (no exogenous hormone) lipolytic rate was similar in obese and lean pigs at 25 and 50 kg body weight. At 80 kg body weight the basal rate was greater in obese than in lean pigs. The in vitro adipose tissue epinephrine-stimulated lipolytic rate expressed on a cell basis was greater at 25 kg, was similar at 50 kg body weight and tended (P less than or equal to .1) to be greater at 80 kg in obese compared with lean pigs. The in vitro sensitivity of lipolysis to epinephrine was slightly greater in lean compared with obese pigs. The data obtained in vitro indicate that obese pigs do not have low adipose tissue lipolytic rates compared with lean pigs. Consequently, adipose tissue lipolysis does not appear to be a major metabolic factor leading to the excessive fat accretion in these obese pigs.     

Influence of maternal obesity on fetal development in pigs

Fetuses from linebred lean (L) and linebred obese (O) and reciprocal crossmatings were examined at 110 d of gestation for line, maternal and heterotic effects. There was no significant heterotic effect for any trait measured. A significant maternal effect was observed for adipose tissue lipoprotein lipase (LPL) activity and for serum triglycerides. The enzyme activity and triglycerides concentration were higher in fetuses from O dams than in fetuses from L dams. In a lipid clearance test, no maternal effect was observed for changes in serum concentrations of triglycerides and free fatty acids or in optical density (associated with the disappearance of injected Liposyn). Linebred O fetuses exhibited higher LPL activity in both the biceps femoris muscle and sc adipose tissue compared with linebred L fetuses. The LPL activity of the adipose tissue was higher than that of the skeletal muscle. The percentage of dry matter, percentage of triglycerides and protein/DNA were higher in the muscle of linebred O fetuses than in that of linebred L fetuses. Based on tissue LPL activity and on muscle compositional traits, linebred O fetuses were more mature at 110 d of gestation than were the linebred L fetuses. Maternal obesity had little detectable influence on fetal development of the pig when measured at 110 d of gestation.     

Differentiation of adipose tissue and muscle in hypophysectomized pig fetuses

In the present study, fetuses were hypophysectomized (hypox) in utero on d 72 to 74 of gestation with an electrical cauterizing needle. One to six successfully hypox fetuses were removed on d 110 of gestation from each of five gilts. Subcutaneous adipose tissue samples and semitendinosus muscles were obtained from the hypox fetuses and an equal number of control fetuses. Body weights of control fetuses (n = 15; mean +/- SE, 1,195 +/- 33 g) were similar to weights of hypox fetuses (n = 15; 1,179 +/- 67 g). Fat cell size in the middle subcutaneous layer of adipose tissue was increased in hypox fetuses (P less than .01) compared with control fetuses. The number of obvious fat cell clusters (outer layer) in lipid stained sections was reduced (P less than .01) by 50% in hypox fetuses. Histochemical reactions for glucose-6-phosphate dehydrogenase, esterase and lipoprotein lipase (LPL) activities in middle layer cell clusters were considerably enhanced in sections from hypox fetuses compared with sections from controls. Quantitative analysis of percent light transmittance (Zeiss photometer) through LPL-stained cell clusters indicated an increase (P less than .001) in LPL staining in sections from hypox fetuses when compared with sections from control fetuses. Transverse muscle sections (cryostat) from hypox fetuses failed to show normal patterns (as seen in control muscles) of reactions for acid ATPase, malate dehydrogenase (NAD-dependent), NADH-TR and alpha-glycerol phosphate dehydrogenase (without NAD). The number of muscle fibers that were stained for these enzymes was greatly reduced in hypox fetuses compared with control fetuses. The number of lipid positive fibers was also reduced in hypox fetuses compared with control fetuses.(ABSTRACT TRUNCATED AT 250 WORDS)     

猪脂肪沉积相关的生化特征研究

以遗传瘦肉型的斯格猪和长白猪以及遗传脂肪型的通城猪和太湖猪为动物样本，分析了血清中激素敏感脂酶，肌肉组织中氨基酸组成、含量和克分子比，分离纯化了肌细胞和脂肪细胞质和膜，并对其膜蛋白进行了SDS－PAGE比较分析。结果表明，脂肪型的通城猪血中激素敏感脂酶活性比瘦肉型的长白猪高近3倍，2猪种中雌雄差异不显著。脂肪型的通城猪与太湖猪肌细胞蛋白质中的氨工酸组成及含量十分相似，瘦肉型的斯格和长白猪的氨基酸含量却显著地高于脂肪型的通城和太湖猪。氨基酸组分中，瘦肉型猪的3种碱性氨基酸（Lys、Arg和His）、2种典型的疏水氨基酸（Ｌeu和lle)、易形成疏水核的苯丙氨酸以及形成二硫键的半胱氨酸均显著地高于脂肪型，这与瘦肉型猪蛋白质的溶解性能较差相关。蛋白质的SDS－PAGE分析发现，脂肪型猪肌细胞质中存在一种一约44．7kDa，与脂肪沉积相关的蛋白质。脂肪细胞膜中的94kDa蛋白也显示也脂肪沉积的遗传特征相关，另外，脂肪型的通城猪性成熟前后肌细胞膜上存在蛋白质组分差异。     

Use of carbohydrate and fat as energy source by obese and lean swine

Genetically obese and lean pigs were fed isonitrogenous-isoenergetic (digestible energy) amounts of a high or low fat diet from 25 kg body weight. Obese pigs gained less and required more feed per unit gain than lean pigs. Lean pigs were more muscular with less fat than obese pigs. Obese pigs utilized more dietary amino acids for energy (greater plasma urea N) than did lean pigs. Weight gain was similar at all intermediate periods in obese pigs fed the two diets. However, gain tended (P less than or equal to .10) to be greater and the ratio of dietary energy intake to gain tended (P less than or equal to .10) to be less in obese pigs fed high compared with low fat diets. Similar results were observed in lean pigs fed the two diets. The high fat diet produced more carcass adipose tissue deposition in both strains after 20 wk of feeding (detectable by ultrasound at 14, but not at 7 wk). Adipose tissue lipogenic rate (glucose incorporation) was similarly depressed by fat feeding in both obese and lean pigs. Obese and lean pigs both utilized dietary carbohydrate and fat differentially but there was no indication of genetic divergence regarding this utilization. In both strains of pigs, energy from the fat-enriched diet was preferentially partitioned into carcass adipose tissue.     

Cellularity of developing subcutaneous adipose tissue in Landrace and Meishan pigs: Adipocyte size differences between two breeds

Experiments were designed to compare the adipocyte cellularity of subcutaneous adipose tissue between growing Landrace (low backfat) and Meishan (high backfat) pigs at 1 week, 3 weeks, 6 weeks, 3 months and 5 months of age. As pigs aged, body weight and backfat thickness of both breeds significantly increased. When compared at equal ages, backfat thickness adjusted to equal body weight was greater for Meishan pigs. The mean diameter of fat cell size also increased with age, and by 6 weeks adipocytes from both outer and inner layers of subcutaneous adipose tissue were larger in Meishan pigs. At 5 months, approximately 80% of the adipose tissue mass in Meishan pigs was attributable to adipocytes measuring 95–165 µm in diameter, whereas adipocytes of 75–145 µm comprised most of the tissue mass in the Landrace. Although the contribution of smaller adipocytes (25–45 µm) to the tissue volume was negligible, both breeds showed a biphasic diameter distribution at all ages, suggesting that adipocyte hyperplasia is still active. Our results demonstrate that cellularity differences exist between the subcutaneous adipose tissues of Landrace and Meishan pigs, and adipocyte hypertrophy is the most overwhelming contributor to the greater backfat deposition for Meishan pigs.     

Adipose tissue development in the fetal pig examined using monoclonal antibodies

Two anti-adipocyte monoclonal antibodies (MAbs: AD-1 and AD-2) have been used to study the development of dorsal s.c. adipose tissue in fetuses from 50 to 110 d of gestation. Immunofluorescent staining of cryostat sections with each antibody revealed antigen-positive cells in fetal s.c. mesenchyme prior to lipid deposition. Lipid droplets as well as AD-1 and AD-2 positive cells were detected within the underlying muscle at 50 d. From 70 to 110 d of development, the AD-1 and AD-2 MAbs each detected all adipocytes examined, as well as capillaries associated with fat cell clusters in s.c. tissues. Reactivity toward both antibodies, as well as lipid deposition, also was detectable in the muscle underlying the s.c. mesenchyme from 70 d onward. Each MAb possessed a distinct pattern of reactivity. The AD-2 MAb stained arrector pili muscles and vessels in the s.c. mesenchyme and vessels in the underlying muscles, whereas the AD-1 did not. No reactivity using either MAb was detectable toward any other cell types within s.c. tissues. These results established the presence of cells expressing surface determinants found on mature adipocytes and associated capillaries prior to adipogenesis. A lineage relationship between adipocytes and capillary endothelial cells is suggested.