Long-chain saturated fatty acids in breast milk are associated with the pathogenesis of atopic dermatitis via induction of inflammatory ILC3s.

Breastfeeding influences the immune system development in infants and may even affect various immunological responses later in life. Breast milk provides a rich source of early nutrition for infant growth and development. However, the presence of certain compounds in breast milk, related to an unhealthy lifestyle or the diet of lactating mothers, may negatively impact infants. Based on a cohort study of atopic dermatitis (AD), we find the presence of damage-associated molecular patterns (DAMPs) activity in the mother's milk. By non-targeted metabolomic analysis, we identify the long-chain saturated fatty acids (LCSFA) as a biomarker DAMPs (+) breast milk samples. Similarly, a mouse model in which breastfed offspring are fed milk high in LCSFA show AD onset later in life. We prove that LCSFA are a type of damage-associated molecular patterns, which initiate a series of inflammatory events in the gut involving type 3 innate lymphoid cells (ILC3s). A remarkable increase in inflammatory ILC3s is observed in the gut, and the migration of these ILC3s to the skin may be potential triggers of AD. Gene expression analysis of ILC3s isolated from the gut reveal upregulation of genes that increase ILC3s and chemokines/chemokine receptors, which may play a role in ILC migration to the skin. Even in the absence of adaptive immunity, Rag1 knockout mice fed a high-LCSFA milk diet develop eczema, accompanied by increased gut ILC3s. We also present that gut microbiota of AD-prone PA milk-fed mice is different from non-AD OA/ND milk-fed mice. Here, we propose that early exposure to LCSFAs in infants may affect the balance of intestinal innate immunity, inducing a highly inflammatory environment with the proliferation of ILC3s and production of interleukin-17 and interleukin-22, these factors may be potential triggers or worsening factors of AD.

Effect of Cetrorelix administration on ovarian stimulation in aged mice.

In mice, ovarian stimulation via hormone administration is an effective method for obtaining many ova simultaneously, but its effect is reduced by the influence of aging. In this study, we demonstrate that this problem can be improved by administering the gonadotropin-releasing hormone antagonist Cetrorelix prior to ovarian stimulation. Before 12-month-old female mice were injected with 5 IU pregnant mare serum gonadotropin and 5 IU human chorionic gonadotropin, we administered 5 µg/kg Cetrorelix for 7 consecutive days (7 times) or 3 times once every 3 days. As a result, 8.7 ± 1.9 (mean ± SEM, n=10) and 9.8 ± 1.3 (n=10) oocytes were obtained, respectively, as opposed to 4.7 ± 1.2 oocytes (n=9) in the case of no administration. Collagen staining of ovarian tissue showed that Cetrorelix administration reduced the degree of fibrosis, which improved ovarian function. In addition, equivalent fertilization and fetal development rates between control and Cetrorelix-treated aged mouse-derived oocytes were confirmed by in vitro fertilization and embryo transfer (Fertilization rate; control: 92.2% vs. 3 times: 96.9%/7 times: 88.5%, Birth rate; control: 56.4% vs. 3 times: 58.3%/7 times: 51.8%), indicating the normality of the obtained oocytes. It is concluded that Cetrorelix improved the effect of superovulation in aged mice without reducing oocyte quality. This procedure will contribute to animal welfare by extending the effective utilization of aged female breeding mice.

The matrix vesicle cargo miR-125b accumulates in the bone matrix, inhibiting bone resorption in mice.

Communication between osteoblasts and osteoclasts plays a key role in bone metabolism. We describe here an unexpected role for matrix vesicles (MVs), which bud from bone-forming osteoblasts and have a well-established role in initiation of bone mineralization, in osteoclastogenesis. We show that the MV cargo miR-125b accumulates in the bone matrix, with increased accumulation in transgenic (Tg) mice overexpressing miR-125b in osteoblasts. Bone formation and osteoblasts in Tg mice are normal, but the number of bone-resorbing osteoclasts is reduced, leading to higher trabecular bone mass. miR-125b in the bone matrix targets and degrades Prdm1, a transcriptional repressor of anti-osteoclastogenic factors, in osteoclast precursors. Overexpressing miR-125b in osteoblasts abrogates bone loss in different mouse models. Our results show that the MV cargo miR-125b is a regulatory element of osteoblast-osteoclast communication, and that bone matrix provides extracellular storage of miR-125b that is functionally active in bone resorption.

Quality of common marmoset (Callithrix jacchus) oocytes collected after ovarian stimulation.

The common marmoset (Callithrix jacchus) is an experimental animal that is considered suitable for the creation of next-generation human disease models. It has recently been used in the reproductive technology field. Oocytes can be effectively collected from female marmosets via ovarian stimulation with injections of follicle-stimulating hormone (FSH) and human chorionic gonadotropin (hCG). The oocytes, collected about 28 h after the hCG injection, include both premature oocytes and postmature (in vivo matured; IVO) oocytes, and the premature oocytes can be matured by in vitro culture (in vitro matured; IVM). Although IVM and IVO oocytes are equivalent in appearance at the MII stage, it remains unclear whether there are differences in their properties. Therefore, we investigated their in vitro fertilization and developmental capacities and cytoskeletal statuses. Our findings revealed that the IVM and IVO oocytes had similar fertilization rates but that no IVO oocytes could develop to the blastocyst stage. Additionally, IVO oocytes showed abnormal cytoskeletal formation. It is concluded that IVM oocytes maintain normal function, whereas IVO oocytes would be affected by aging and other factors when they remain for a long time in the ovary.

Characterization of common marmoset (Callithrix jacchus) bone marrow-derived mesenchymal stem cells.

Mesenchymal stem cells (MSCs) could be useful for regenerative medicine because they can beharvested easily from the bone marrow of living donors and the cells can be differentiated into adipogenic, osteogenic, and chondrogenic lineages in vitro. To apply MSCs for the medical treatment of human diseases as regenerative medicine, detailed experimental characterization of the cells is required. Recently, a New World primate, the common marmoset (Callithrix jacchus), has been widely used as a new human disease model because of its ease of handling and breeding. Although common marmoset MSCs have been established and will be used in preclinical studies of regenerative medicine, the characteristics of these cells remain unclear. Aiming to characterize common marmoset MSCs further, we harvested common marmoset bone marrow-derived cells (cmBMDCs) from the femurs of newborn males. We revealed that the morphology of the cells was similar to common marmoset fibroblasts, and extracellular matrix components, such as gelatin and fibronectin, were effective for their proliferation and formation of colony-forming unit fibroblasts. Furthermore, we were able to differentiate cmBMDCs into adipocytes, osteocytes, and chondrocytes in vitro, and they expressed the MSCmarkers CD44, CD73, CD90, and CD105, but their expression decreased with increasing passage number. The data demonstrate that cmBMDCs exhibit characteristics of MSCs and thus it would be beneficial to use these cells in preclinical studies.

A methyl-deficient diet modifies early B cell development.

A functional methyl group donor is essential for the epigenetic regulation of all biological events due to the importance of DNA methylation and histone methylation as an epigenetic marker. However, the epigenetic alterations in the immune system due to methyl donor deficiency are not well known. In this study, we tried to address this question by studying the lymphocyte development and DNA methylation changes caused by a methyl-deficient diet (MDD). We fed one group of C57BL/6J mice with a methyl-sufficient diet (MSD) and the other group with an MDD for 5 months. Flow cytometry analyses of their immune systems showed a decrease in B220+ IgM+ (immature B) cells and an increase in B220+ IgM- (pro/pre-B) cells in the bone marrow of mice fed an MDD. By means of an in vitro OP9 coculture system, we recognized that this B220+ IgM- cell fraction from the MDD has an intrinsic developmental defect. When we quantitatively measured the mRNA expression levels of transcription factors and recombination machinery related to B cell development in the B220+ IgM- cell fraction of their bone marrow, we found that ADA, EBF1, DNTT and Pax5 mRNA expression levels were significantly downregulated in mice fed with an MDD. In addition, there was a drastic decrease in histone methylation profile H3K4me3 in the Pax5 and EBF1 promoters in these B220+ IgM- B cells. However, CpG-DNA methylation profiles had not changed and this revealed that these two promoters are demethylated even under an MSD condition. We also found changed expression levels of the Polycomb group genes (mel18, bmi1, Pc1, Pc2, Ring1A, Ring1B, Ph1) on semi-quantitative RT-PCR. These results indicate that under an MDD condition, early B cell development in bone marrow is easily affected by epigenetic alterations.

Mel-18 controls the enrichment of tumor-initiating cells in SP fraction in mouse breast cancer.

Side population (SP) cell analysis has been used to identify and isolate a minor population of cells with stem cell properties in normal tissues and in many cancers including breast cancer cells. However, the molecular mechanisms that operate in tumor-initiating cells (TICs) in SP fraction remain unclear. The Polycomb group genes, including Bmi1 and Mel-18, have been implicated in the maintenance of hematopoietic stem cells (HSCs) and suggested to be oncogenic and tumor suppressive, respectively, in breast cancer. In this study, we determined the critical role of Mel-18 in the enrichment mechanisms of TICs with the SP phenotype in a mouse breast cancer cell line, MMK3, that was established from a breast cancer developed spontaneously in Mel-18+/- mice. The Mel-18 protein expression level significantly correlates to the percentage of SP fraction in the mouse breast cancer cell line MMK3 series. The comparison between MMK3V3 (V3) cells containing one copy of the Mel-18 gene and MMK3S2 (S2) cells having twice the amount of Mel-18 expression clearly demonstrates the above relationship. Similar results obtained with the percentage of ALDH+ cells in V3 and S2 further confirmed the correlation between protein expression level of Mel-18 and the TICs. More importantly, transplantation of SP and non-SP cells of V3 and S2 cells into the NOD/SCID mice clearly showed that the heterozygous level of Mel-18 leads to the disappearance of enrichment of TICs into SP fraction in vivo. Stem cell pathway focused gene expression profiling of V3 and S2 cells revealed that the genes Abcg2, Aldh1a1 and Dhh were highly down-regulated in V3 compared to S2. These results indicate that the precise Mel-18 expression level controls TIC enrichment mechanisms through the regulation of channel molecule of Abcg2 and functional TIC marker of Aldhlal. In conclusion, our findings revealed the significance of fine-tuning mechanisms for Mel-18 protein expression level in the maintenance of TIC into SP fractions in mouse breast cancer.

Incisor enamel formation is impaired in transgenic rats overexpressing the type III NaPi transporter Slc20a1.

Inorganic phosphate (Pi) is required in many biological processes, including signaling cascades, skeletal development, tooth mineralization, and nucleic acid synthesis. Recently, we showed that Pi transport in osteoblasts, mediated by Slc20a1, a member of the type III sodium-dependent phosphate transporter family, is indispensable for osteoid mineralization in rapidly growing rat bone. In addition, we found that bone mineral density decreased slightly with dysfunction of Pi homeostasis in aged transgenic rats overexpressing mouse Slc20a1 (Slc20a1-Tg). Bone and tooth share certain common molecular features, and thus, we focused on tooth development in Slc20a1-Tg mandibular incisors in order to determine the role of Slc20a1 in tooth mineralization. Around the time of weaning, there were no significant differences in serologic parameters between wild-type and Slc20a1-Tg rats. However, histological analysis showed that Slc20a1-Tg ameloblasts formed clusters in the papillary layer during the maturation stage as early as 4 weeks of age. These pathologies became more severe with age and included the formation of cyst-like or multilayer ameloblast structures, accompanied by a chalky white appearance with abnormal attrition and fracture. Hyperphosphatemia was also observed in aging Slc20a1-Tg rats. Micro-computed tomography and electron probe microanalysis revealed impairments in enamel, such as delayed mineralization and hypomineralization. Our results suggest that enamel formation is sensitive to imbalances in Pit1-mediated cellular function as seen in bone, although these processes are under the control of systemic Pi homeostasis.

Preimplantation development of somatic cell cloned embryos in the common marmoset (Callithrix jacchus).

The somatic cell nuclear transfer technique has been applied to various mammals to produce cloned animals; however, a standardized method is not applicable to all species. We aimed here to develop optimum procedures for somatic cell cloning in nonhuman primates, using common marmosets. First, we confirmed that parthenogenetic activation of in vitro matured oocytes was successfully induced by electrical stimulation (three cycles of 150 V/mm, 50 microsec x 2, 20 min intervals), and this condition was applied to the egg activation procedure in the subsequent experiments. Next, nuclear transfer to recipient enucleated oocytes was performed 1 h before, immediately after, or 1 h after egg activation treatment. The highest developmental rate was observed when nuclear transfer was performed 1 h before activation, but none of the cloned embryos developed beyond the eight-cell stage. To investigate the causes of the low developmental potential of cloned embryos, a study was performed to determine whether the presence of metaphase II (MII) chromosome in recipient ooplasm has an effect on developmental potential. As a result, only tetraploid cloned embryos produced by transferring a donor cell into a recipient bearing the MII chromosome developed into blastocysts (66.7%). In contrast, neither parthenogenetic embryos nor cloned embryos (whether diploid or tetraploid) produced using enucleated oocytes developed past the eight-cell stage. These results suggest that MII chromosome, or cytoplasm proximal to the MII chromosome, plays a major role in the development of cloned embryos in common marmosets.

Mapping of A gene responsible for cataract formation and its modifier in the UPL rat.

PURPOSE: The Upjohn Pharmaceuticals Limited (UPL) rat is a unique model for cataracts, which are inherited as an autosomal semidominant trait and expressed as early-onset (E-type) cataracts in homozygotes and as late-onset (L-type) cataracts in heterozygotes. In this study, a gene and its modifier, which are responsible for formation of cataract, were mapped. METHODS: Fifty-five BN x (BN x UPL)F(1) backcross rats and 133 BN x UPL intercross rats were produced. The cataracts present in the rats at eye opening were diagnosed as E-type. Cataracts that developed after eye opening were diagnosed as L-type, and the ages when complete opacity in the lens was observed were used as a quantitative trait to map a gene that modifies the development of mature cataracts. Linkage analysis was performed using 64 arbitrarily primed-representational difference analysis (AP-RDA) markers and 74 microsatellite markers. RESULTS: A gene responsible for the formation of cataract was mapped to the vicinity of D2Rat134 on rat chromosome (chr) 2. A candidate gene, connexin 50 (Cx50/Gja8), had a C-to-T transition at codon 340 that is predicted to result in a nonconservative substitution of arginine by tryptophan. Recombination in the Cx50 genotype and formation of cataract was not observed. By quantitative trait loci analysis, a gene that modified the age of the development of mature cataract was mapped on rat chr 5. CONCLUSIONS: A candidate gene for formation of cataracts in UPL rats was mapped to rat chr 2, and the Cx50 gene was a strong candidate. In addition, a potential modifier gene was mapped on chr 5. Future cloning of these genes will provide good targets for new therapies that can delay the progression of cataracts.