Protective Effect of Docetaxel Against Autophagy-Related Genes in Vitrification of Mouse Metaphase II Oocytes

Background: Autophagy is a conservative mechanism for cell survival as the main response of cells to stress conditions. The present study aimed to assess the effect of docetaxel on the survival, fertilization, and expression of autophagy-related genes in vitrified oocytes. Methods: The study was conducted in 2018 at the Stem Cells Technology Research Center, Shiraz University of Medical Sciences (Shiraz, Iran). Denuded oocytes were randomly selected and assigned to five groups, namely control (n=133), docetaxel (n=136), docetaxel+cryoprotectants (n=146), docetaxel+vitrification (n=138), and vitrification (n=145). The effect of vitrification on the expression of autophagy-related gene 5 (ATG5) and Beclin-1 was determined using a real-time polymerase chain reaction. Data were analyzed using SPSS software (version 26.0) and GraphPad Prism 9.Results: Survival and fertilization rates in each experimental group were significantly reduced compared to the control group (P=0.001). After in vitro fertilization of oocytes, the 2-cell formation rate was significantly reduced in the docetaxel+vitrification and vitrification groups compared to the control and docetaxel groups (P=0.001 and P=0.001, respectively). Pre-incubation of oocytes with docetaxel reduced gene expression levels of Beclin-1 and ATG5 in the docetaxel+cryoprotectants and docetaxel+vitrification groups (P=0.001 and P=0.019, respectively). The expression level of these genes was also reduced in the docetaxel group compared to the control group (P=0.001). Conclusion: Incubation of mouse metaphase II oocytes with docetaxel prior to vitrification reduced the expression of autophagy-related genes and increased survival and fertilization rates compared to untreated oocytes

Enhanced characterization of beta cell mass in a Tg(Pdx1-GFP) mouse model

Introduction: Measurement of pancreatic beta cell mass in animal models is a common assay in diabetes researches. Novel whole-organ clearance methods in conjunction with transgenic mouse models hold tremendous promise to improve beta cell mass measurement methods. Here, we proposed a refined method to estimate the beta cell mass using a new transgenic Tg(Pdx1-GFP) mouse model and a recently developed free-of-acrylamide clearing tissue (FACT) protocol. Methods: First, we generated and evaluated a Tg(Pdx1-GFP) transgenic mouse model. Using the FACT protocol in our model, we could quantify the beta cell mass and alloxan-induced beta cell destruction in whole pancreas specimens. Results: Compiled fluorescent images of pancreas resulted in enhanced beta cell mass characterization in FACT-cleared sections (2928869±120215 AU) compared to No-FACT cleared sections (1292372±325632 AU). Additionally, the total number of detected islets with this method was significantly higher than the other clearance methods (155.7 and 109, respectively). Using this method, we showed green fluorescent protein (GFP) expression confined to beta cells in Tg(Pdx1-GFP) transgenic. This enhanced GFP expression enabled us to accurately measure beta cell loss in a beta cell destruction model. The results suggest that our proposed method can be used as a simple, and rapid assay for beta cell mass measurement in islet biology and diabetes studies. Conclusion: The Tg(Pdx1-GFP) transgenic mouse in conjunction with the FACT protocol can enhance large-scale screening studies in the field of diabetes

Decellularized Lung Extracellular Matrix Scaffold Promotes Human Embryonic Stem Cell Differentiation towards Alveolar Progenitors

Objective: Efficient production of functional and mature alveolar epithelial is a major challenge for developing any cellreplacement therapy for lung degenerative diseases. The extracellular matrix (ECM) pro-vides a dynamic environmentand mediates cellular responses during development and maintenance of tissue functions. The decellularized ECM(dECM) which retains its native-like structure and bio-chemical composition can provide the induction of embryonicstem cell (ESC) differentiation toward the tissue-specific lineages during in vitro culture. Therefore, the aim of this studywas to evaluate the effect of sheep lung dECM-derived scaffold on differentiation and further maturation of ESC-derivedlung progenitor cells.Materials and Methods: This study was an experimental study. In the first step, a sheep lung was decellularizedto achieve dECM scaffolds and hydrogels. Afterwards, the obtained dECM scaffold was evaluated for collagen andglycosaminoglycan contents, DNA quantification, and its ultrastructure. Next, the three experimental groups: i. Sheeplung dECM-derived scaffold, ii. Sheep lung dECM-derived hydrogel, and iii. Fibronectin-coated plates were comparedin their abilities to induce further differentiation of human embryonic stem cells (hESCs)-derived definitive endoderm(DE) into lung progenitor cells. The comparison was evaluated by immuno-staining and real-time polymerase chainreaction (PCR) assessments.Results: We found that the dECM-derived scaffold preserved its composition and native porous structures whilelacking nuclei and intact cells. All experimental groups displayed lung progenitor cell differen-tiation as revealed by theRNA and protein expression of NKX2.1, P63 and CK5. DE cells differenti-ated on dECM-derived scaffold and dECMderivedhydrogel showed significant upregulation of SOX9 gene expression, a marker of the distal airway epithelium.DE cells differentiated on the dECM-derived scaffold compared to the two other groups, showed enhanced expressionof SFTPC (type 2 alveolar epithelial [AT2] cell marker), FOXJ1 (ciliated cell marker), and MUC5A (secretory cell marker)genes.Conclusion: Overall, our results suggest that dECM-derived scaffold improves the differentiation of DE cells towardslung alveolar progenitor cells in comparison with dECM-derived hydrogel and fibronectin-coated plates

A review on insulin trafficking and exocytosis

Insulin is a peptide hormone responsible for stable glycemia, is entirely secreting from pancreatic β cells at the core of glucose homeostatic regulation. Upon synthesis as preproinsulin on rough endoplasmic reticulum (rER), proinsulin is directed to trans Golgi apparatus. Subsequently, proinsulin packaging into secretory granules occurs in a dynamic and highly efficient process. During maturation stage of secretory granules, proinsulin undergoes cleavage and produces insulin and C-peptide upon acidification of the granules due to the activation of ATP-deriven proton pump. Fusion of the insulin containing secretory granules with the plasma membranes takes place after an increase in intracellular Ca2+. Finally, insulin is co-secreting with other components that are present in the secretory granules, including C-peptide, ATP, γ-aminobutyric acid (GABA), ghrelin and amylin. The other accompanying components of the insulin vesicles play important roles in the insulin secretion, insulin receptor activation and other homeostatic effects.. Responding to the glucose stimulation or increases in cytoplasmic Ca2+ levels, insulin secretion is immediately starts. Whereas, the second phase of insulin secretion is slow and continued, which reaches a plateau within 1-3 hours and lasts for longer period. In contrast to the first phase, the second phase of insulin secretion is independent of the extracellular glucose level. Finally, sequential or compound exocytosis of insulin is repressed to prevent sugar crash arising from excessive and sudden insulin secretion. In this paper we have reviewed the recent progress of molecular scenarios which are behind insulin biogenesis, intracellular sorting and exocytosis events.The first author was supported by grants from the Spanish Institute of Health Carlos III (PI16/00259, PI17/02104, and RD16/0011/0034) and co-financed by FEDER Funds

The Convenience of Single Homology Arm Donor DNA and CRISPR/Cas9-Nickase for Targeted Insertion of Long DNA Fragment

Objective: CRISPR/Cas9 technology provides a powerful tool for targeted modification of genomes. In this system, a donor DNA harboring two flanking homology arms is mostly used for targeted insertion of long exogenous DNA. Here, we introduced an alternative design for the donor DNA by incorporation of a single short homology arm into a circular plasmid. Materials and Methods: In this experimental study, single homology arm donor was applied along with a single guide RNA (sgRNA) specific to the homology region, and either Cas9 or its mutant nickase variant (Cas9n). Using Pdx1 gene as the target locus the functionality of this system was evaluated in MIN6 cell line and murine embryonic stem cells (ESCs). Results: Both wild type Cas9 and Cas9n could conduct the knock-in process with this system. We successfully applied this strategy with Cas9n for generation of Pdx1GFP knock-in mouse ESC lines. Altogether, our results demonstrated that a combination of a single homology arm donor, a single guide RNA and Cas9n is capable of precisely incorporating DNA fragments of multiple kilo base pairs into the targeted genomic locus. Conclusion: While taking advantage of low off-target mutagenesis of the Cas9n, our new design strategy may facilitate the targeting process. Consequently, this strategy can be applied in knock-in or insertional inactivation studies

Stauprimide Priming of Human Embryonic Stem Cells toward Definitive Endoderm

Objective: In vitro production of a definitive endoderm (DE) is an important issue in stem cell-related differentiation studies and it can assist with the production of more efficient endoderm derivatives for therapeutic applications. Despite tremendous progress in DE differentiation of human embryonic stem cells (hESCs), researchers have yet to discover universal, efficient and cost-effective protocols. Materials and Methods: In this experimental study, we have treated hESCs with 200 nM of Stauprimide (Spd) for one day followed by activin A (50 ng/ml; A50) for the next three days (Spd-A50). In the positive control group, hESCs were treated with Wnt3a (25 ng/ml) and activin A (100 ng/ml) for the first day followed by activin A for the next three days (100 ng/ml; W/A100-A100). Results: Gene expression analysis showed up regulation of DE-specific marker genes (SOX17, FOXA2 and CXCR4) comparable to that observed in the positive control group. Expression of the other lineage specific markers did not significantly change (p<0.05). We also obtained the same gene expression results using another hESC line. The use of higher concentrations of Spd (400 and 800 nM) in the Spd-A50 protocol caused an increase in the expression SOX17 as well as a dramatic increase in mortality rate of the hESCs. A lower concentration of activin A (25 ng/ml) was not able to up regulate the DE-specific marker genes. Then, A50 was replaced by inducers of definitive endoderm; IDE1/2 (IDE1 and IDE2), two previously reported small molecule (SM) inducers of DE, in our protocol (Spd-IDE1/2). This replacement resulted in the up regulation of visceral endoderm (VE) marker (SOX7) but not DE-specific markers. Therefore, while the Spd-A50 protocol led to DE production, we have shown that IDE1/2 could not fully replace activin A in DE induction of hESCs. Conclusion: These findings can assist with the design of more efficient chemically-defined protocols for DE induction of hESCs and lead to a better understanding of the different signaling networks that are involved in DE differentiation of hESCs

Combined inhibition of menin-MLL interaction and TGF-β signaling induces replication of human pancreatic beta cells

Both type 1 and type 2 diabetes are associated with hyperglycemia and loss of functional beta cell mass. Inducing proliferation of preexisting beta cells is an approach to increase the numbers of beta cells. In this study, we examined a panel of selected small molecules for their proliferation-inducing effects on human pancreatic beta cells. Our results demonstrated that a small molecule inhibitor of the menin-MLL interaction (MI-2) and small molecule inhibitors of TGF-β signaling (SB431542, LY2157299, or LY364947) synergistically increased ex vivo replication of human beta cells. We showed that this increased proliferation did not affect insulin production, as a pivotal indication of beta cell function. We further provided evidence which suggested that menin-MLL and TGF-β inhibition cooperated through downregulation of cell cycle inhibitors CDKN1A, CDKN1B, and CDKN2C. Our findings might provide a new option for extending the pharmacological repertoire for induction of beta cell proliferation as a potential therapeutic approach for diabetes

Role of gender in explaining metabolic syndrome risk factors in an Iranian rural population using structural equation modelling

Abstract Many factors can lead to an increase in the prevalence of metabolic syndrome (MetS) in different populations. Using an advanced structural equation model (SEM), this study is aimed to determine the most important risk factors of MetS, as a continuous latent variable, using a large number of males and females. We also aimed to evaluate the interrelations among the associated factors involved in the development of MetS. This study used data derived from the Fasa PERSIAN cohort study, a branch of the PERSIAN cohort study, for participants aged 35 to 70 years with 10,138 males and females. SEM was used to evaluate the direct and indirect effects, as well as gender effects of influencing factors. Results from the SEM showed that in females most changes in MetS are described by waist circumference (WC), followed by hypertension (HP) and triglyceride (TG), while in males most changes in MetS are described by WC, followed by TG then fasting blood glucose (FBG). Results from the SEM confirmed the gender effects of social status on MetS, mediated by sleep and controlled by age, BMI, ethnicity and physical activity. This study also shows that the integration of TG and WC within genders could be useful as a screening criterion for MetS in our study population

Hydrocortisone Promotes Differentiation of Mouse Embryonic Stem Cell-Derived Definitive Endoderm toward Lung Alveolar Epithelial Cells

Objective: The ability to generate lung alveolar epithelial type II (ATII) cells from pluripotent stem cells (PSCs) enables the study of lung development, regenerative medicine, and modeling of lung diseases. The establishment of defined, scalable differentiation methods is a step toward this goal. This study intends to investigate the competency of small molecule induced mouse embryonic stem cell-derived definitive endoderm (mESC-DE) cells towards ATII cells. Materials and Methods: In this experimental study, we designed a two-step differentiation protocol. mESC line Royan B20 (RB20) was induced to differentiate into DE (6 days) and then into ATII cells (9 days) by using an adherent culture method. To induce differentiation, we treated the mESCs for 6 days in serum-free differentiation (SFD) media and induced them with 200 nM small molecule inducer of definitive endoderm 2 (IDE2). For days 7-15 (9 days) of induction, we treated the resultant DE cells with new differentiation media comprised of 100 ng/ml fibroblast growth factor (FGF2) (group F), 0.5 μg/ml hydrocortisone (group H), and A549 conditioned medium (A549 CM) (group CM) in SFD media. Seven different combinations of factors were tested to assess the efficiencies of these factors to promote differentiation. The expressions of DE- and ATII-specific markers were investigated during each differentiation step. Results: Although both F and H (alone and in combination) promoted differentiation through ATII-like cells, the highest percentage of surfactant protein C (SP-C) expressing cells (~37%) were produced in DE-like cells treated by F+H+CM. Ultrastructural analyses also confirmed the presence of lamellar bodies (LB) in the ATII-like cells. Conclusion: These results suggest that hydrocortisone can be a promoting factor in alveolar fate differentiation of IDE2- induced mESC-DE cells. These cells have potential for drug screening and cell-replacement therapies