Serotonin (5-HT) has been reported to play an important role in mammary gland involution that is defined as the process through which the gland returns to a nonlactating state. However, the overall picture of the regulatory mechanisms of 5-HT and the effects of serotonylation on mammary gland involution still need to be further investigated. The current study aimed to investigate the effects of 5-HT on global gene expression profiles of bovine mammary epithelial cells (MAC-T) and to preliminarily examine whether the serotonylation involved in the mammary gland involution by using Monodansylcadaverine (MDC), a competitive inhibitor of transglutaminase 2. Results showed that a high concentration of 5-HT decreased viability and transepithelial electrical resistance (TEER) in MAC-T cells. Transcriptome analysis indicated that 2477 genes were differentially expressed in MAC-T cells treated with 200 μg/mL of 5-HT compared with the control group, and the Notch, p53, and PI3K-Akt signaling pathways were enriched. MDC influenced 5-HT-induced MAC-T cell death, fatty acid synthesis, and the formation and disruption of tight junctions. Overall, a high concentration of 5-HT is able to accelerate mammary gland involution, which may be regulated through the Notch, p53, and PI3K-Akt signaling pathways. Serotonylation is involved in bovine mammary gland involution.

This study conducted transcriptome sequencing of goat-mammary-gland tissue at the late lactation (LL), dry period (DP), and late gestation (LG) stages to reveal the expression characteristics and molecular functions of circRNAs during mammary involution. A total of 11,756 circRNAs were identified in this study, of which 2528 circRNAs were expressed in all three stages. The number of exonic circRNAs was the largest, and the least identified circRNAs were antisense circRNAs. circRNA source gene analysis found that 9282 circRNAs were derived from 3889 genes, and 127 circRNAs\' source genes were unknown. Gene Ontology (GO) terms, such as histone modification, regulation of GTPase activity, and establishment or maintenance of cell polarity, were significantly enriched (FDR < 0.05), which indicates the functional diversity of circRNAs\' source genes. A total of 218 differentially expressed circRNAs were identified during the non-lactation period. The number of specifically expressed circRNAs was the highest in the DP and the lowest in LL stages. These indicated temporal specificity of circRNA expression in mammary gland tissues at different developmental stages. In addition, this study also constructed circRNA-miRNA-mRNA competitive endogenous RNA (ceRNA) regulatory networks related to mammary development, immunity, substance metabolism, and apoptosis. These findings help understand the regulatory role of circRNAs in mammary cell involution and remodeling.

Peak lactation occurs when milk production is at its highest. The factors limiting peak lactation performance have been subject of intense debate. Milk production at peak lactation appears limited by the capacity of lactating females to dissipate body heat generated as a by-product of processing food and producing milk. As a result, manipulations that enhance capacity to dissipate body heat (such as fur removal) increase peak milk production. We investigated the potential correlates of shaving-induced increases in peak milk production in laboratory mice. By transcriptomic profiling of the mammary gland, we searched for the mechanisms underlying experimentally increased milk production and its consequences for mother-young conflict over weaning, manifested by advanced or delayed involution of mammary gland. We demonstrated that shaving-induced increases in milk production were paradoxically linked to reduced expression of some milk synthesis-related genes. Moreover, the mammary glands of shaved mice had a gene expression profile indicative of earlier involution relative to unshaved mice. Once provided with enhanced capacity to dissipate body heat, shaved mice were likely to rear their young to independence faster than unshaved mothers.

Long noncoding RNA (lncRNA) can regulate mammary gland development and lactation physiological activities. However, the molecular genetic mechanisms of lncRNA in mammary gland involution and cell remodeling remain unclear. This work analyzed the expression characteristics and molecular functions of lncRNA in goat mammary gland tissue at the late lactation (LL), dry period (DP), and late gestation (LG) stages. Sequencing results showed that 3074 lncRNAs were identified in non-lactating goat mammary gland tissue. Statistical analysis of lncRNA length characteristics and exon number found that goat lncRNAs were shorter in length, had fewer exons, and significantly lower expression levels than those of protein-coding genes. 331 differentially expressed lncRNAs were identified in the three comparison groups (LLvsDP, DPvsLG, and LLvsLG), which indicated that the lncRNAs expression at the transcriptional level were changed during mammary involution. Interestingly, lncRNAs were more actively expressed during the dry period compared to lactation, suggesting that lncRNAs in mammary glands are developmentally specific. Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analyses revealed that lncRNAs could regulate immune function, cell proliferation, apoptosis, hormones, substance metabolism, transport, and intercellular communication in the mammary gland through various action modes. Among them, cis-acting lncRNAs enhanced the protection of mammary gland health during the dry period and late gestation. The above reflects the particular mechanisms of lncRNA to adapt to the developmental needs of mammary involution and remodeling. Furthermore, in the lncRNA-miRNA-mRNA network associated with mammary gland development, the expression of LOC102168552 was higher in late gestation than in the dry period and late lactation. Its expression was positively correlated with PRLR and negatively correlated with chi-miR-324-3p. Overexpression of LOC102168552 in goat mammary epithelial cells cultured in vitro could up-regulate PRLR to activate the prolactin signaling pathway by competitively binding to chi-miR-324-3p, promoting cell proliferation, reducing cell cycle arrest in the G1 / S phase, and inhibiting apoptosis. However, overexpression of LOC102168552 alone did not affect mammary cell growth status and the prolactin signaling pathway. This indicates that LOC102168552 must rely on chi-miR-324-3p to inhibit mammary cell apoptosis. In conclusion, the above analysis revealed that lncRNAs in goat mammary tissue are differentially expressed at different stages of involution. As expected, lncRNAs adaptively regulate various physiological activities during mammary gland involution through multiple modes of action, in preparation for a new round of lactation. These findings provide a reference and help further understand the regulatory role of lncRNAs in mammary cell involution and remodeling.

The mammary gland redevelops to the prepregnancy state during involution, which shows the mammary cells have the characteristics of remodeling. The rapidity and degree of mammary gland involution vary across species (e.g., between model organism mice and dairy livestock). However, the molecular genetic mechanism of involution and remodeling of goat mammary gland has not yet been clarified. This work investigated the structural changes and transcriptome characteristics of the mammary gland tissue of nonlactating dairy goats during the late lactation (LL), the dry period (DP), and late gestation (LG). Terminal deoxynucleotidyl transferase dUTP nick-end labeling (TUNEL) staining revealed significant changes in the structure of the nonlactating goat mammary gland, and obvious cell apoptosis occurred at LL and DP. Sequencing identified 1,381 genes that are differentially expressed in mammary gland tissue at the 3 developmental stages. Genes related to cell growth, apoptosis, immunity, nutrient transport, synthesis, and metabolism exhibited adaptive transcriptional changes to meet the needs of a new set of mammary gland lactation functions. The significant enrichment of Gene Ontology terms such as humoral immune response, complement activation, and neutrophil-mediated immunity indicates that the innate immune system plays an important role in maintaining the health of degenerative mammary glands and eliminating apoptotic cells. The peroxisome proliferator-activated receptor signaling pathway plays an important regulatory role in lipid metabolism, especially the adaptive changes in expression of genes encoded lipid transport and enzymes, which promote the formation of milk fat during the lactation. The mammary gland development gene module revealed that pregnancy hormone receptors, cell growth factors and their receptors, and genes encoding insulin-like growth factor binding proteins regulate the physiological process of mammary gland involution through adaptive transcriptional changes. Interestingly, ERBB4 was identified as the hub gene of the network that regulates mammary gland growth and development. Overexpression of ERBB4 in mammary epithelial cells cultured in vitro can reduce cell cycle arrest in G1/S phase and apoptosis by regulating the PI3K/Akt signaling pathway and promote the proliferation of mammary epithelial cells. The gene ERBB4 also affects the expression of genes that initiate mammary gland involution and promote mammary gland remodeling. These findings contribute to an in-depth understanding of the molecular mechanisms involved in mammary gland involution and remodeling.

MicroRNAs play an essential role in mammary gland development, and involution is a factor that limits lactation. Chi-miR-8516 is one of the validated microRNAs that regulates the expression of STC1 and MMP1, which surge during the involution of the mammary gland. This study aims to explore the direct or indirect regulation of STC1 and MMP1 by chi-miR-8516 and the regulation of chi-miR-8516 by circ-140. In goat mammary epithelial cells, we found that chi-miR-8516 takes circ-140 as a sponge and regulates MMP1 expression by targeting STC1 and promoting the phosphorylation of MAPK. The examination of αs1-/β-casein and lipid showed the modulation of the circ-140/chi-miR-8516/STC1-MMP1 axis in casein secretion and lipid formation, which was regulated by the phosphorylation of mTOR and STAT5. This study illustrates an axis that regulates the synthesis of milk components, and explores the pathways in which the axis participates.