Embryonic Cells Research Articles

Isolation and identification of a novel goose-origin reovirus GD218 and its pathogenicity experiments

Since 2020, a novel goose-derived reovirus, characterized by goose hemorrhagic hepatitis, has emerged in the goose breeding industry of Guangdong province, China, leading to significant economic losses in the poultry sector. To study the genetic variation of novel goose reovirus (NGRV) in Guangdong province, this experiment utilized goose embryonic fibroblast cells for virus isolation. RT-PCR was conducted to identify, amplify, clone, and sequence the complete genome of the NGRV isolated from Zhaoqing. The genomic sequences were compared with reference strains to construct a phylogenetic tree. Moreover, animal pathogenicity, excretion patterns, and pathological sections were examined. The results showed that liver and spleen samples from geese suspected of NGRV infection were used for isolation, resulting in the identification of a reovirus presumed to originate from geese, designated as GD218. In terms of genomic structure and sequence homology, GD218 closely resembles the novel duck reovirus, differing significantly from earlier isolated NDRV strains (J18, NP03, SD12, etc.) in genetic composition (nt: 80.6–97.9%, aa: 94.3–98.9%). However, it is similar to strains isolated after 2018, such as XT18, SY, QR, YL, LY20, etc. (nt: 95.3–98.9%, aa: 98.6–99.7%). Therefore, based on phylogenetic analysis, GD218 is hypothesized to be a novel type of goose-origin reovirus homologous to the novel duck reovirus.

Apoptosis, inflammatory and innate immune responses induced by infection with a novel goose astrovirus in goose embryonic kidney cells

IntroductionSince 2016, a highly lethal visceral gout induced by infection with the novel goose astrovirus (GoAstV) resulted in an ongoing outbreak in goslings in China, with a mortality rate ranging from 10% to 50%, and causing considerable economic losses in the goose industry. However, the pathogenesis of GoAstV and the molecular mechanism by which kidney lesions are induced by GoAstV infection are unclear.MethodsIn the present study, a GEK cell infection model for GoAstV was established, and the apoptosis, inflammatory and innate immune responses induced by GoAstV were investigated in GEK cells.ResultsThe results shown that the expression of proapoptotic proteins, including Bax, caspase-3, caspase-9 and cytochrome c, increased in the infection group; however, the expression of the antiapoptotic protein Bcl-2 decreased, indicating that apoptosis was induced by GoAstV infection in GEK cells. Besides, the activation of the RIG-I/MDA5 pathway and the downstream upregulation of proinflammatory cytokines, including the adapter proteins MAVS, IRF7 and NF-κB and the proinflammatory cytokines IL-6, IL-8 and TNF-α, were detected in GEK cells infected with GoAstV. In addition, GoAstV infection induces the activation of the NLPR3 pathway and further stimulates the increased production of IL-1β. In summary, the present study revealed that GoAstV infection could induce apoptosis and the activation of the RIG-I/MDA5 and NLRP3 pathways in GEK cells, as well as the massive release of proinflammatory cytokines.DiscussionThese results are helpful for elucidating the molecular mechanism of pathological lesions in the kidney in gout goslings infected with GoAstV and the interaction between GoAstV and the innate immune system of the host.

Distinct role of Klotho in long bone and craniofacial bone: skeletal development, repair and regeneration.

Bone defects are highly prevalent diseases caused by trauma, tumors, inflammation, congenital malformations and endocrine abnormalities. Ideally effective and side effect free approach to dealing with bone defects remains a clinical conundrum. Klotho is an important protein, which plays an essential role in regulating aging and mineral ion homeostasis. More recently, research revealed the function of Klotho in regulating skeleton development and regeneration. Klotho has been identified in mesenchymal stem cells, osteoblasts, osteocytes and osteoclasts in different skeleton regions. The specific function and regulatory mechanisms of Klotho in long bone and craniofacial bone vary due to their different embryonic development, ossification and cell types, which remain unclear and without conclusion. Moreover, studies have confirmed that Klotho is a multifunctional protein that can inhibit inflammation, resist cancer and regulate the endocrine system, which may further accentuate the potential of Klotho to be the ideal molecule in inducing bone restoration clinically. Besides, as an endogenous protein, Klotho has a promising potential for clinical therapy without side effects. In the current review, we summarized the specific function of Klotho in long bone and craniofacial skeleton from phenotype to cellular alternation and signaling pathway. Moreover, we illustrated the possible future clinical application for Klotho. Further research on Klotho might help to solve the existing clinical difficulties in bone healing and increase the life quality of patients with bone injury and the elderly.

The Fatal Mushroom Neurotoxin Muscarine is Released from a Harmless Phosphorylated Precursor upon Cellular Injury

l‐(+)‐Muscarine (1)‐producing mushrooms pose a severe threat to human health as ingestion can result in circulatory collapse or even death. However, their metabolic profile is surprisingly poorly understood, including knowledge of poison release and potentially toxic congeners. In the mycelium of the 1‐producing fool’s funnel mushroom Clitocybe rivulosa, we identified 4’‐phosphomuscarine (2) as the major natural product. Its structure was elucidated by high‐resolution mass spectrometry, nuclear magnetic resonance spectroscopy and by comparison with a synthesized reference. We also detected this previously overlooked phosphorylated compound in the fiber cap mushrooms Pseudosperma spectrale and Inocybe nitidiuscula. Studies on the activation of the muscarinic acetylcholine receptor M3 indicate only weak affinity of 2 to this target. Furthermore, we present biological evidence that muscaridine (3), a quaternary amine congener related to and co‐occurring with 1, does not activate the muscarinic acetylcholine receptor M3 on human embryonic kidney cells. Our work provides important insight into the metabolic profile and the pharmacology of some of the most poisonous mushrooms. As the harmless 2 can liberate the potentially fatal 1 by unspecific enzymatic ester cleavage, these results are highly relevant for emergency medicine to estimate the true toxicity of these mushrooms.

The Fatal Mushroom Neurotoxin Muscarine is Released from a Harmless Phosphorylated Precursor upon Cellular Injury.

l-(+)-Muscarine (1)-producing mushrooms pose a severe threat to human health as ingestion can result in circulatory collapse or even death. However, their metabolic profile is surprisingly poorly understood, including knowledge of poison release and potentially toxic congeners. In the mycelium of the 1-producing fool's funnel mushroom Clitocybe rivulosa, we identified 4'-phosphomuscarine (2) as the major natural product. Its structure was elucidated by high-resolution mass spectrometry, nuclear magnetic resonance spectroscopy and by comparison with a synthesized reference. We also detected this previously overlooked phosphorylated compound in the fiber cap mushrooms Pseudosperma spectrale and Inocybe nitidiuscula. Studies on the activation of the muscarinic acetylcholine receptor M3 indicate only weak affinity of 2 to this target. Furthermore, we present biological evidence that muscaridine (3), a quaternary amine congener related to and co-occurring with 1, does not activate the muscarinic acetylcholine receptor M3 on human embryonic kidney cells. Our work provides important insight into the metabolic profile and the pharmacology of some of the most poisonous mushrooms. As the harmless 2 can liberate the potentially fatal 1 by unspecific enzymatic ester cleavage, these results are highly relevant for emergency medicine to estimate the true toxicity of these mushrooms.

Apigenin as a Promising Agent for Enhancing Female Reproductive Function and Treating Associated Disorders.

Apigenin is an organic flavonoid abundant in some plants such as parsley, chamomile, or celery. Recently, it has been investigated for several of its pharmacological characteristics, such as its ability to act as an antioxidant, reduce inflammation, and inhibit the growth of cancer cells. The purpose of this review is to provide a summary of the existing knowledge regarding the effects of apigenin on female reproductive systems and its dysfunctions. Apigenin can influence reproductive processes by regulating multiple biological events, including oxidative processes, cell proliferation, apoptosis, cell renewal and viability, ovarian blood supply, and the release of reproductive hormones. It could stimulate ovarian folliculogenesis, as well as ovarian and embryonal cell proliferation and viability, which can lead to an increase in fertility and influence the release of reproductive hormones, which may exert its effects on female reproductive health. Furthermore, apigenin could inhibit the activities of ovarian cancer cells and alleviate the pathological changes in the female reproductive system caused by environmental pollutants, harmful medications, cancer, polycystic ovarian syndrome, ischemia, as well as endometriosis. Therefore, apigenin may have potential as a biostimulator for female reproductive processes and as a therapeutic agent for certain reproductive diseases.

Human stem cell-specific epigenetic signatures control transgene expression

Human stem cell-derived models have emerged as an important platform to study tissue differentiation and disease mechanisms. Those models could capitalize on biochemical and cell biological methodologies such as omics, autophagy, and organelle dynamics. However, epigenetic silencing in stem cells creates a barrier to apply genetically encoded tools. Here we investigate the molecular mechanisms underlying exogenously expressed gene silencing by employing multiple commonly used promoters in human induced pluripotent stem cells (iPSCs), glioblastoma cells (GBM), and embryonic kidney cells (HEK). We discover that all promoters tested are highly methylated on the CpG island regions with lower protein expression in iPSCs, as compared to non-iPSCs. Elongation factor 1 alpha short (EF1α short or EFS) promoter, which has fewer CpG island number compared to the other promoters, can drive relatively higher gene expression in iPSCs, despite CpG methylation. Adding a minimal A2 ubiquitous chromatin opening element (minimal A2 UCOE or miniUCOE) upstream of a promoter inhibits CpG methylation and enhances gene expression in iPSCs. Our results demonstrate stem cell type-specific epigenetic modification of transgenic promoter region and provide useful information for designing anti-silencing strategies to increase transgene expression in iPSCs.

Insights into the molecular characteristics of embryonic cranial neural crest cells and their derived mesenchymal cell pools

Neural crest cells (NCCs) are central to vertebrate embryonic development, giving rise to diverse cell types with unique migratory and differentiation capacities. This study examines the molecular characteristics of cranial neural crest cell (CNCC)-derived mesenchymal cells, specifically those from teeth which in deer show continuous but limited growth, and antlers, which exhibit remarkable regenerative capabilities. Here, through single-cell RNA sequencing analysis, we uncover shared gene expression profiles between adult antlerogenic and dental mesenchymal cells, indicating common developmental pathways. We identify a striking resemblance in transcriptomic features between antlerogenic progenitor cells and dental pulp mesenchymal cells. Comparative analysis of CNCC-derived and non-CNCC-derived mesenchymal cell pools across species reveals core signature genes associated with CNCCs and their derivatives, delineating essential connections between CNCCs and CNCC-derived adult mesenchymal pools. Furthermore, whole-genome DNA methylation analysis unveils hypomethylation of CNCC derivate signature genes in regenerative antlerogenic periosteum, implying a role in maintaining multipotency. These findings offer crucial insights into the developmental biology and regenerative potential of CNCC-derived mesenchymal cells, laying a foundation for innovative therapeutic strategies in tissue regeneration.

What is the real value of omics data? Enhancing research outcomes and securing long-term data excellence.

A wealth of high-throughput biological data, of which omics constitute a significant fraction, has been made publicly available in repositories over the past decades. These data come in various formats and cover a range of species and research areas providing insights into the complexities of biological systems; the public repositories hosting these data serve as multifaceted resources. The potentially greater value of these data lies in their secondary utilization as the deployment of data science and artificial intelligence in biology advances. Here, we critically evaluate challenges in secondary data use, focusing on omics data of human embryonic kidney cell lines available in public repositories. The emerging issues are obstacles faced by secondary data users across diverse domains as they concern platforms and repositories, which accept deposition of data irrespective of their species type. The evolving landscape of data-driven research in biology prompts re-evaluation of open access data curation and submission procedures to ensure that these challenges do not impede novel research opportunities through data exploitation. This paper aims to draw attention to widespread issues with data reporting and encourages data owners to meticulously curate submissions to maximize not only their immediate research impact but also the long-term legacy of datasets.

Genetic and developmental divergence in the neural crest program between cichlid fish species.

Neural crest (NC) is a vertebrate-specific embryonic progenitor cell population at the basis of important vertebrate features such as the craniofacial skeleton and pigmentation patterns. Despite the wide-ranging variation of NC-derived traits across vertebrates, the contribution of NC to species diversification remains underexplored. Here, leveraging the adaptive diversity of African Great Lakes' cichlid species, we combined comparative transcriptomics and population genomics to investigate the evolution of the NC genetic program in the context of their morphological divergence. Our analysis revealed substantial differences in transcriptional landscapes across somitogenesis, an embryonic period coinciding with NC development and migration. This included dozens of genes with described functions in the vertebrate NC gene regulatory network, several of which showed signatures of positive selection. Among candidates showing between-species expression divergence, we focused on teleost-specific paralogs of the NC-specifier sox10 (sox10a and sox10b) as prime candidates to influence NC development. These genes, expressed in NC cells, displayed remarkable spatio-temporal variation in cichlids, suggesting their contribution to inter-specific morphological differences, such as craniofacial structures and pigmentation. Finally, through CRISPR/Cas9 mutagenesis, we demonstrated the functional divergence between cichlid sox10 paralogs, with the acquisition of a novel skeletogenic function by sox10a. When compared to teleost models zebrafish and medaka, our findings reveal that sox10 duplication, although retained in most teleost lineages, had variable functional fates across their phylogeny. Altogether, our study suggests that NC-related processes - particularly those controlled by sox10s - are involved in generating morphological diversification between species and lays the groundwork for further investigations into the mechanisms underpinning vertebrate NC diversification.

Novel human PDX1 Asn196Thr variant causes pancreas agenesis and reduces the generation of duodenal enteroendocrine cells

Abstract Introduction/Objective Pancreatic and duodenal homeobox 1 (PDX1) is a well-studied transcription factor required for pancreas organogenesis. PDX1 mutations are associated with the development of diabetes. An 8-month-old female patient with previously uncharacterized compound heterogeneous PDX1 missense mutations (Thr151Met and Asn196Thr) was identified in this study. The patient has permanent neonatal diabetes, pancreas hypoplasia, and a malformed gallbladder. Methods/Case Report PDX1 Thr151Met and Asn196Thr variants in the patient were identified by next-generation sequencing gene panel and confirmed by Sanger sequencing. To examine how the mutations affect PDX1 functions in vitro, we expressed mouse Pdx1 Thr152Met and Asn197Thr, homologous to human PDX1 Thr151Met and Asn196Thr, respectively, in mouse insulinoma MIN6 cells and human embryonic kidney 293T cells and examined protein localization, protein stability, DNA binding, and protein-protein interaction. We also generated embryonic day 18 mouse embryos carrying Pdx1 Asn197Thr missense mutation using CRISPR/Cas9 to examine its roles in the development of the pancreas and other digestive organs in vivo. Results (if a Case Study enter NA) We found that the Pdx1 Asn197Thr variant, but not Thr152Met, altered its nuclear localization and disrupted PDX1-Onecut 1 interaction. Neither variant significantly affected PDX1 protein stability, but both reduced PDX1 binding to the Pdx1 gene promoter. Importantly, we found that the Pdx1 Asn197Thr variant caused pancreas agenesis and a reduction in the generation of enteroendocrine cells in the proximal duodenum in mouse models. Conclusion Our data indicated that the PDX1 Asn196Thr variant impairs its DNA binding and protein-protein interaction, causing pancreas agenesis and a reduction in the generation of duodenal enteroendocrine cells.

INVESTIGATING CUDC-101 EFFECT AND MECHANISM OF ACTION AGAINST GLIOBLASTOMA IN VITRO

Abstract AIMS Glioblastoma (GB) has complex pathophysiology, difficult treatment and resultant poor prognosis. Its median survival rate is approximately 15 months. The aggressive nature of GB results in rapid disease progression in 60-70% patients often within 12 weeks. Limited treatment options include maximal safe surgical resection, followed by radiotherapy and temozolomide (TMZ). The blood brain barrier restricts chemotherapeutic entry and increases dosage leading to increased side effects and decreased treatment tolerance. Furthermore, significant disease heterogeneity means reoccurrence is expected in most cases, for which there are no standard treatment routes. This coupled with inefficient treatment with temozolomide (TMZ) due to the blood brain barrier, highlights the requirement for novel treatments. METHOD Histone deacetylases (HDAC) and endothelial growth factor receptor (EGFR) are mutated and upregulated in GB allowing tumour infiltration and proliferation. CUDC-101 is known to target both HDAC and EGFR in other cancers making it a promising therapeutic to trial in GB. Cell viability of U251, T98G and U87MG human cells was measured post-CUDC-101 administration at 24, 48 and 72hrs. SVGp19 embryonic non-cancerous human glial cells were used as a control to establish CUDC-101 preliminary specificity. Targeting another major hallmark of GB, wound healing assays were performed to assess CUDC-101 capacity to inhibit migration. In addition to this, long-term cellular resistance was investigated through clonogenic assays. Western blotting was then used to identify non-/treated expression levels of activated EGFR and acetylated histone H3. Expression levels in non/-treated cells were then visualised with fluorescent microscopy. In addition, flow cytometry was utilised to observe cell cycle changes. RESULTS Overall, results indicate CUDC-101 has a dose-dependent effect on cell viability (long-term and short-term) and migration. Additionally, fluorescent images show treatment does increase histone acetylation and decrease total EGFR. CONCLUSION Future work will solidify these datasets and show changes in activated EGFR and acetylated histone H3 using western blotting.

A fascination with tailless mice: a scientific historical review of studies of the T/t complex.

The T/t complex of the mouse attracted many of the major figures of mouse genetics to perform genetic, cytogenetic, physiological, biochemical and molecular biological studies of it. These studies started with the discovery of short tailed mutants (Ts) and recessive lethal developmental mutations (ts) which mapped to the same "locus" in the early 1920s in France. However, due to the non-receptivity of French scientists to genetics, they continued to be studied in mostly Anglophone countries to be joined by a wider international community in the 1970s. These discoveries led to developmental studies of the lethal mutants which provided the origin of mammalian developmental genetics. The fascinating property of transmission ratio distortion (non-50/50 segregation of alleles in offspring of males) elicited tremendous interest. There were false leads (that the region consisted of unusual DNA, that the alleles controlled cell surface antigens on embryonic cells and spermatozoa) and exciting discoveries. This historical review provides a review of this extensive area of research and some of the individuals involved in it.

Effects of cadherin mediated contact normalization on oncogenic Src kinase mediated gene expression and protein phosphorylation

Nontransformed cells form heterotypic cadherin junctions with adjacent transformed cells to inhibit tumor cell growth and motility. Transformed cells must override this form of growth control, called “contact normalization”, to invade and metastasize during cancer progression. Heterocellular cadherin junctions between transformed and nontransformed cells are needed for this process. However, specific mechanisms downstream of cadherin signaling have not been clearly elucidated. Here, we utilized a β-catenin reporter construct to determine if contact normalization affects Wnt signaling in transformed cells. β-catenin driven GFP expression in Src transformed mouse embryonic cells was decreased when cultured with cadherin competent nontransformed cells compared to transformed cells cultured with themselves, but not when cultured with cadherin deficient nontransformed cells. We also utilized a layered culture system to investigate the effects of oncogenic transformation and contact normalization on gene expression and oncogenic Src kinase mediated phosphorylation events. RNA-Seq analysis found that cadherin dependent contact normalization inhibited the expression of 22 transcripts that were induced by Src transformation, and increased the expression of 78 transcripts that were suppressed by Src transformation. Phosphoproteomic analysis of cells expressing a temperature sensitive Src kinase construct found that contact normalization decreased phosphorylation of 10 proteins on tyrosine residues that were phosphorylated within 1 h of Src kinase activation in transformed cells. Taken together, these results indicate that cadherin dependent contact normalization inhibits Wnt signaling to regulate oncogenic kinase activity and gene expression, particularly PDPN expression, in transformed cells in order to control tumor progression.

Transcriptional coactivator MED15 is required for beta cell maturation

Mediator, a co-regulator complex required for RNA Polymerase II activity, interacts with tissue-specific transcription factors to regulate development and maintain homeostasis. We observe reduced Mediator subunit MED15 expression in endocrine hormone-producing pancreatic islets isolated from people living with type 2 diabetes and sought to understand how MED15 and Mediator control gene expression programs important for the function of insulin-producing β-cells. Here we show that Med15 is expressed during mouse β-cell development and maturation. Knockout of Med15 in mouse β-cells causes defects in β-cell maturation without affecting β-cell mass or insulin expression. ChIP-seq and co-immunoprecipitation analyses found that Med15 binds β-cell transcription factors Nkx6-1 and NeuroD1 to regulate key β-cell maturation genes. In support of a conserved role during human development, human embryonic stem cell-derived β-like cells, genetically engineered to express high levels of MED15, express increased levels of maturation markers. We provide evidence of a conserved role for Mediator in β-cell maturation and demonstrate an additional layer of control that tunes β-cell transcription factor function.

Exceptional stability of the sugammadex-solasodine complex: Insights from experimental and theoretical studies

Sugammadex (SGM) is the first cyclodextrin (CD)-based selective relaxant binding agent. We investigated its ability to capture natural aminosteroid phytotoxins, and assessed its potential as an antidote for intoxication. Solasodine (SS), a toxic alkaloid from the Solanaceae family, was chosen as the model compound. Complexation was studied using nuclear magnetic resonance (NMR) spectroscopy, molecular modelling, and isothermal titration calorimetry (ITC). NMR in various D2O/DMSO‑d6 media revealed a particularly stable inclusion-type complex, identifying a slow exchange process between the CD and the aminosteroid along with a less significant fast exchange between DMSO and SGM. Using various NMR techniques, the structure and kinetic/thermodynamic parameters of the inclusion complex were explored. Theoretical calculations showed the secondary amino head of SS near the carboxylate ends of the SGM sidechains, facilitating intermolecular ionic interactions. ITC experiments in an aqueous environment provided Ka stability constants of 7.03 × 106 M−1 and 4.17 × 106 M−1 at 25 °C and 37 °C, respectively, similar to previously reported SGM complexes with aminosteroid neuromuscular blockers. Finally, SGM significantly increased cell survival and reduced SS toxicity in mHippoE-14 mouse hippocampal embryonic cells, supporting the hypothesis that SGM could act as an antidote to SS's toxic effects.

9271 Cholinergic Signaling in the Mouse Embryonic Pancreas Targets Early Endocrine Cells

Abstract Disclosure: C. Duarte: None. J.K. Panzer: None. N. Borowsky: None. A. Caicedo: None. The parasympathetic vagus nerve affects pancreas function by activating local intrapancreatic neurons that release acetylcholine (ACh). These neurons are derived from progenitors of the vagal neural crest and colonize the pancreas during embryonic development. The specific mechanisms by which ACh is released from these neurons influence embryonic development of the islet and, specifically, beta cells remain largely unknown. The purpose of this study was to identify cholinergic signaling components and assess early physiological responses to ACh during murine development of endocrine lineage cells. We extracted pancreatic rudiments from mice at embryonic stages E15 to E18 and stained them for neuronal and endocrine markers, along with components associated with cholinergic signaling. We further performed Ca2+ imaging of the pancreatic rudiments from NGN3CRE-GCaMP3 mice to record responses to ACh in cells of the endocrine lineage. At E15, we observed a significantly higher concentration of glucagon+ cells compared to insulin+ cells, consistent with the earlier differentiation of alpha cells in the developing pancreas. Neuronal body clusters were identified in close proximity to endocrine lineage cells from E15 to E18, with the neuronal network becoming more dispersed and interconnected. At E15, wide distribution of the presynaptic vesicular acetylcholine transporter (VAChT) was observed later becoming localized around insulin+ and glucagon+ cells at E18. Postsynaptic acetylcholinesterase (AChE) colocalized with glucagon+ cells from E15 to E18 and with insulin+ cells by E18. ACh elicited Ca2+ responses in individual endocrine cells as early as E15. Our results show that cholinergic nerve terminals target early endocrine cells and elicit responses to ACh, indicating that local cholinergic neurons innervate and activate endocrine progenitors in the embryonic pancreas. Our current studies are aimed at determining how cholinergic signaling contributes to beta cell differentiation and function. We expect this knowledge to guide future protocols for deriving beta cells from stem cells. Presentation: 6/2/2024

8715 Cholinergic Signaling in the Mouse Embryonic Pancreas Targets Early Endocrine Cells

Abstract Disclosure: C. Duarte: None. J.K. Panzer: None. N. Borowsky: None. A. Caicedo: None. The parasympathetic vagus nerve affects pancreas function by activating local intrapancreatic neurons that release acetylcholine (ACh). These neurons are derived from progenitors of the vagal neural crest and colonize the pancreas during embryonic development. The specific mechanisms by which ACh is released from these neurons influence embryonic development of the islet and, specifically, beta cells remain largely unknown. The purpose of this study was to identify cholinergic signaling components and assess early physiological responses to ACh during murine development of endocrine lineage cells. We extracted pancreatic rudiments from mice at embryonic stages E15 to E18 and stained them for neuronal and endocrine markers, along with components associated with cholinergic signaling. We further performed Ca2+ imaging of the pancreatic rudiments from NGN3CRE-GCaMP3 mice to record responses to ACh in cells of the endocrine lineage. At E15, we observed a significantly higher concentration of glucagon+ cells compared to insulin+ cells, consistent with the earlier differentiation of alpha cells in the developing pancreas. Neuronal body clusters were identified in close proximity to endocrine lineage cells from E15 to E18, with the neuronal network becoming more dispersed and interconnected. At E15, wide distribution of the presynaptic vesicular acetylcholine transporter (VAChT) was observed later becoming localized around insulin+ and glucagon+ cells at E18. Postsynaptic acetylcholinesterase (AChE) colocalized with glucagon+ cells from E15 to E18 and with insulin+ cells by E18. ACh elicited Ca2+ responses in individual endocrine cells as early as E15. Our results show that cholinergic nerve terminals target early endocrine cells and elicit responses to ACh, indicating that local cholinergic neurons innervate and activate endocrine progenitors in the embryonic pancreas. Our current studies are aimed at determining how cholinergic signaling contributes to beta cell differentiation and function. We expect this knowledge to guide future protocols for deriving beta cells from stem cells. Presentation: 6/2/2024

Highly efficient photocatalysis-Fenton degradation of antibiotics and phenol over sulfidated FeOCl under natural sunlight illumination

Sulfidated FeOCl is prepared as a heterogeneous photo-Fenton catalyst. And the surface sulfidation of FeOCl can remarkably accelerate the photoinduced charge separation and transfer, while also increase Fe2+/Fe3+ atomic ratio, leading to the boosted photo-Fenton activity in the presence of H2O2. Under irradiation of natural sunlight (light intensity: ∼80 mW·cm−2), over 10 mg sulfidated FeOCl catalyst with using 20 μL 15 % H2O2, 91.2 % of ofloxacin solution (50 mg·L−1) and 97.5 % of sulfisoxazole solution (60 mg·L−1) can be degraded in 80 min, and 99.6 % of phenol solution (625 mg·L−1) is decomposed in 4 h. Under irradiation of a white Light-Emitting Diode (LED) lamp (light intensity: 5 mW·cm−2), 99.8 % of ofloxacin solution is decomposed after treatment for 4 h. Moreover, this photo-Fenton degradation system displays a stable activity in a wide range of pH (1−10), diverse water bodies, and various coexisting ions with concertation from 1 mM to 500 mM. Moreover, sulfidated FeOCl catalyst coated on a frosted glass sheet exhibits excellent stability for degrading ofloxacin even in seven continuous cycles. Particularly, the non-toxicity of the treated ofloxacin, sulfisoxazole, and phenol solution, have been proven by testing their toxic effects on cabbage seed, bacteria, and human embryonic kidney cell, respectively.

Loss of Cell-Cell Contact Inhibits Cellular Differentiation of α-Catenin Knock Out P19 Embryonal Carcinoma Cells and Their Colonization into the Developing Mouse Embryos.

Cadherin-catenin cell-cell adhesion complexes, composed of cadherin, β-catenin or plakoglobin, and α-catenin (α-cat) molecules, are crucial for maintaining cell-cell contact and are commonly referred to as "adherens junctions (AJs)." Inactivating this system leads to loss of cell-cell contact and developmental arrest in early embryos. However, it remains unclear whether the loss of cell-cell contact affects the differentiation of embryonic cells. In this study, we explored the use of a murine embryonal carcinoma cell line, P19, as an in vitro model for early embryogenesis. P19 cells easily form embryoid bodies (EBs) and are susceptible to cellular differentiation in response to retinoic acid (RA) and teratoma formation. Using CRISPR/Cas9 technology to disrupt the endogenous α-cat gene in P19 cells, we generated α-cat knockout (KO) cells that exhibited a loss of cell-cell contact. When cultivated on non-coated dishes, these α-cat KO cells formed EBs, but their structures were labile. In the RA-containing medium, the α-cat KO EBs failed to produce differentiated cells on their outer layer and continued to express SSEA-1, an antigen specific to pluripotent cells. Teratoma formation assays revealed an absence of overt differentiated cells in tumors derived from α-cat KO P19 cells. Aggregation assays revealed the inability of the KO cells to colonize into the zona pellucida-denuded 8-cell embryos. These findings suggest that the AJs are essential for promoting the early stages of cellular differentiation and for the colonization of early-developing embryos.