Project description:Mammary gland development during pregnancy is controlled by lactogenic hormones via the JAK2-STAT5 pathway. Gene deletion studies in mice have revealed the crucial roles of both STAT5A and STAT5B in establishing the genetic programs necessary for the development of mammary epithelium and successful lactation. Several hundred single nucleotide polymorphisms (SNPs) have been identified in human STAT5B, although their pathophysiological significance remains largely unknown. The SH2 domain is vital for STAT5B activation, and this study focuses on the impact of two specific missense mutations identified in T cell leukemias, the substitution of tyrosine 665 with either phenylalanine (Y665F) or histidine (Y665H). By introducing these human mutations into the mouse genome, we uncovered distinct and opposite functions. Mice harboring the STAT5BY665H mutation failed to develop functional mammary tissue, resulting in lactation failure, while STAT5BY665F mice exhibited accelerated mammary development during pregnancy. Transcriptomic and epigenomic analyses identified STAT5BY665H as Loss-Of-Function (LOF) mutation, impairing enhancer establishment and alveolar differentiation, whereas STAT5BY665F acted as a Gain-Of-Function (GOF) mutation, elevating enhancer formation. Persistent hormonal stimulation through two pregnancies led to the establishment of enhancer structures, gene expression and successful lactation in STAT5BY665H mice. Lastly, we demonstrate that Olah, a gene known to drive life-threatening viral disease in humans, is regulated by STAT5B through a candidate four-partite super-enhancer. In conclusion, our findings underscore the role of human STAT5B variants in modulating mammary gland homeostasis and their critical impact on lactation.

Project description:Normal hematopoiesis is regulated by various cytokines via the JAK-STAT signaling pathway. Gene deletion studies in mice have demonstrated the crucial role of STAT5B in the proliferation, differentiation, and survival of immune cells. However, the physiological effects of human STAT5B mutations remain poorly understood. Mutations within the SH2 domain of STAT5B have been identified in leukemia patients. In this study, we investigate two specific variants: one that substitutes tyrosine 665 with phenylalanine (STAT5BY665F) and another that substitutes tyrosine 665 with histidine (STAT5BY665H). We introduced these two mutations into the mouse genome and observed distinct and divergent impacts on immune cell function. The STAT5BY665F mutation enhanced STAT5B activity and the establishment of transcriptional enhancers and genetic programs. Conversely, the STAT5BY665H mutation was largely inactive, failing to induce the interleukin-regulated enhancer landscape and gene expression. Both mutations modified immune cell profiles, inducing features characteristic of autoimmune disease. In STAT5BY665F mice, there was an expansion of CD8+ and regulatory CD4+ T cells, whereas STAT5BY665H mice didn’t. Both mutant strains exhibited skin abnormalities; however, only the STAT5BY665F mice developed progressive dermatitis. Introduction of equivalent mutations into STAT5A did not significantly impact hematopoiesis. However, mice carrying mutations in both STAT5A and STAT5B displayed additive effects with highly elevated CD4+ and CD8+ T cells. Our findings demonstrate that different naturally occurring missense mutations identified in leukemia patients, changing a single amino acid within the SH2 domain, can either activate or inactivate STAT5B and thereby impact T cell populations.

Project description:Normal hematopoiesis is regulated by various cytokines via the JAK-STAT signaling pathway. Gene deletion studies in mice have demonstrated the crucial role of STAT5B in the proliferation, differentiation, and survival of immune cells. However, the physiological effects of human STAT5B mutations remain poorly understood. Mutations within the SH2 domain of STAT5B have been identified in leukemia patients. In this study, we investigate two specific variants: one that substitutes tyrosine 665 with phenylalanine (STAT5BY665F) and another that substitutes tyrosine 665 with histidine (STAT5BY665H). We introduced these two mutations into the mouse genome and observed distinct and divergent impacts on immune cell function. The STAT5BY665F mutation enhanced STAT5B activity and the establishment of transcriptional enhancers and genetic programs. Conversely, the STAT5BY665H mutation was largely inactive, failing to induce the interleukin-regulated enhancer landscape and gene expression. Both mutations modified immune cell profiles, inducing features characteristic of autoimmune disease. In STAT5BY665F mice, there was an expansion of CD8+ and regulatory CD4+ T cells, whereas STAT5BY665H mice didn’t. Both mutant strains exhibited skin abnormalities; however, only the STAT5BY665F mice developed progressive dermatitis. Introduction of equivalent mutations into STAT5A did not significantly impact hematopoiesis. However, mice carrying mutations in both STAT5A and STAT5B displayed additive effects with highly elevated CD4+ and CD8+ T cells. Our findings demonstrate that different naturally occurring missense mutations identified in leukemia patients, changing a single amino acid within the SH2 domain, can either activate or inactivate STAT5B and thereby impact T cell populations.

Project description:Normal hematopoiesis is regulated by various cytokines via the JAK-STAT signaling pathway. Gene deletion studies in mice have demonstrated the crucial role of STAT5B in the proliferation, differentiation, and survival of immune cells. However, the physiological effects of human STAT5B mutations remain poorly understood. Mutations within the SH2 domain of STAT5B have been identified in leukemia patients. In this study, we investigate two specific variants: one that substitutes tyrosine 665 with phenylalanine (STAT5BY665F) and another that substitutes tyrosine 665 with histidine (STAT5BY665H). We introduced these two mutations into the mouse genome and observed distinct and divergent impacts on immune cell function. The STAT5BY665F mutation enhanced STAT5B activity and the establishment of transcriptional enhancers and genetic programs. Conversely, the STAT5BY665H mutation was largely inactive, failing to induce the interleukin-regulated enhancer landscape and gene expression. Both mutations modified immune cell profiles, inducing features characteristic of autoimmune disease. In STAT5BY665F mice, there was an expansion of CD8+ and regulatory CD4+ T cells, whereas STAT5BY665H mice didn’t. Both mutant strains exhibited skin abnormalities; however, only the STAT5BY665F mice developed progressive dermatitis. Introduction of equivalent mutations into STAT5A did not significantly impact hematopoiesis. However, mice carrying mutations in both STAT5A and STAT5B displayed additive effects with highly elevated CD4+ and CD8+ T cells. Our findings demonstrate that different naturally occurring missense mutations identified in leukemia patients, changing a single amino acid within the SH2 domain, can either activate or inactivate STAT5B and thereby impact T cell populations.

Project description:T cells accumulate in the mammary gland during pregnancy and lactation. In order to understand the diversity, transcriptional states, TCR repertoire, and function of mammary gland T cells, and how these change during pregnancy and lactation compared to homeostasis, we performed single cell RNA sequencing on mammary gland T cells in mice.

Project description:Cross-species hybridization analysis of mammary glands during pregnancy and lactation. Results provide insight into putative conserved molecular mechanisms regulating mammary gland development. This study was performed to identify orthologous transcripts that are differentially co-expressed in the mammary gland at 2 stages of development (pregnancy and lactation) in wild type Sprague-Dawley rats.

Project description:Previously we have shown significant differences in lactation performance, mammary gland histology and expression profiles of mammary transcriptome during peak-lactation (lactation day 9; L9) between the ordinary CBA/CaH (CBA) and the superior QSi5 strains of mice. In the present study, we compared mammary gland histology between CBA and QSi5 at mid-pregnancy (pregnancy day 12; P12). We assessed lactation performance during the first 8 days of lactation of the 13th - 14th generation of the Advanced Intercross Line (AIL) (CBA X QSi5) mice. We utilized an integrative approach to analyzing mammary microarray expression profiles of CBA and QSi5 at P12 and CBA, AIL and QSi5 at L9. The inguinal mammary glands of CBA/CaH and QSi5 during mid-pregnancy (Pregnancy day 12; P12), and the glands of CBA/CaH, AIL and QSi5 during peak lactation (Lactation day 9; L9) were collected and total RNA was extracted for Affymetrix microarray (mouse genome 430 2) assay

Project description:Previously we have shown significant differences in lactation performance, mammary gland histology and expression profiles of mammary transcriptome during peak-lactation (lactation day 9; L9) between the ordinary CBA/CaH (CBA) and the superior QSi5 strains of mice. In the present study, we compared mammary gland histology between CBA and QSi5 at mid-pregnancy (pregnancy day 12; P12). We assessed lactation performance during the first 8 days of lactation of the 13th - 14th generation of the Advanced Intercross Line (AIL) (CBA X QSi5) mice. We utilized an integrative approach to analyzing mammary microarray expression profiles of CBA and QSi5 at P12 and CBA, AIL and QSi5 at L9.

Project description:Macrophages are involved in immune defense, organogenesis and tissue homeostasis. They also contribute to the different phases of mammary gland remodeling during development, pregnancy and involution post-lactation. Yet, less is known about the dynamics of mammary gland macrophages in the lactation stage. Here, we describe a macrophage population present during lactation in mice. By multi-parameter flow cytometry and single-cell RNA sequencing we reveal this population as distinct from the two resident macrophage subsets present pregestationally. These lactation-induced macrophages (LiMacs) are predominantly monocyte-derived and expand by proliferation in situ concomitant with nursing. LiMacs develop independently of IL-34 but require CSF-1 signaling and are partly microbiota-dependent. Locally, they reside adjacent to the basal cells of the alveoli and extravasate into the milk. Moreover, we also found several macrophage subsets in human milk, resembling LiMacs. Collectively, these findings reveal the emergence of unique macrophages in the mammary gland and milk during lactation.

Project description:Previoulsly miRNA expression profiling of the whole mammary gland across different stages of pregnancy and lactation has been performed in mice. Since mammary gland has both epithelial and stromal compartments, to specifically identify the miRNAs involved in the transition from pregnancy to lactation a process termed as secretory activation, expression profiling of isolated mammary epithelial cells (MECs) from four CD1 mice each at Pregnancy day 14 (P14) and Lactation day 2 (L2) was performed in the current study. Statistical analysis of the miRNA changes between P14 and L2 identified 32 miRNAs to be differentially expressed with a fold change greater than or equal to 2, of which, the majority of them declinied at the onset of lactation.