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6. Milk from dams fed an obesogenic diet combined with a high-fat/high-sugar diet induces long-term abnormal mammary gland development in the rabbit1

Author

Hue-Beauvais, C., primary, Koch, E., additional, Chavatte-Palmer, P., additional, Galio, L., additional, Chat, S., additional, Letheule, M., additional, Rousseau-Ralliard, D., additional, Jaffrezic, F., additional, Laloë, D., additional, Aujean, E., additional, Révillion, F., additional, Lhotellier, V., additional, Gertler, A., additional, Devinoy, E., additional, and Charlier, M., additional

Published
2015
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8. Assignment of the rabbit whey acidic protein gene (WAP) to rabbit chromosome 10 by in situ hybridization and description of a large region surrounding this gene

Author

Claire ROGEL-GAILLARD, Zijlstra, C., Bosma, A. A., Thépot, D., Fontaine, M. L., Devinoy, E., Chardon, P., ProdInra, Migration, Laboratoire de radiobiologie et d'étude du génome (LREG), Institut National de la Recherche Agronomique (INRA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Unité de biologie cellulaire et moléculaire, Institut National de la Recherche Agronomique (INRA), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de la Recherche Agronomique (INRA)

Subjects
[SDV] Life Sciences [q-bio], EXPRESSION DU GENE, [SDV]Life Sciences [q-bio], BIOLOGIE MOLECULAIRE, GENETIQUE, ComputingMilieux_MISCELLANEOUS
Abstract

International audience

Published
2000

9. Association between litter size and the k-casein genotype in the INRA rabbit lines

Author

Hungarian Scientific Research Fund, Bolet, G., Devinoy, E., Viràg, G., Harsányi, I., Bosze, Zs., Hungarian Scientific Research Fund, Bolet, G., Devinoy, E., Viràg, G., Harsányi, I., and Bosze, Zs.

Abstract

[EN] The reproductive traits of 276 rabbit does belonging to an intercross generation of two synthetic INRAlines, which differed by their genotypes at the k-casein locus being either AA or AB, were recorded at birth andat weaning for a total of 743 litters. They were the daughters of 77 dams whose k-casein genotype was ABand 18 sires whose genotype was AA. A significant association between the k-casein genotype andreproductive traits at birth was found in favour of the AB females, with an increase in litter size (+0.56;P<0.009) as well as in litter weight (+27 g; P<0.023). After standardisation of the litter size at birth, thegenotype of the dam was found to have no effect on weight gain and the viability of the young between birthand weaning or on the litter weight at weaning. Work is now in progress to explain this association.

Published
2007

10. Variation of transferrin mRNA concentration in the rabbit mammary gland during the pregnancy-lactation-weaning cycle and in cultured mammary cells. A comparison with the other major milk protein mRNAs

Author

Claudine Puissant, Bayat-Sarmadi M, Devinoy E, and Houdebine Lm

Subjects
medicine.medical_specialty, Endocrinology, Diabetes and Metabolism, Mammary gland, Molecular Sequence Data, Weaning, Polymerase Chain Reaction, Endocrinology, Mammary Glands, Animal, Pregnancy, Internal medicine, Lactation, Gene expression, medicine, Animals, Northern blot, RNA, Messenger, Cells, Cultured, DNA Primers, chemistry.chemical_classification, biology, Base Sequence, Transferrin, Caseins, Glyceraldehyde-3-Phosphate Dehydrogenases, General Medicine, Blotting, Northern, Milk Proteins, Prolactin, Peptide Fragments, Extracellular Matrix, medicine.anatomical_structure, chemistry, Gene Expression Regulation, Liver, biology.protein, Pregnancy, Animal, Female, Whey Acidic Protein, Rabbits, Hormone
Abstract

Puissant C, Bayat-Sarmadi M, Devinoy E, Houdebine L-M. Variation of transferrin mRNA concentration in the rabbit mammary gland during the pregnancy–lactation–weaning cycle and in cultured mammary cells. A comparison with the other major milk protein mRNAs. Eur J Endocrinol 1994;130:522–9. ISSN 0804–4643 The concentration of transferrin mRNA was evaluated during pregnancy and lactation in rabbit mammary gland and liver using northern blot and dot blot assays. Transferrin mRNA was present in the virgin rabbit mammary gland and its concentration increased as pregnancy proceeded, with a major enhancement after day 15. A high concentration was reached 3 days after parturition, with no additional increase during lactation and with a marked decline after weaning. During the same period, the concentration of transferrin mRNA showed only a very weak variation in liver. This mRNA was six times more abundant in mammary gland than in liver of lactating rabbit. The accumulation of transferrin mRNA in the mammary gland was concomitant with the accumulation of αs1-, β-, kcasein and WAP (whey acidic protein) mRNAs. The concentration of glyceraldehyde 3-phosphate dehydrogenase mRNA, taken as a non-inducible control mRNA, declined progressively during pregnancy to reach its lower level in lactation. These observations suggest that casein, WAP and transferrin mRNAs are subjected to a similar control mechanism in vivo, at least in the second half of pregnancy and during lactation. Experiments carried out in vitro using isolated rabbit epithelial mammary cells cultured on collagen I gel indicated that transferrin mRNA was abundant and only weakly inducible by the lactogenic hormones insulin, cortisol and prolactin, as opposed to caseins and WAP mRNAs. R5020, an analogue of progesterone, inhibited at most very slightly the accumulation of αs1-casein mRNA in the presence of prolactin and it did not reduce the expression of transferrin gene. The mammary cells cultured on a plastic support contained much less transferrin mRNA than those maintained on collagen gel or on EHS (Engelbreth–Holm–Swarm) extracellular matrix independently of any hormonal stimulation. These data suggest that although caseins, WAP and transferrin mRNAs have parallel variations during the pregnancy–lactation–weaning cycle, they are subjected to different mechanisms of regulation at the molecular level. The accumulation of the mRNAs for caseins and WAP is positively regulated by lactogenic hormones and by the presence of the extracellular matrix, whereas the accumulation of transferrin mRNA is positively regulated essentially by the presence of the matrix. The fact that the levels of all the mRNAs studied here are increased simultaneously as progesterone starts declining suggests that the steroid controls the action of a factor, possibly the presence of the extracellular matrix, that regulates the expression of all the milk protein genes. L-M Houdebine, Unité de Differenciation Cellulaire, Institut National de la Recherche Agronomique, 78352 Jouy-en-Josas Cédex, France

Published
1994

12. Milk from dams fed an obesogenic diet combined with a high-fat/high-sugar diet induces long-term abnormal mammary gland development in the rabbit.

Author

Beauvais, C. Hue-, Koch, E., Chavatte-Palmer, P., Galio, L., Chat, S., Letheule, M., Rousseau-Ralliard, D., Jaffrezic, F., Laloë, D., Aujean, E., Révillion, F., Lhotellier, V., Gertler, A., Devinoy, E., and Charlier, M.

Subjects
MILK, RABBIT feeding & feeds, MAMMARY glands, ANIMAL nutrition, ANIMAL development, PHENOTYPES
Abstract

Alterations to the metabolic endocrine environment during early life are crucial to mammary gland development. Among these environmental parameters, the initial nutritional event after birth is the consumption of milk, which represents the first maternal support provided to mammalian newborns. Milk is a complex fluid that exerts effects far beyond its immediate nutritional value. The present study, therefore, aimed to determine the effect of the nutritional changes during the neonatal and prepubertal periods on the adult mammary phenotype. Newborn rabbits were suckled by dams fed a high-fat/high-sugar obesogenic (OD) or a control (CON) diet and then subsequently fed either the OD or CON diets from the onset of puberty and throughout early pregnancy. Mammary glands were collected during early pregnancy (Day 8 of pregnancy). Rabbits fed with OD milk and then subjected to an OD diet displayed an abnormal development of the mammary gland: the mammary ducts were markedly enlarged (P < 0.05) and filled with abundant secretory products. Moreover, the alveolar secretory structures were disorganized, with an abnormal aspect characterized by large lumina. Mammary epithelial cells contained numerous large lipid droplets and exhibited fingering of the apical membrane and abnormally enlarged intercellular spaces filled with casein micelles. Leptin has been shown to be involved in modulating several developmental processes. We therefore analyzed its expression in the mammary gland. Mammary leptin mRNA was strongly expressed in rabbits fed with OD milk and subjected to an OD diet by comparison with the CON rabbits. Leptin transcripts and protein were localized in the epithelial cells, indicating that the increase in leptin synthesis occurs in this compartment. Taken together, these findings suggest that early-life nutritional history, in particular through the milking period, can determine subsequent mammary gland development. Moreover, they highlight the potentially important regulatory role that leptin may play during critical early-life nutritional windows with respect to long-term growth and mammary function. [ABSTRACT FROM AUTHOR]

Published
2015
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28. Characterization of rabbit κ-casein cDNA: control of κ-casein gene expression in vivoand in vitro

Author

Bösze, Zs, Devinoy, E, Puissant, C, Fontaine, M L, and Houdebine, L M

Abstract

The rabbit κ-casein cDNA was cloned and sequenced. One of the isolated clones included almost the entire 5′ end, while another clone corresponded to the 3′ end of the cDNA. No polyadenylation site was found and therefore this clone did not harbour the complete cDNA. The amino acid sequence of a full-length protein was deduced from the nucleotide sequence obtained for this partial cDNA. It revealed the presence of a chymosin cleavage site and five potential phosphorylation sites. Rabbit κ-casein was compared with those already described in other species. The rabbit sequence is closer to the ovine than to the mouse sequence. This result supports the idea that Lagomorpha are not closer to Rodentia than to Artiodactyla. The cDNA described above was used to study κ-casein gene expression in the rabbit mammary gland. This expression was induced primarily by prolactin in mammary gland organoids and was similar to αs1-casein gene expression in vivo. The κ-casein gene present in the casein gene locus is thus subject to the same regulation as the αs1-casein gene, although it has evolved from a fibrinogen gene.

Published
1993
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29. Assignment<FOOTREF>[sup 1] </FOOTREF> of the rabbit whey acidic protein gene (WAP) to rabbit chromosome 10 by in situ hybridization and description of a large region surrounding this gene.

Author

Rogel-Gaillard, C., Zijlstra, C., Bosma, A. A., Thépot, D., Fontaine, M. L., Devinoy, E., and Chardon, P.

Subjects
WHEY, GENES, HUMAN chromosomes, PROTEASE inhibitors, IN situ hybridization, BACTERIAL artificial chromosomes
Abstract

This article describes the entire region of the rabbit whey acidic protein (WAP) gene used in transgenic experiments. WAP has been described in the milk of rodents, rabbits, camels and pigs. WAP belongs to the four-disulfide core family that includes protease inhibitors but its physiological role is still unclear. Two overlapping bacterial artificial chromosome clones carrying the WAP gene were recovered from a rabbit library. Chromosomes showing specific sites of hybridization were identified according to the recommendations of the Committee for Standardized Karyotype of Oryctolagus cuniculus.

Published
2000
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30. Effect of once daily milking on mammary transcriptome and cell turnover in dairy goat.

Author

Boutinaud, M., Dris-Kerdreux, V., Wiart, S., Aubry, J. M., Laloe, D., Jaffrezic, F., Devinoy, E., and Galio, L.

Subjects
MILKING, MESSENGER RNA, GOATS
Abstract

Once-daily milking is known to modify cell number and activity in the bovine mammary gland. However, in goats, the effect of once-daily milking on mammary cell death is controversial. To assess the effect of once-daily milking on mammary transcriptome and cell turnover and the effect of the duration of once-daily milking, 10 goats producing 2.5 kg of milk per day at 100 DIM were divided into 2 groups. All goats were twice daily milked during a pre-experimental period of 2 wk. Then, the goats were once daily milked for the 3 following weeks. Mammary biopsy samples were collected at d -1 and 7 after the start of once-daily milking for one group of 5 goats and at d -1 and 21 for a second group of 5 goats. Cell apoptosis and proliferation rates were analyzed in mammary tissue by immunohistological analyses after TUNEL and PCNA staining, respectively. Ribonucleic acid was extracted from mammary tissues. A transcriptomic analysis using the Agilent Bovine 4x44k microarrays has been performed to compare the effect of once-daily milking on mammary transcript profiles. Data were normalized and statistical significant raw P-values were adjusted for multiple comparisons using the Benjamini-Hochberg procedure. A similar reduction in milk yield (-19%) was observed in both groups of goats during once-daily milking compared with twice-daily milking. Cell apoptosis was higher during once-daily milking than during twice-daily milking for both groups of goats (P < 0.05) whereas cell proliferation did not vary (P = 0.27). The transcriptomic analysis showed a differential gene expression of 4,039 transcripts, 2,238 and 1,801 transcripts up- and downregulated, respectively, by once-daily milking compared with twice-daily milking. More than 1,000 transcripts were commonly regulated between the 2 groups of goats. IPA analysis showed that these transcripts were part of networks associated with DNA replication, cellular growth and proliferation, and cell-to-cell signaling and interaction in both groups of goats. RT-qPCR analysis of 11 genes confirmed the differential gene expression with a downregulation of genes involved in milk synthesis and an upregulation of genes involved in cellular cycle and apoptosis. These results showed that once-daily milking induce cell turnover in goat mammary tissue, with a small impact of time. [ABSTRACT FROM AUTHOR]

Published
2017
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33. DNA methylation and transcription in a distal region upstream from the bovine AlphaS1 casein gene after once or twice daily milking.

Author

Nguyen M, Boutinaud M, Pétridou B, Gabory A, Pannetier M, Chat S, Bouet S, Jouneau L, Jaffrezic F, Laloë D, Klopp C, Brun N, Kress C, Jammes H, Charlier M, and Devinoy E

Subjects
Animals, Base Sequence, Cattle, Dairying, Female, Mammary Glands, Animal ultrastructure, Molecular Sequence Data, Multigene Family, Transcription, Genetic, Caseins genetics, DNA Methylation, Lactation, Milk chemistry, Peptide Fragments genetics
Abstract

Once daily milking (ODM) induces a reduction in milk production when compared to twice daily milking (TDM). Unilateral ODM of one udder half and TDM of the other half, enables the study of underlying mechanisms independently of inter-individual variability (same genetic background) and of environmental factors. Our results show that in first-calf heifers three CpG, located 10 kb upstream from the CSN1S1 gene were methylated to 33, 34 and 28%, respectively, after TDM but these levels were higher after ODM, 38, 38 and 33%, respectively. These methylation levels were much lower than those observed in the mammary gland during pregnancy (57, 59 and 50%, respectively) or in the liver (74, 78 and 61%, respectively). The methylation level of a fourth CpG (CpG4), located close by (29% during TDM) was not altered after ODM. CpG4 methylation reached 39.7% and 59.5%, during pregnancy or in the liver, respectively. CpG4 is located within a weak STAT5 binding element, arranged in tandem with a second high affinity STAT5 element. STAT5 binding is only marginally modulated by CpG4 methylation, but it may be altered by the methylation levels of the three other CpG nearby. Our results therefore shed light on mechanisms that help to explain how milk production is almost, but not fully, restored when TDM is resumed (15.1 ± 0.2 kg/day instead of 16.2 ± 0.2 kg/day, p<0.01). The STAT5 elements are 100 bp away from a region transcribed in the antisense orientation, in the mammary gland during lactation, but not during pregnancy or in other reproductive organs (ovary or testes). We now need to clarify whether the transcription of this novel RNA is a consequence of STAT5 interacting with the CSN1S1 distal region, or whether it plays a role in the chromatin structure of this region.

Published
2014
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34. Unilateral once daily milking locally induces differential gene expression in both mammary tissue and milk epithelial cells revealing mammary remodeling.

Author

Boutinaud M, Galio L, Lollivier V, Finot L, Wiart S, Esquerré D, and Devinoy E

Subjects
Animals, Apoptosis genetics, Cattle, Cell Proliferation, Down-Regulation genetics, Female, Gene Regulatory Networks, Mammary Glands, Animal anatomy & histology, Prolactin metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, Up-Regulation genetics, Dairying, Epithelial Cells metabolism, Gene Expression Profiling, Mammary Glands, Animal cytology, Mammary Glands, Animal physiology, Milk cytology
Abstract

Once daily milking reduces milk yield, but the underlying mechanisms are not yet fully understood. Local regulation due to milk stasis in the tissue may contribute to this effect, but such mechanisms have not yet been fully described. To challenge this hypothesis, one udder half of six Holstein dairy cows was milked once a day (ODM), and the other twice a day (TDM). On the 8th day of unilateral ODM, mammary epithelial cells (MEC) were purified from the milk using immunomagnetic separation. Mammary biopsies were harvested from both udder halves. The differences in transcript profiles between biopsies from ODM and TDM udder halves were analyzed by a 22k bovine oligonucleotide array, revealing 490 transcripts that were differentially expressed. The principal category of upregulated transcripts concerned mechanisms involved in cell proliferation and death. We further confirmed remodeling of the mammary tissue by immunohistochemistry, which showed less cell proliferation and more apoptosis in ODM udder halves. Gene expression analyzed by RT-qPCR in MEC purified from milk and mammary biopsies showed a common downregulation of six transcripts (ABCG2, FABP3, NUCB2, RNASE1 and 5, and SLC34A2) but also some discrepancies. First, none of the upregulated transcripts in biopsies varied in milk-purified MEC. Second, only milk-purified MEC showed significant LALBA downregulation, which suggests therefore that they correspond to a mammary epithelial cell subpopulation. Our results, obtained after unilateral milking, suggest that cell remodeling during ODM is due to a local effect, which may be triggered by milk accumulation.

Published
2013
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35. Leptin gene in rabbit: cloning and expression in mammary epithelial cells during pregnancy and lactation.

Author

Koch E, Hue-Beauvais C, Galio L, Solomon G, Gertler A, Révillon F, Lhotellier V, Aujean E, Devinoy E, and Charlier M

Subjects
Adipose Tissue metabolism, Animals, Cloning, Molecular, DNA Primers genetics, Epithelial Cells metabolism, Female, Gene Expression Regulation genetics, Immunohistochemistry, In Situ Hybridization, Lactation genetics, Pregnancy genetics, Protein Folding, RNA, Messenger metabolism, Real-Time Polymerase Chain Reaction, Recombinant Proteins genetics, Recombinant Proteins metabolism, Gene Expression Regulation physiology, Lactation metabolism, Leptin genetics, Leptin metabolism, Mammary Glands, Animal metabolism, Pregnancy metabolism, Rabbits genetics
Abstract

Leptin is known as a cytokine mostly produced by fat cells and implicated in regulation of energy metabolism and food intake but has also been shown to be involved in many physiological mechanisms such as tissue metabolism and cell differentiation and proliferation. In particular, leptin influences the development of mammary gland. Although leptin expression in mammary gland has been studied in several species, no data are available in the rabbit. Leptin transcripts in this species have been described as being encoded by only two exons rather than three as in other species. Our focus was to clone and sequence the rabbit leptin cDNA and to prepare the recombinant biologically active protein for validation of the proper sequence and then to describe leptin expression in rabbit mammary gland during different stages of pregnancy and lactation. The leptin sequence obtained was compared with those of other species, and genome alignment demonstrated that the rabbit leptin gene is also encoded by three exons. Additionally, we analyzed the expression of leptin during pregnancy and lactation. Leptin mRNA was weakly expressed throughout pregnancy, whereas mRNA levels were higher during lactation, with a significant increase between days 3 and 16. Leptin transcripts and protein were localized in luminal epithelial cells, thus indicating that leptin synthesis occurs in this compartment. Therefore, mammary synthesized leptin may constitute a major regulator of mammary gland development by acting locally as an autocrine and/or paracrine factor. Furthermore, our results support the possible physiological role of leptin in newborns through consumption of milk.

Published
2013
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36. MicroRNA in the ovine mammary gland during early pregnancy: spatial and temporal expression of miR-21, miR-205, and miR-200.

Author

Galio L, Droineau S, Yeboah P, Boudiaf H, Bouet S, Truchet S, and Devinoy E

Subjects
Animals, Cattle, Epithelial Cells metabolism, Female, Immunohistochemistry veterinary, In Situ Hybridization veterinary, Keratin-14 genetics, Keratin-14 metabolism, Keratin-8 genetics, Keratin-8 metabolism, Lactation genetics, Mammary Glands, Animal cytology, Mammary Glands, Animal growth & development, Mice, Oligonucleotide Array Sequence Analysis veterinary, Pregnancy, Reverse Transcriptase Polymerase Chain Reaction veterinary, Time Factors, Gene Expression Profiling veterinary, Gene Expression Regulation, Developmental, Mammary Glands, Animal metabolism, MicroRNAs genetics, Sheep genetics
Abstract

The mammary gland undergoes extensive remodeling between the beginning of pregnancy and lactation; this involves cellular processes including cell proliferation, differentiation, and apoptosis, all of which are under the control of numerous regulators. To unravel the role played by miRNA, we describe here 47 new ovine miRNA cloned from mammary gland in early pregnancy displaying strong similarities with those already identified in the cow, human, or mouse. A microarray study of miRNA variations in the adult ovine mammary gland during pregnancy and lactation showed that 100 miRNA are regulated according to three principal patterns of expression: a decrease in early pregnancy, a peak at midpregnancy, or an increase throughout late pregnancy and lactation. One miRNA displaying each pattern (miR-21, miR-205, and miR-200b) was analyzed by qRT-PCR. Variations in expression were confirmed for all three miRNA. Using in situ hybridization, we detected both miR-21 and miR-200 in luminal mammary epithelial cells when expressed, whereas miR-205 was expressed in basal cells during the first half of pregnancy and then in luminal cells during the second half. We therefore conclude that miR-21 is strongly expressed in the luminal cells of the normal mammary gland during early pregnancy when extensive cell proliferation occurs. In addition, we show that miR-205 and miR-200 are coexpressed in luminal cells, but only during the second half of pregnancy. These two miRNA may cooperate to maintain epithelial status by repressing an EMT-like program, to achieve and preserve the secretory phenotype of mammary epithelial cells.

Published
2013
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37. Specific positioning of the casein gene cluster in active nuclear domains in luminal mammary epithelial cells.

Author

Kress C, Kiêu K, Droineau S, Galio L, and Devinoy E

Subjects
Animals, Caseins biosynthesis, Cell Differentiation genetics, Cell Line, Cell Nucleus metabolism, Epithelial Cells cytology, Female, Gene Expression Regulation, Gene Rearrangement, Genetic Loci, Heterochromatin genetics, Heterochromatin metabolism, Lactation, Liver cytology, Liver metabolism, Mammary Glands, Animal cytology, Mammary Glands, Animal metabolism, Milk Proteins metabolism, Rabbits, Caseins genetics, Cell Nucleus genetics, Epithelial Cells metabolism, Milk Proteins genetics, Multigene Family
Abstract

The nuclear organization of mammary epithelial cells has been shown to be sensitive to the three-dimensional microenvironment in several models of cultured cells. However, the relationships between the expression and position of genes have not often been explored in animal tissues. We therefore studied the localization of milk protein genes in the nuclei of luminal mammary epithelial cells during lactation as well as in two non-expressing cells, i.e., hepatocytes and the less differentiated embryonic fibroblasts. We compared the position of a cluster of co-regulated genes, encoding caseins (CSN), with that of the whey acidic protein (WAP) gene which is surrounded by genes displaying different expression profiles. We show that the position of the CSN cluster relative to various nuclear compartments is correlated with its activity. In luminal cells, the CSN cluster loops out from its chromosome territory and is positioned in the most euchromatic regions, and frequently associated with elongating RNA polymerase II-rich zones. In hepatocytes and embryonic fibroblasts, the cluster is found preferentially closer to the nuclear periphery. Interestingly, we had previously observed a very peripheral position of the CSN locus in the nuclei of HC11 mammary epithelial cells weakly expressing milk protein genes. We thus show that cultured cell lines are not fully representative of the nuclear organization of genes in a complex and highly organized tissue such as the mammary gland and propose that the spatial positioning of the locus is important to ensuring the optimum control of CSN gene activity observed in the mammary tissue.

Published
2011
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38. An obesogenic diet started before puberty leads to abnormal mammary gland development during pregnancy in the rabbit.

Author

Hue-Beauvais C, Chavatte-Palmer P, Aujean E, Dahirel M, Laigre P, Péchoux C, Bouet S, Devinoy E, and Charlier M

Subjects
Animals, Body Weight, Eating, Female, Mammary Glands, Animal pathology, Models, Animal, Pregnancy, Rabbits, Diet adverse effects, Mammary Glands, Animal growth & development, Obesity pathology, Sexual Maturation
Abstract

Alterations to the metabolic environment during puberty can impact future lactation efficiency and mammary tumorigenesis. During this study, we used a model of rabbits receiving an obesogenic diet (OD), starting before puberty and extending until mid-pregnancy. Three months later, the body weight of OD animals was significantly higher than that of controls and their mammary glands displayed a precocious and abnormal development at mid-pregnancy. OD mammary ducts were filled with dense products, while alveolar structures invaded most of the fat pad. The proportion of secretory epithelium was significantly higher in OD mammary tissue, which contained an abundant accumulation of milk proteins and lipids. In conclusion, an obesogenic diet started before puberty induced an accelerated development of the rabbit mammary gland, leading to an accumulation of secretory products at mid-pregnancy. These results support the critical influence of nutrition on mammary growth and differentiation, which may be deleterious to mammary development and subsequent lactation., (Copyright © 2010 Wiley-Liss, Inc.)

Published
2011
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39. Statistical analysis of 3D images detects regular spatial distributions of centromeres and chromocenters in animal and plant nuclei.

Author

Andrey P, Kiêu K, Kress C, Lehmann G, Tirichine L, Liu Z, Biot E, Adenot PG, Hue-Beauvais C, Houba-Hérin N, Duranthon V, Devinoy E, Beaujean N, Gaudin V, Maurin Y, and Debey P

Subjects
Animals, Arabidopsis cytology, Embryo, Mammalian cytology, Female, Mammary Glands, Animal cytology, Microscopy, Confocal, Monte Carlo Method, Nuclear Proteins chemistry, Rabbits, Cell Nucleus chemistry, Centromere chemistry, Heterochromatin chemistry, Imaging, Three-Dimensional, Models, Statistical
Abstract

In eukaryotes, the interphase nucleus is organized in morphologically and/or functionally distinct nuclear "compartments". Numerous studies highlight functional relationships between the spatial organization of the nucleus and gene regulation. This raises the question of whether nuclear organization principles exist and, if so, whether they are identical in the animal and plant kingdoms. We addressed this issue through the investigation of the three-dimensional distribution of the centromeres and chromocenters. We investigated five very diverse populations of interphase nuclei at different differentiation stages in their physiological environment, belonging to rabbit embryos at the 8-cell and blastocyst stages, differentiated rabbit mammary epithelial cells during lactation, and differentiated cells of Arabidopsis thaliana plantlets. We developed new tools based on the processing of confocal images and a new statistical approach based on G- and F- distance functions used in spatial statistics. Our original computational scheme takes into account both size and shape variability by comparing, for each nucleus, the observed distribution against a reference distribution estimated by Monte-Carlo sampling over the same nucleus. This implicit normalization allowed similar data processing and extraction of rules in the five differentiated nuclei populations of the three studied biological systems, despite differences in chromosome number, genome organization and heterochromatin content. We showed that centromeres/chromocenters form significantly more regularly spaced patterns than expected under a completely random situation, suggesting that repulsive constraints or spatial inhomogeneities underlay the spatial organization of heterochromatic compartments. The proposed technique should be useful for identifying further spatial features in a wide range of cell types.

Published
2010
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40. Oleate and linoleate stimulate degradation of β-casein in prolactin-treated HC11 mouse mammary epithelial cells.

Author

Pauloin A, Chat S, Péchoux C, Hue-Beauvais C, Droineau S, Galio L, Devinoy E, and Chanat E

Subjects
Animals, Autophagy drug effects, Autophagy physiology, Caseins drug effects, Cell Line, Enzyme Inhibitors pharmacology, Epithelial Cells cytology, Epithelial Cells drug effects, Fatty Acids, Unsaturated metabolism, Fatty Acids, Unsaturated pharmacology, Female, Linoleic Acid pharmacology, Lipid Metabolism drug effects, Lipid Metabolism physiology, Lipids physiology, Lysosomes drug effects, Lysosomes metabolism, Mammary Glands, Animal cytology, Mammary Glands, Animal drug effects, Mice, Oleic Acid pharmacology, Prolactin pharmacology, Proteasome Endopeptidase Complex metabolism, Proteasome Inhibitors, Protein Processing, Post-Translational drug effects, Protein Processing, Post-Translational physiology, Caseins metabolism, Epithelial Cells metabolism, Linoleic Acid metabolism, Mammary Glands, Animal metabolism, Oleic Acid metabolism, Prolactin metabolism
Abstract

Although virtually all cells store neutral lipids as cytoplasmic lipid droplets, mammary epithelial cells have developed a specialized function to secrete them as milk fat globules. We have used the mammary epithelial cell line HC11 to evaluate the potential connections between the lipid and protein synthetic pathways. We show that unsaturated fatty acids induce a pronounced proliferation of cytoplasmic lipid droplets and stimulate the synthesis of adipose differentiation-related protein. Unexpectedly, the cellular level of beta-casein, accumulated under lactogenic hormone treatment, decreases following treatment of the cells with unsaturated fatty acids. In contrast, saturated fatty acids have no significant effect on either cytoplasmic lipid droplet proliferation or cellular beta-casein levels. We demonstrate that the action of unsaturated fatty acids on the level of beta-casein is post-translational and requires protein synthesis. We have also observed that proteasome inhibitors potentiate beta-casein degradation, indicating that proteasomal activity can destroy some cytosolic protein(s) involved in the process that negatively controls beta-casein levels. Finally, lysosome inhibitors block the effect of unsaturated fatty acids on the cellular level of beta-casein. Our data thus suggest that the degradation of beta-casein occurs via the microautophagic pathway.

Published
2010
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41. Epigenetics in mammary gland biology and cancer.

Author

Devinoy E and Rijnkels M

Subjects
Animals, Cell Differentiation, Chromatin Assembly and Disassembly, DNA metabolism, Female, Humans, Male, Mammary Glands, Animal cytology, Mammary Glands, Animal physiology, Mammary Glands, Human cytology, Breast Neoplasms genetics, Breast Neoplasms physiopathology, Epigenesis, Genetic, Mammary Glands, Human physiology
Published
2010
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42. The epigenetic landscape of mammary gland development and functional differentiation.

Author

Rijnkels M, Kabotyanski E, Montazer-Torbati MB, Hue Beauvais C, Vassetzky Y, Rosen JM, and Devinoy E

Subjects
Animals, Breast Neoplasms genetics, Breast Neoplasms physiopathology, Cell Differentiation physiology, Chromatin metabolism, Chromatin Assembly and Disassembly physiology, Female, Histones metabolism, Humans, RNA, Untranslated metabolism, Stem Cells metabolism, Transcription Factors metabolism, Transcription, Genetic, Epigenesis, Genetic, Gene Expression Regulation, Neoplastic, Mammary Glands, Animal growth & development, Mammary Glands, Animal physiology, Mammary Glands, Human growth & development, Mammary Glands, Human physiology
Abstract

Most of the development and functional differentiation in the mammary gland occur after birth. Epigenetics is defined as the stable alterations in gene expression potential that arise during development and proliferation. Epigenetic changes are mediated at the biochemical level by the chromatin conformation initiated by DNA methylation, histone variants, post-translational modifications of histones, non-histone chromatin proteins, and non-coding RNAs. Epigenetics plays a key role in development. However, very little is known about its role in the developing mammary gland or how it might integrate the many signalling pathways involved in mammary gland development and function that have been discovered during the past few decades. An inverse relationship between marks of closed (DNA methylation) or open chromatin (DnaseI hypersensitivity, certain histone modifications) and milk protein gene expression has been documented. Recent studies have shown that during development and functional differentiation, both global and local chromatin changes occur. Locally, chromatin at distal regulatory elements and promoters of milk protein genes gains a more open conformation. Furthermore, changes occur both in looping between regulatory elements and attachment to nuclear matrix. These changes are induced by developmental signals and environmental conditions. Additionally, distinct epigenetic patterns have been identified in mammary gland stem and progenitor cell sub-populations. Together, these findings suggest that epigenetics plays a role in mammary development and function. With the new tools for epigenomics developed in recent years, we now can begin to establish a framework for the role of epigenetics in mammary gland development and disease.

Published
2010
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43. Epigenetic modifications in 3D: nuclear organization of the differentiating mammary epithelial cell.

Author

Kress C, Ballester M, Devinoy E, and Rijnkels M

Subjects
Animals, Breast Neoplasms genetics, Breast Neoplasms metabolism, Chromatin Assembly and Disassembly physiology, Extracellular Matrix metabolism, Female, Gene Expression Regulation, Heterochromatin metabolism, Humans, Mammary Glands, Animal cytology, Mammary Glands, Human cytology, Nuclear Matrix metabolism, Cell Differentiation physiology, Cell Nucleus metabolism, Epigenesis, Genetic, Mammary Glands, Animal physiology, Mammary Glands, Human physiology, Nuclear Matrix physiology
Abstract

During the development of tissues, complex programs take place to reach terminally differentiated states with specific gene expression profiles. Epigenetic regulations such as histone modifications and chromatin condensation have been implicated in the short and long-term control of transcription. It has recently been shown that the 3D spatial organization of chromosomes in the nucleus also plays a role in genome function. Indeed, the eukaryotic interphase nucleus contains sub-domains that are characterized by their enrichment in specific factors such as RNA Polymerase II, splicing machineries or heterochromatin proteins which render portions of the genome differentially permissive to gene expression. The positioning of individual genes relative to these sub-domains is thought to participate in the control of gene expression as an epigenetic mechanism acting in the nuclear space. Here, we review what is known about the sub-nuclear organization of mammary epithelial cells in connection with gene expression and epigenetics. Throughout differentiation, global changes in nuclear architecture occur, notably with respect to heterochromatin distribution. The positions of mammary-specific genes relative to nuclear sub-compartments varies in response to hormonal stimulation. The contribution of tissue architecture to cell differentiation in the mammary gland is also seen at the level of nuclear organization, which is sensitive to microenvironmental stimuli such as extracellular matrix signaling. In addition, alterations in nuclear organization are concomitant with immortalization and carcinogenesis. Thus, the fate of cells appears to be controlled by complex pathways connecting external signal integration, gene expression, epigenetic modifications and chromatin organization in the nucleus.

Published
2010
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44. [Organization of the nucleus during cell differentiation in the mammary tissue].

Author

Kress C and Devinoy E

Subjects
Animals, Cell Nucleus genetics, Chromosomes, Human, Pair 11 genetics, Chromosomes, Human, Pair 5 genetics, Epithelial Cells cytology, Epithelial Cells physiology, Female, Gene Expression Profiling, Hormones physiology, Humans, Organ Specificity, Cell Differentiation physiology, Cell Nucleus physiology, Mammary Glands, Animal physiology
Abstract

In many tissues, the features of cell nuclei are specific to their differentiated state, notably in terms of the nature and distribution of nuclear compartments and the position of chromosomes and genes. This spatial organization of the nucleus reveals domains that are differentially permissive for gene expression and may constitute an epigenetic mechanism that is involved in maintaining tissue-specific expression profiles. The mammary gland is a complex tissue in which mammary epithelial cells (MECs), which synthesize and secrete milk components, interact with other cell types (myoepithelial cells, adipocytes) and the extracellular matrix. MECs cultures can to some extent recreate cell differentiation in vitro and have been used to follow the development and functional importance of nuclear organization. They have made it possible to show how hormonal stimulation can lead to a remodeling of nuclear domains and the repositioning of genes specific to the mammary gland, such as milk protein genes. By modulating the growth conditions of culture in order to replace cells in a microenvironment similar to that of mammary gland tissue, it should be possible to study the role of this cellular microenvironment in nuclear organization., (© Société de Biologie, 2010.)

Published
2010
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45. Modeling the 3D functional architecture of the nucleus in animal and plant kingdoms.

Author

Gaudin V, Andrey P, Devinoy E, Kress C, Kieu K, Beaujean N, Maurin Y, and Debey P

Subjects
Algorithms, Animals, Arabidopsis cytology, Blastocyst cytology, Cell Compartmentation, Cell Differentiation, Cell Nucleus physiology, Eukaryotic Cells physiology, Female, Gene Expression Regulation, Gene Expression Regulation, Plant, Image Processing, Computer-Assisted, Mammary Glands, Animal cytology, Plants genetics, Pregnancy, Protoplasts ultrastructure, Rabbits, Systems Biology methods, Cell Nucleus ultrastructure, Eukaryotic Cells ultrastructure, Models, Biological, Plant Cells
Abstract

Compartmentalization is one of the fundamental principles which underly nuclear function. Numerous studies describe complex and sometimes conflicting relationships between nuclear gene positioning and transcription regulation. Therefore the question is whether topological landmarks and/or organization principles exist to describe the nuclear architecture and, if existing, whether these principles are identical in the animal and plant kingdoms. In the frame of an agroBI-INRA program on nuclear architecture, we set up a multidisciplinary approach combining biological studies, spatial statistics and 3D modeling to investigate spatial organization of a nuclear compartment in both plant and animal cells in their physiological contexts. In this article, we review the questions addressed in this program and the methodology of our work.

Published
2009
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46. The genome sequence of taurine cattle: a window to ruminant biology and evolution.

Author

Elsik CG, Tellam RL, Worley KC, Gibbs RA, Muzny DM, Weinstock GM, Adelson DL, Eichler EE, Elnitski L, Guigó R, Hamernik DL, Kappes SM, Lewin HA, Lynn DJ, Nicholas FW, Reymond A, Rijnkels M, Skow LC, Zdobnov EM, Schook L, Womack J, Alioto T, Antonarakis SE, Astashyn A, Chapple CE, Chen HC, Chrast J, Câmara F, Ermolaeva O, Henrichsen CN, Hlavina W, Kapustin Y, Kiryutin B, Kitts P, Kokocinski F, Landrum M, Maglott D, Pruitt K, Sapojnikov V, Searle SM, Solovyev V, Souvorov A, Ucla C, Wyss C, Anzola JM, Gerlach D, Elhaik E, Graur D, Reese JT, Edgar RC, McEwan JC, Payne GM, Raison JM, Junier T, Kriventseva EV, Eyras E, Plass M, Donthu R, Larkin DM, Reecy J, Yang MQ, Chen L, Cheng Z, Chitko-McKown CG, Liu GE, Matukumalli LK, Song J, Zhu B, Bradley DG, Brinkman FS, Lau LP, Whiteside MD, Walker A, Wheeler TT, Casey T, German JB, Lemay DG, Maqbool NJ, Molenaar AJ, Seo S, Stothard P, Baldwin CL, Baxter R, Brinkmeyer-Langford CL, Brown WC, Childers CP, Connelley T, Ellis SA, Fritz K, Glass EJ, Herzig CT, Iivanainen A, Lahmers KK, Bennett AK, Dickens CM, Gilbert JG, Hagen DE, Salih H, Aerts J, Caetano AR, Dalrymple B, Garcia JF, Gill CA, Hiendleder SG, Memili E, Spurlock D, Williams JL, Alexander L, Brownstein MJ, Guan L, Holt RA, Jones SJ, Marra MA, Moore R, Moore SS, Roberts A, Taniguchi M, Waterman RC, Chacko J, Chandrabose MM, Cree A, Dao MD, Dinh HH, Gabisi RA, Hines S, Hume J, Jhangiani SN, Joshi V, Kovar CL, Lewis LR, Liu YS, Lopez J, Morgan MB, Nguyen NB, Okwuonu GO, Ruiz SJ, Santibanez J, Wright RA, Buhay C, Ding Y, Dugan-Rocha S, Herdandez J, Holder M, Sabo A, Egan A, Goodell J, Wilczek-Boney K, Fowler GR, Hitchens ME, Lozado RJ, Moen C, Steffen D, Warren JT, Zhang J, Chiu R, Schein JE, Durbin KJ, Havlak P, Jiang H, Liu Y, Qin X, Ren Y, Shen Y, Song H, Bell SN, Davis C, Johnson AJ, Lee S, Nazareth LV, Patel BM, Pu LL, Vattathil S, Williams RL Jr, Curry S, Hamilton C, Sodergren E, Wheeler DA, Barris W, Bennett GL, Eggen A, Green RD, Harhay GP, Hobbs M, Jann O, Keele JW, Kent MP, Lien S, McKay SD, McWilliam S, Ratnakumar A, Schnabel RD, Smith T, Snelling WM, Sonstegard TS, Stone RT, Sugimoto Y, Takasuga A, Taylor JF, Van Tassell CP, Macneil MD, Abatepaulo AR, Abbey CA, Ahola V, Almeida IG, Amadio AF, Anatriello E, Bahadue SM, Biase FH, Boldt CR, Carroll JA, Carvalho WA, Cervelatti EP, Chacko E, Chapin JE, Cheng Y, Choi J, Colley AJ, de Campos TA, De Donato M, Santos IK, de Oliveira CJ, Deobald H, Devinoy E, Donohue KE, Dovc P, Eberlein A, Fitzsimmons CJ, Franzin AM, Garcia GR, Genini S, Gladney CJ, Grant JR, Greaser ML, Green JA, Hadsell DL, Hakimov HA, Halgren R, Harrow JL, Hart EA, Hastings N, Hernandez M, Hu ZL, Ingham A, Iso-Touru T, Jamis C, Jensen K, Kapetis D, Kerr T, Khalil SS, Khatib H, Kolbehdari D, Kumar CG, Kumar D, Leach R, Lee JC, Li C, Logan KM, Malinverni R, Marques E, Martin WF, Martins NF, Maruyama SR, Mazza R, McLean KL, Medrano JF, Moreno BT, Moré DD, Muntean CT, Nandakumar HP, Nogueira MF, Olsaker I, Pant SD, Panzitta F, Pastor RC, Poli MA, Poslusny N, Rachagani S, Ranganathan S, Razpet A, Riggs PK, Rincon G, Rodriguez-Osorio N, Rodriguez-Zas SL, Romero NE, Rosenwald A, Sando L, Schmutz SM, Shen L, Sherman L, Southey BR, Lutzow YS, Sweedler JV, Tammen I, Telugu BP, Urbanski JM, Utsunomiya YT, Verschoor CP, Waardenberg AJ, Wang Z, Ward R, Weikard R, Welsh TH Jr, White SN, Wilming LG, Wunderlich KR, Yang J, and Zhao FQ

Subjects
Alternative Splicing, Animals, Animals, Domestic, Cattle, Evolution, Molecular, Female, Genetic Variation, Humans, Male, MicroRNAs genetics, Molecular Sequence Data, Proteins genetics, Sequence Analysis, DNA, Species Specificity, Synteny, Biological Evolution, Genome
Abstract

To understand the biology and evolution of ruminants, the cattle genome was sequenced to about sevenfold coverage. The cattle genome contains a minimum of 22,000 genes, with a core set of 14,345 orthologs shared among seven mammalian species of which 1217 are absent or undetected in noneutherian (marsupial or monotreme) genomes. Cattle-specific evolutionary breakpoint regions in chromosomes have a higher density of segmental duplications, enrichment of repetitive elements, and species-specific variations in genes associated with lactation and immune responsiveness. Genes involved in metabolism are generally highly conserved, although five metabolic genes are deleted or extensively diverged from their human orthologs. The cattle genome sequence thus provides a resource for understanding mammalian evolution and accelerating livestock genetic improvement for milk and meat production.

Published
2009
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47. The nuclear localization of WAP and CSN genes is modified by lactogenic hormones in HC11 cells.

Author

Ballester M, Kress C, Hue-Beauvais C, Kiêu K, Lehmann G, Adenot P, and Devinoy E

Subjects
Active Transport, Cell Nucleus, Animals, Caseins genetics, Cell Line, Chromosomes genetics, Heterochromatin genetics, Mice, Milk Proteins genetics, Caseins metabolism, Cell Nucleus drug effects, Cell Nucleus metabolism, Hormones pharmacology, Lactation, Milk Proteins metabolism
Abstract

Whey acidic protein (WAP) and casein (CSN) genes are among the most highly expressed milk protein genes in the mammary gland of the lactating mouse. Their tissue-specific regulation depends on the activation and recruitment of transcription factors, and chromatin modifications in response to hormonal stimulation. We have investigated if another mechanism, such as specific positioning of the genes in the nucleus, could be involved in their functional regulation. Fluorescent in situ hybridization was used to study the nuclear localization of WAP and CSN genes in mouse mammary epithelial cells (HC11) cultured in the absence and presence of lactogenic hormones. Automatic 3D image processing and analysis tools were developed to score gene positions. In the absence of lactogenic hormones, both genes are distributed non-uniformly within the nucleus: the CSN locus was located close to the nuclear periphery and the WAP gene tended to be central. Stimulation by lactogenic hormones induced a statistically significant change to their distance from the periphery, which has been described as a repressive compartment. The detection of genes in combination with the corresponding chromosome-specific probe revealed that the CSN locus is relocated outside its chromosome territory following hormonal stimulation, whereas the WAP gene, which is already sited more frequently outside its chromosome territory in the absence of hormones, is not affected. We conclude that milk protein genes are subject to nuclear repositioning when activated, in agreement with a role for nuclear architecture in gene regulation, but that they behave differently as a function of their chromosomal context., ((c) 2008 Wiley-Liss, Inc.)

Published
2008
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48. Epigenetic modifications and chromatin loop organization explain the different expression profiles of the Tbrg4, WAP and Ramp3 genes.

Author

Montazer-Torbati MB, Hue-Beauvais C, Droineau S, Ballester M, Coant N, Aujean E, Petitbarat M, Rijnkels M, and Devinoy E

Subjects
Animals, Cell Line, Liver, Mammary Glands, Animal, Membrane Proteins genetics, Mice, Rabbits, Receptor Activity-Modifying Protein 3, Receptor Activity-Modifying Proteins, Chromatin, DNA Methylation, Gene Expression Regulation physiology, Intracellular Signaling Peptides and Proteins genetics, Milk Proteins genetics
Abstract

Whey Acidic Protein (WAP) gene expression is specific to the mammary gland and regulated by lactogenic hormones to peak during lactation. It differs markedly from the more constitutive expression of the two flanking genes, Ramp3 and Tbrg4. Our results show that the tight regulation of WAP gene expression parallels variations in the chromatin structure and DNA methylation profile throughout the Ramp3-WAP-Tbrg4 locus. Three Matrix Attachment Regions (MAR) have been predicted in this locus. Two of them are located between regions exhibiting open and closed chromatin structures in the liver. The third, located around the transcription start site of the Tbrg4 gene, interacts with topoisomerase II in HC11 mouse mammary cells, and in these cells anchors the chromatin loop to the nuclear matrix. Furthermore, if lactogenic hormones are present in these cells, the chromatin loop surrounding the WAP gene is more tightly attached to the nuclear structure, as observed after a high salt treatment of the nuclei and the formation of nuclear halos. Taken together, our results point to a combination of several epigenetic events that may explain the differential expression pattern of the WAP locus in relation to tissue and developmental stages.

Published
2008
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49. [Nuclear organization and expression of milk protein genes].

Author

Chanat E, Aujean E, Balteanu A, Chat S, Coant N, Fontaine ML, Hue-Beauvais C, Péchoux C, Torbati MB, Pauloin A, Petitbarat M, and Devinoy E

Subjects
Animals, Breast cytology, Breast metabolism, Caseins biosynthesis, Caseins chemistry, Caseins genetics, Cattle, Cell Nucleus ultrastructure, Chromatin genetics, Chromatin ultrastructure, Cystine physiology, Epithelial Cells metabolism, Female, Genes, Regulator, Glycolipids metabolism, Glycoproteins metabolism, Glycoproteins ultrastructure, Hormones physiology, Humans, Intracellular Membranes physiology, Intracellular Membranes ultrastructure, Intracellular Signaling Peptides and Proteins genetics, Intracellular Signaling Peptides and Proteins physiology, Lactation genetics, Lipid Droplets, Mammary Glands, Animal cytology, Membrane Proteins genetics, Membrane Proteins physiology, Mice, Micelles, Milk Proteins biosynthesis, Nuclear Matrix physiology, Nuclear Matrix ultrastructure, Rabbits, Receptor Activity-Modifying Proteins, Transcription Factors physiology, Triglycerides metabolism, Cell Nucleus physiology, Gene Expression Regulation physiology, Lactation physiology, Mammary Glands, Animal metabolism, Milk Proteins genetics
Abstract

Milk protein gene expression varies during the pregnancy/lactation cycle under the influence of lactogenic hormones which induce the activation of several transcription factors. Beyond this activation modifying the binding properties of these factors to their consensus sequences, their interactions with DNA is regulated by variations of the chromatin structure. In the nuclei of the mammary epithelial cell, the three dimensional organisation of the chromatin loops, located between matrix attachment regions, is now being studied. The main milk components are organised in supramolecular structures. Milk fat globules are made of a triglyceride core enwrapped by a tripartite membrane originating from various intracellular compartments. The caseins, the main milk proteins, form aggregates: the casein micelles. Their gradual aggregation in the secretory pathway is initiated as soon as from the endoplasmic reticulum. The mesostructures of the milk fat globule and of the casein micelle remain to be elucidated. Our goal is to make some progress into the understanding of the molecular and cellular mechanisms involved in the formation of these milk products.

Published
2006
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50. Interactions between the rabbit CSN1 gene and the nuclear matrix of stably transfected HC11 mammary epithelial cells vary with its level of expression.

Author

Poussin K, Hayes H, Pauloin A, Chanat E, Fontaine ML, Aujean E, Sun JS, Debey P, and Devinoy E

Subjects
Animals, Cell Line, Cell Nucleus metabolism, Cell Nucleus ultrastructure, Chromosomes, DNA metabolism, Epithelial Cells cytology, Female, Gene Dosage, In Situ Hybridization, Mice, Rabbits, Transgenes, Caseins genetics, Caseins metabolism, Epithelial Cells metabolism, Gene Expression Regulation, Mammary Glands, Animal cytology, Nuclear Matrix metabolism
Abstract

The expression of casein genes is specific to the mammary gland and maximal during lactation. However, among the numerous mammary cell lines described so far, only a few express some casein genes. The regulatory regions of casein genes have been largely described but the mechanisms explaining the mammary specific expression of these genes, and their silencing in most mammary cell lines, have not yet been fully elucidated. To test the hypothesis that the nuclear location of the casein genes may affect their expression, we transfected HC11 mouse mammary cell line with a 100 kb DNA fragment surrounding the rabbit alpha S1 casein gene. We derived stable clones which express or not the transfected rabbit casein gene, in the same cellular context, independently of the number of transgene copies. Metaphase spreads were prepared from the different clones and the transfected genes were localized. Unexpectedly, we observed that in the original HC11 cell line the number of chromosomes per metaphase spread is close to 80, suggesting that HC11 cells have undergone a duplication event, since the mouse karyotype is 2n = 40. In alpha S1 casein expressing cells, the expression level does not clearly correlate with a localization of the transfected DNA proximal to the centromeres or the telomeres. Analysis of the localization of the transfected DNA in nuclear halos allows us to conclude that when expressed, transfected DNA is more closely linked to the nuclear matrix. The next step will be to study the attachment of the endogenous casein gene in mammary nuclei during lactation., ((c) 2005 Wiley-Liss, Inc.)

Published
2005
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