Project description:Postpartum mammary gland involution is a coordinated process of cell death and remodeling that returns the tissue to a near pre-pregnant state following lactation and weaning. In models of postpartum breast cancer, defined as breast cancer diagnosed in women under age 45 and within 10 years of recent childbirth, involution induces durable phenotypes in breast tumor cells that promote progression and are associated with increased risk for therapeutic resistance, metastasis, and death in patients. SRY-Box Transcription Factor 9 (SOX9), a known regulator of mammary stem and progenitor cells, also promotes resistance to therapy and metastasis in breast cancers. Yet the contribution of SOX9 to the involution process is not well understood. We utilized single-cell RNA sequencing of mouse mammary glands during involution to delineate Sox9-expressing cell populations during lactation and involution. We found that Sox9 mRNA is primarily expressed in luminal progenitor cells that are largely absent during lactation and present during early involution. We also reveal that Sox9 is involved in a shift in cell state from lactational to non-lactational and is expressed in the surviving cells during involution. Prior work revealed that Semaphorin-7a (SEMA7A) also promotes cancer stem cell and pro-survival phenotypes in luminal progenitor cells during involution, and we observe a population of luminal progenitor cells that co-expresses Sox9 and Sema7a during involution. Mechanistically, we demonstrate that knockdown of Sox9 in cultured mammary epithelial cells results in increased SEMA7A expression, mesenchymal phenotypes, and loss of lactogenic differentiation capacity, identifying a potential regulatory axis where SOX9 balances SEMA7A expression in normal mammary epithelium and that disruption of this balance results in a dedifferentiated state that resembles mesenchymal cells. We validated a spatial relationship between SOX9 and SEMA7A proteins in a unique set of breast tissue samples from healthy human donors to show co-expression during early involution. In breast cancer datasets, we observe elevated expression of SOX9 and SEMA7A in triple-negative breast cancers, as well as in the mesenchymal subtype of triple-negative breast cancers, suggesting disruption of this regulatory axis in breast cancer. Finally, we observe that co-expression increases metastatic risk in both estrogen receptor-negative and -positive breast cancers. Collectively, these findings define a novel SOX9–SEMA7A relationship in healthy mammary tissues and illustrate how studies of normal progenitor cell phenotypes can delineate cellular mechanisms that contribute to breast tumor progression.

Project description:To investigate the dynamic changes in gene expression during mammary gland development and lactation in sows, mammary tissue samples were collected from 30 multiparous crossbred half-sibling sows (Danish Landrace × Yorkshire) housed under standardized conditions. Samples were obtained at five critical physiological stages: mid-gestation (Day 70), late gestation (Day 110), early lactation (Day 2 postpartum), peak lactation (Day 10 postpartum), and early involution (Day 2 post-weaning), with six biological replicates per stage. Parenchymal mammary tissue (0.5–1 cm³) was excised from a defined location below the third pair of teats and rapidly snap-frozen in liquid nitrogen for RNA preservation. All instruments were treated with RNase inhibitors to ensure RNA integrity. The collected samples were stored at –80°C for subsequent total RNA extraction and transcriptome sequencing, providing a valuable resource for elucidating molecular mechanisms underlying mammary gland remodeling and lactation regulation in sows.

Project description:Cellular senescence is an evolutionarily conserved stress response which contributes to tissue repair and tumor suppression, yet its accumulation is also linked to aging and disease. Whether physiological senescence can be exploited by oncogenic events to promote tumorigenesis is unknown. Postpartum mammary gland involution is a major adult tissue-remodeling event, resembling wound healing, and is closely associated with postpartum breast cancer (PPBC). Here, we show that during mammary gland involution in mice, a p16-dependent senescence response is induced in alveolar luminal cells. Eliminating senescent cells disrupts tissue remodeling and delays involution, demonstrating their physiological importance. However, in a PPBC model where oncogenic activation coincides with involution, removing involution-associated senescent cells extended tumor latency. Mechanistically, senescent cells enhance tumor cell plasticity via the senescence-associated secretory phenotype (SASP), fostering metastasis. Our findings reveal that senescence, while required for postpartum tissue remodelling, can be hijacked to facilitate tumorigenesis, defining senescence as a unifying mechanism linking tissue repair to tumorigenesis.

Project description:The mammary gland develops mainly postnatally, when during pregnancy the epithelium grows out into the mammary fat pad and forms a network of epithelial ducts. During pregnancy, these ducts branch and bud to form alveoli. These alveoli produce the milk during lactation. After 7 days of lactation, involution was induced by force weaning the pups. The newly formed epithelium undergoes apoptosis and is removed from the tissue by neighbouring epithelial cells. Tissue remodelling leads to a morphology resembling a gland of a pre-pregnant mouse. Microarray analysis was used to measure mRNA expression of genes during puberty, pregnancy, lactation and involution in a Balb/c mouse strain. Keywords: developmental time course

Project description:Involution returns the lactating mammary gland to a quiescent state after weaning. The mechanism of involution involves collapse of the mammary epithelial cell compartment. To test whether the cJUN NH2-terminal kinase (JNK) signal transduction pathway contributes to involution, we established mice with JNK deficiency in the mammary epithelium. We found that JNK is required for efficient involution. JNK deficiency did not alter the STAT3/5 or SMAD2/3 signaling pathways that have been previously implicated in this process. Nevertheless, JNK promotes the expression of genes that drive involution, including matrix metalloproteases, cathepsins, and BH3-only proteins. These data demonstrate that JNK has a key role in mammary gland involution post lactation.

Project description:The mammary gland develops mainly postnatally, when during pregnancy the epithelium grows out into the mammary fat pad and forms a network of epithelial ducts. During pregnancy, these ducts branch and bud to form alveoli. These alveoli produce the milk during lactation. After 7 days of lactation, involution was induced by force weaning the pups. The newly formed epithelium undergoes apoptosis and is removed from the tissue by neighbouring epithelial cells. Tissue remodelling leads to a morphology resembling a gland of a pre-pregnant mouse. Microarray analysis was used to measure mRNA expression of genes during puberty, pregnancy, lactation and involution in a Balb/c mouse strain. Experiment Overall Design: Total RNA was extracted from the 4th (inguinal) gland after removal of the lymph node. Individual samples represent RNA from one gland of one mouse. Samples were taken in triplicate (i.e. three mice per triplicate) for 18 time points of development.

Project description:Next-generation sequencing (NGS) has revolutionized systems-based analysis of miRNA expression files. The goals of this study are to obtain the miRNA expression files in dairy goat mammary gland at early lactation (10th day after parturition) and early involution (5th day after forced weaning at late lactation, 218 day after parturition).

Project description:Post-lactational involution of the mammary gland provides a unique model to study breast cancer susceptibility and metastasis. We have shown that the short isoform of Singleminded-2 (Sim2s), a bHLH/PAS transcription factor, plays a role in promoting lactogenic differentiation, as well as in maintaining mammary epithelial differentiation and malignancy. Sim2s is dynamically expressed during mammary gland development, with expression peaking during lactation, and decreasing in early involution. To determine the role of Sim2s in involution, we used transgenic mice expressing Sim2s under the mouse mammary tumor virus (MMTV-Sim2s) promoter. Over-expression of Sim2s in the mouse mammary gland resulted in delayed involution, indicated by a lower proportion of cleaved caspase-3 positive cells and slower re-establishment of the mammary fat pad. Immunohistochemical and quantitative RNA analysis showed a decrease in apoptotic markers and inflammatory response genes, and an increase in anti-apoptotic genes, which were accompanied by inhibition of signal transducer and activator of transcription 3 (Stat3) activity. Microarray analysis confirmed that genes in the Stat3 signaling pathway were repressed by Sim2s expression, along with NFκB and other key pathways involved in mammary gland development. Multiparous MMTV-Sim2s females displayed a more differentiated phenotype compared to wild-type controls, characterized by enhanced β-casein expression and alveolar structures. Together, these results suggest a role for Sim2s in the normal involuting gland, and identify potential down-stream pathways regulated by Sim2s. Gene expression was measured in 6 mammary gland samples using CodeLink Mouse Whole Genome microarrays. 3 samples were from wild-type mice harvested at 72 hours post weaning and 3 samples were MMTV-Sim2s mice harvested at 72 hours post weaning.

Project description:The mammary gland is a unique organ as it undergoes most of its development during puberty and adulthood. Characterising the hierarchy of the various mammary epithelial cells and how they are regulated in response to gestation, lactation and involution is important for understanding how breast cancer develops. Recent studies have used numerous markers to enrich, isolate and characterise the different epithelial cell compartments within the adult mammary gland. However, in all of these studies only a handful of markers were used to define and trace cell populations. Therefore, there is a need for an unbiased and comprehensive description of mammary epithelial cells within the gland at different developmental stages. To this end we used single cell RNA sequencing (scRNAseq) to determine the gene expression profile of individual mammary epithelial cells across four adult developmental stages; nulliparous, mid gestation, lactation and post weaning (full natural involution). Our data from 25,010 individual cells identifies 8 distinct mammary epithelial cell populations and allows their hierarchical structure across development to be charted. Interestingly, the effect of gestation and lactation appeared to be more pronounced for some cell types. For example, our analysis revealed a cluster of luminal progenitor cells in post involution glands, which is distinct from progenitors found in nulliparous glands. The data also showed that few clusters could be fully characterized by a single marker gene. We argue instead that the epithelial cells – especially in the luminal compartment – should rather be conceptualized as being part of a continuous spectrum of differentiation. This view highlights the plasticity of the tissue and might help to explain some of the conflicting results from lineage tracing studies.

Project description:This study was performed to identify transcripts that are differentially expressed in the mammary gland at 4 stages of developmental (virgin, pregnant, lactating and involution) in wild type C57BL/6J mice. Experiment Overall Design: Whole mammary glands No4 (inguinal) were obtained from female mice at 4 stages of development: Virgin (puberty, 6 wks of age), Pregnant (14 days of pregnancy), Lactating (day 10 postpartum) and Involution (4 days post weaning of pups). Three biological replicates were obtained from Virgin females and two biological replicates for the three other stages. mice