Polycystic ovary syndrome (PCOS) is a prevalent endocrine disorder in women that is a leading cause of infertility. Follicular development disorder, as the main cause of oligoovulation, is the key factor affecting the fertility of PCOS patients. Among them, the disorder of the ovarian microenvironment is an important inducement for follicular development disorder. Emerging research highlights that the ovarian microenvironment plays a sophisticated role in follicular development and maturation through various mechanisms, including the cellular constituents within the ovary, the extracellular matrix's structural support, adequate vascular supply, and the regulation of hormonal and growth factor signaling. These factors collectively ensure the normal growth and ovulation of follicles, thereby safeguarding female reproductive health. In women with PCOS, however, the ovarian microenvironment is compromised, leading to excessive extracellular matrix deposition and fibrosis, abnormalities in vascular architecture and function, immune-inflammatory reactions, and metabolic disturbances. These anomalies collectively hinder follicular growth and development, resulting in ovulation disorders. This comprehensive review will delve into the intricacies of these disruptions and their implications for fertility in PCOS patients.

DNA methylation is an important epigenetic modification in mammals, playing a crucial role in various physiological processes, including cell differentiation and the gene expression regulation. The ten-eleven translocation (TET) protein family of DNA demethylases is integral to the regulation of DNA methylation, as it catalyzes the oxidation of 5-methylcytosine to form 5-hydroxymethylcytosine. During early embryonic development, the genome undergoes extensive DNA demethylation, and any aberration in this reprogramming process can result in abnormal embryonic development and physiological defects in offspring. The TET proteins, due to their unique dynamics and multifaceted roles, facilitate DNA demethylation and are involved in development and maturation of germ cells, the establishment of pluripotency, cell lineage differentiation, and transcriptional processes throughout mammalian embryogenesis. Furthermore, these proteins are closely associated with the maintenance of pregnancy and susceptibility of progeny to disease. Factors such as genetic mutations, maternal health conditions, and exposure to adverse environmental influences can impact TET protein activity, resulting in abnormal patterns of DNA demethylation. A comprehensive investigation of the related mechanisms of TET proteins is essential for enhancing our understanding of epigenetic regulation during early life, diagnosing and treating related diseases such as early fetal development retardation, and informing strategies for the prevention and management of pregnancy.This article reviews the regulatory role of DNA demethylation mediated by TET protein in mammalian embryonic development and pregnancy outcomes.

Aichivirus,also known as kobuvirus(KoV),is a newly identified genus within the family of small RNA viruses.In 2019,the KoVs were classified into six types including Aichiviru A,B,C,D,E and F by International Committee on Taxonomy of Viruses.Aichivirus C infect goats and pigs.Aichivirus C infection in goats has been detected in four countries,including the United States,South Korea,Italy,and China,demonstrating a wide geographic distribution.In 2019,our la-boratory isolated strains of goat Aichivirus C from fecal samples of goats suffering from diarrhea for the first time,confirming it as a new pathogen responsible for diarrhea in lambing goats.This virus is already endemic in several provinces and regions of China.In this paper,we review the pathogenic characteristics,viral genomic features,prevalence,clinical symptoms and pathological changes as well as detection methods,with the aim of providing a reference for further research on Aichivirus C in goats.

Polycystic ovary syndrome (PCOS) is a prevalent endocrine disorder in women that is a leading cause of infertility. Follicular development disorder, as the main cause of oligoovulation, is the key factor affecting the fertility of PCOS patients. Among them, the disorder of the ovarian microenvironment is an important inducement for follicular development disorder. Emerging research highlights that the ovarian microenvironment plays a sophisticated role in follicular development and maturation through various mechanisms, including the cellular constituents within the ovary, the extracellular matrix's structural support, adequate vascular supply, and the regulation of hormonal and growth factor signaling. These factors collectively ensure the normal growth and ovulation of follicles, thereby safeguarding female reproductive health. In women with PCOS, however, the ovarian microenvironment is compromised, leading to excessive extracellular matrix deposition and fibrosis, abnormalities in vascular architecture and function, immune-inflammatory reactions, and metabolic disturbances. These anomalies collectively hinder follicular growth and development, resulting in ovulation disorders. This comprehensive review will delve into the intricacies of these disruptions and their implications for fertility in PCOS patients.

DNA methylation is an important epigenetic modification in mammals, playing a crucial role in various physiological processes, including cell differentiation and the gene expression regulation. The ten-eleven translocation (TET) protein family of DNA demethylases is integral to the regulation of DNA methylation, as it catalyzes the oxidation of 5-methylcytosine to form 5-hydroxymethylcytosine. During early embryonic development, the genome undergoes extensive DNA demethylation, and any aberration in this reprogramming process can result in abnormal embryonic development and physiological defects in offspring. The TET proteins, due to their unique dynamics and multifaceted roles, facilitate DNA demethylation and are involved in development and maturation of germ cells, the establishment of pluripotency, cell lineage differentiation, and transcriptional processes throughout mammalian embryogenesis. Furthermore, these proteins are closely associated with the maintenance of pregnancy and susceptibility of progeny to disease. Factors such as genetic mutations, maternal health conditions, and exposure to adverse environmental influences can impact TET protein activity, resulting in abnormal patterns of DNA demethylation. A comprehensive investigation of the related mechanisms of TET proteins is essential for enhancing our understanding of epigenetic regulation during early life, diagnosing and treating related diseases such as early fetal development retardation, and informing strategies for the prevention and management of pregnancy.This article reviews the regulatory role of DNA demethylation mediated by TET protein in mammalian embryonic development and pregnancy outcomes.

Aichivirus,also known as kobuvirus(KoV),is a newly identified genus within the family of small RNA viruses.In 2019,the KoVs were classified into six types including Aichiviru A,B,C,D,E and F by International Committee on Taxonomy of Viruses.Aichivirus C infect goats and pigs.Aichivirus C infection in goats has been detected in four countries,including the United States,South Korea,Italy,and China,demonstrating a wide geographic distribution.In 2019,our la-boratory isolated strains of goat Aichivirus C from fecal samples of goats suffering from diarrhea for the first time,confirming it as a new pathogen responsible for diarrhea in lambing goats.This virus is already endemic in several provinces and regions of China.In this paper,we review the pathogenic characteristics,viral genomic features,prevalence,clinical symptoms and pathological changes as well as detection methods,with the aim of providing a reference for further research on Aichivirus C in goats.