No abstract available.
Animals ; Coculture Techniques ; Fertilization in Vitro ; Mice*

No abstract available.
Animals ; Coculture Techniques* ; Embryonic Structures* ; Mice*

In recent years, the interaction mechanisms underpinning the synthetic microbial co-culture systems have gained increasing attention due to their potentials in various biotechnological applications. Exploration of the inter-species mechanisms underpinning the synthetic microbial co-culture system could contribute to a better understanding of the theoretical basis to further optimize the existing co-culture systems, and design new synthetic co-culture system for large-scale application. OMICS technologies such as genomics, transcriptomics, proteomics, and metabolomics could analyze the biological processes in a high throughput manner. Multi-omics analysis could achieve a "global view" of various members in the microbial co-culture systems, which presents opportunities in understanding synthetic microbial consortia better. This article summarizes recent advances in understanding the mechanisms of synthetic microbial co-culture systems using omics technologies, from the aspects of metabolic network, energy metabolism, signal transduction, membrane transport, stress response, community stability and structural rationality. All these findings could provide important theoretical basis for future application of the microbial co-culture systems with the aids of emerging biotechnologies such as synthetic biology and genome editing.
Coculture Techniques ; Genomics ; Metabolomics ; Proteomics ; Synthetic Biology

Intense utilization and mining of fossil fuels for energy production have resulted in environmental pollution and climate change. Compared to fossil fuels, microalgae is considered as a promising candidate for biodiesel production due to its fast growth rate, high lipid content and no occupying arable land. However, monocultural microalgae bear high cost of harvesting, and are prone to contamination, making them incompetent compared with traditional renewable energy sources. Co-culture system induces self-flocculation, which may reduce the cost of microalgae harvesting and the possibility of contamination. In addition, the productivity of lipid and high-value by-products are higher in co-culture system. Therefore, co-culture system represents an economic, energy saving, and efficient technology. This review aims to highlight the advances in the co-culture system, including the mechanisms of interactions between microalgae and other microorganisms, the factors affecting the lipid production of co-culture, and the potential applications of co-culture system. Finally, the prospects and challenges to algal co-culture systems were also discussed.
Biofuels ; Biomass ; Coculture Techniques ; Flocculation ; Microalgae

Traditional methods of microbial synthesis usually rely on a single engineered strain to synthesize the target product through metabolic engineering. The key cofactors, precursors and energy are produced by the introduced complex synthetic pathways. This would increase the physiological burden of engineering strains, resulting in a decrease in the yield of target products. The modular co-culture engineering has become an attractive solution for effective heterologous biosynthesis, where product yield can be greatly improved. In the modular co-culture engineering, the coordination between the population of different modules is essential for increasing the production efficiency. This article summarized recent advances in the application of modular co-culture engineering and population control strategies.
Coculture Techniques ; Metabolic Engineering ; Population Control

UNLABELLEDOBJECTIVE; The purpose of this study was to observe the influence on proliferation of rabbit osteoblast (ROB) of rabbit vascular endothelial cell(RVEC) co-cultured with rabbit osteoblast (ROB).

METHODSRabbit osteoblasts and rabbit vascular endothelial cells in ratio of 1:0, 1:1, 2:1, 4:1 were selected to co-culture. The function of osteoblasts was assessed by alkaline phosphatase (ALP) activity and osteocalcin (OC) assay.

RESULTSThere was good compatibility when osteoblasts and vascular endothelial cells were co-cultured. The activity of ALP and OC in the group of ROB and RVEC co-cultured in ratio of 2:1 was higher than that of the other three groups.

CONCLUSIONIn direct co-culture system in vitro, RVEC can improve activity of ROB.

OBJECTIVE: This study aimed to compare the cartilage regeneration of the stromal vascular fraction (SVF) cells and adipose-derived mesenchymal stem cells (ASCs) cocultured with chondrocytes seeded on the scaffolds. METHODS: The cellular morphologies and proliferation capabilities on the scaffolds were evaluated. The scaffolds with the cocul-ture of ASCs/SVF and chondrocytes were implanted into the full thickness cartilage defective rabbit joints for 10 weeks. RESULTS: The cells seeded into the scaffolds showed good adhesion and proliferation. Implantation with SVF and chondrocytes revealed desirable in vitro healing outcomes. CONCLUSIONS The SVF cells were better than ASCs in terms of the formation of cartilage matrix in a coimplantation model. Without in vitro expansion, the SVF cells are good cell sources for cartilage repair.
Adipose Tissue ; Animals ; Cartilage ; Chondrocytes ; Coculture Techniques ; Rabbits ; Regeneration

Objective To explore whether nano-vesicles derived from M1 macrophages (M1-NVs) can reprogram M2 macrophages into M1 phenotype and further affect the development of endometriosis (EMS). Methods Extracellular vesicles (EVs) were isolated from macrophage culture supernatant by differential centrifugation. Immunofluorescence cytochemistry was used to detect the expression of vimentin, CD31 and F4/80 to identify endometrial stromal cells (EMS-ESCs), HUVECs and polarized peritoneal macrophages of EMS patients. M1-NVs were prepared by filtering cell suspension through (5, 1, 0.4, 0.22)μm polycarbonate membrane filters after syringe aspiration at 0-4 DegreesCelsius. Flow cytometry was used to analyze the polarization of RAW264.7 mouse peritoneal macrophages in vitro, and reverse transcription PCR (RT-qPCR) was employed to detect mRNA expression of VEGF, CD86, interleukin-6 (IL-6), IL-1β, tumor necrosis factor α (TNF-α), arginase 1 (Arg1), CD163, CD206, and IL-10. PKH67-labeled M1-NVs were co-cultured with EMS-ESCs, HUVECs and macrophages. And tubule formation experiments were conducted to assess the impact of M1-NVs on the tubule formation of HUVECs. Transwell^TM invasion and migration assays were employed to evaluate changes in the migration and invasion abilities of EMS-ESCs. Results By monitoring the contents of NVs, it was found that NVs contained much more protein and other bioactive particles than the same amount of EVs; immunofluorescence staining results showed that PKH67 labeled M1-NVs were internalized by EMS-ESCs, HUVECs and macrophages when co-cultured. The results of flow cytometry and RT-qPCR multi-target analysis showed that after treatment with different concentrations of M1-NVs or M0-NVs, 20 μg/mL of M1-NVs could effectively reprogram M2 macrophages into M1 macrophages compared with M0-NVs. Transewell^TM results showed that compared with the blank group and M0-NVs group, the number of EMS-ESCs migrating from the upper chamber to the lower chamber after M1-NV treatment was significantly reduced, while the number of EMS-ESCs treated with M2NVs increased significantly. The invasion situation was similar to the migration situation, indicating that M1-NVs directly or indirectly inhibited invasion, migration and tubule formation of EMS-ESCs in vitro. Conclusion M1-NVs reprogrammes M2 macrophages into M1 macrophages by internalization of primary cells and macrophages, thereby inhibiting invasion, migration and angiogenesis of EMS-ESCs, and further hindering the occurrence and development of EMS.
Female ; Humans ; Animals ; Mice ; Endometriosis ; Macrophages ; Macrophages, Peritoneal ; Coculture Techniques

OBJECTIVETo find a better method for harvesting highly purified neurons by comparing three methods used for co-culture of neurons and astrocytes.

METHODSThe co-culture models of neurons and astrocytes were established by primary culture, Banker's co-culture method or Transwell cell-culture inserts. The neurons and astrocytes cultured in vitro were from neonatal rats.

RESULTSThe highly purified neurons were not harvested by primary culture because the neurons and astrocytes grew on the same cover slip and it was difficult to control the growth velocity of astrocytes. The highly purified neurons were harvested by Banker's co-culture method or the method using Transwell cell-culture inserts, but the procedure of the former was more complicated than that of the later.

CONCLUSIONSThe culture method using Transwell cell-culture inserts is recommended for the establishment of the co-culture system of neurons and astrocytes.

Coculture Techniques ; Hematopoietic Stem Cells ; cytology ; Humans ; Small Molecule Libraries