Species-level Microbiota of Biting Midges and Ticks from Poyang Lake.

Objective: The purpose of this study was to investigate the bacterial communities of biting midges and ticks collected from three sites in the Poyang Lake area, namely, Qunlu Practice Base, Peach Blossom Garden, and Huangtong Animal Husbandry, and whether vectors carry any bacterial pathogens that may cause diseases to humans, to provide scientific basis for prospective pathogen discovery and disease prevention and control. Methods: Using a metataxonomics approach in concert with full-length 16S rRNA gene sequencing and operational phylogenetic unit (OPU) analysis, we characterized the species-level microbial community structure of two important vector species, biting midges and ticks, including 33 arthropod samples comprising 3,885 individuals, collected around Poyang Lake. Results: A total of 662 OPUs were classified in biting midges, including 195 known species and 373 potentially new species, and 618 OPUs were classified in ticks, including 217 known species and 326 potentially new species. Surprisingly, OPUs with potentially pathogenicity were detected in both arthropod vectors, with 66 known species of biting midges reported to carry potential pathogens, including Asaia lannensis and Rickettsia bellii, compared to 50 in ticks, such as Acinetobacter lwoffii and Staphylococcus sciuri. We found that Proteobacteria was the most dominant group in both midges and ticks. Furthermore, the outcomes demonstrated that the microbiota of midges and ticks tend to be governed by a few highly abundant bacteria. Pantoea sp7 was predominant in biting midges, while Coxiella sp1 was enriched in ticks. Meanwhile, Coxiella spp., which may be essential for the survival of Haemaphysalis longicornis Neumann, were detected in all tick samples. The identification of dominant species and pathogens of biting midges and ticks in this study serves to broaden our knowledge associated to microbes of arthropod vectors. Conclusion: Biting midges and ticks carry large numbers of known and potentially novel bacteria, and carry a wide range of potentially pathogenic bacteria, which may pose a risk of infection to humans and animals. The microbial communities of midges and ticks tend to be dominated by a few highly abundant bacteria.

Creation of engineered cardiac tissue in vitro from mouse embryonic stem cells.

BACKGROUND: Embryonic stem (ES) cells can terminally differentiate into all types of somatic cells and are considered a promising source of seed cells for tissue engineering. However, despite recent progress in in vitro differentiation and in vivo transplantation methodologies of ES cells, to date, no one has succeeded in using ES cells in tissue engineering for generation of somatic tissues in vitro for potential transplantation therapy. METHODS AND RESULTS: ES-D3 cells were cultured in a slow-turning lateral vessel for mass production of embryoid bodies. The embryoid bodies were then induced to differentiate into cardiomyocytes in a medium supplemented with 1% ascorbic acid. The ES cell-derived cardiomyocytes were then enriched by Percoll gradient centrifugation. The enriched cardiomyocytes were mixed with liquid type I collagen supplemented with Matrigel to construct engineered cardiac tissue (ECT). After in vitro stretching for 7 days, the ECT can beat synchronously and respond to physical and pharmaceutical stimulation. Histological, immunohistochemical, and transmission electron microscopic studies further indicate that the ECTs both structurally and functionally resemble neonatal native cardiac muscle. Markers related to undifferentiated ES cell contamination were not found in reverse transcriptase-polymerase chain reaction analysis of the Percoll-enriched cardiomyocytes. No teratoma formation was observed in the ECTs implanted subcutaneously in nude mice for 4 weeks. CONCLUSIONS: ES cells can be used as a source of seed cells for cardiac tissue engineering. Additional work remains to demonstrate engraftment of the engineered heart tissue in the case of cardiac defects and its functional integrity within the host's remaining healthy cardiac tissue.

Construction of a unidirectionally beating 3-dimensional cardiac muscle construct.

BACKGROUND: Cardiac tissue engineering aims to construct cardiac tissue with characteristics similar to those of the native tissue. Engineered cardiac tissues (ECTs) can be constructed using synthetic scaffold or liquid collagen. We report an initial study using our own newly designed cardiac muscle device to construct heart tissue. We investigated the effects of cell seeding density and collagen quantity on the formation of liquid collagen-based cardiac muscle. METHODS: We obtained cardiac myocytes from neonatal rats mixed with collagen type I and matrix factors cast in circular molds to form circular strands. Cell densities (0.1 x 10(7) to 6 x 10(7)) and collagen quantity (0.3 to 1.0 ml/ECT) were tested. Cell gross morphology, cell orientation, spatial distribution and ultrastructure were evaluated using histologic analyses, confocal laser scanning microscopy and transmission electron microscopy. RESULTS: Histologic analyses of ECTs revealed that cardiac cells reconstituted longitudinally oriented, cardiac bundles with morphologic features characteristic of the native tissue. Confocal and electron microscopy demonstrated that, using optimized cell density and collagen quantity, we made ECTs with characteristic features similar to those of native differentiated myocardium. CONCLUSIONS: ECTs comparable to native cardiac tissue can be engineered under optimized conditions. This construct is a first step in the development of cardiac tissue engineered in vitro, and may be used as a basis for studies of cardiac development, drug testing and tissue replacement therapy.

[Experimental study of tissue-engineered heart tissue using type I collagen as scaffold].

OBJECTIVE: To construct tissue-engineered heart tissue (EHT) using liquid collagen as scaffold. METHODS: Neonatal rat cardiac myocytes were isolated, cultured, and mixed with liquid collagen type I and matrix factors and then cast in circular molds to construct circular cardiac myocytes/collagen strand. After a 7-day culture in circular molds, the strands were removed, and subjected to 10% static stretch for another 7 days. Microscopy and transmission electron microscopy, routine HE staining and immunohistochemical staining were used to analyze the engineered heart tissue. RESULTS: Beating areas could be seen on the surface of the EHTs at the second day after stretching; more beating areas could be seen thereafter. These areas beat stronger and stronger, and finally came to synchronzation. Histological and immunohistochemical analyses showed that the cardiac myocytes in the EHTs distributed evenly in the whole strand and the majority of the cells, with elongated nuclei, stretched along the stretching direction. The morphology of EHTs resembled that of the native adult cardiac tissue. Transmission electron microscopy revealed that the cardiac myocytes in EHTs contained arranged myofibrils oriented parallel to the longitudinal cell axis. Clearly defined sarcomeres and Z lines were observed. CONCLUSION: Liquid type I collagen is a good scaffold for generation of EHTs similar to the native heart tissue.