稳定表达ALB启动子及荧光素酶报告基因的肝干细胞株的构建

目的构建稳定表达ALB启动子及荧光素酶报告基因的肝干细胞株。方法PCR扩增获得ALB启动子,并与pBGLuc连接获得携带ALB启动子及荧光素酶报告基因的pBGLuc—ALB质粒,脂质体转染质粒到不同细胞,ALB—GLuc活性检测功能。构建逆转录病毒,感染HP14．5肝干细胞株获得携带ALB启动子及荧光素酶报告基因的稳定细胞株,经Dex、HGF体外诱导后第3、6、9、12天ALB—GLuc检测荧光素酶活性,免疫荧光检测ALB的表达。结果PCR、酶切及测序结果显示ALB启动子正确插入至荧光素酶GLuc基因上游,HEK293、HP14．5、LC14d及Hepa1-6细胞中ALB—GLuc活性与免疫荧光结果一致。HP14．5ALB—Gluc稳定细胞株在高浓度的稻瘟菌素中存活,免疫荧光结果显示Dex、HGF诱导后细胞中ALB的表达逐渐增强,并与ALB—Gluc活性升高一致。结论成功构建了稳定表达ALB启动子及荧光素酶报告基因的肝干细胞株,为研究肝干细胞的体外成熟分化提供了重要的细胞手段。     

Osteogenic and neurogenic differentiation of EGFP gene transfected neural stem cells derived from the brain of porcine fetuses at intermediate and late gestational age

The aims of this study were (i) to determine whether NSCs (neural stem cells) could be isolated from the brain of porcine fetuses at intermediate and late gestational age and (ii) to determine if these stem cells could be differentiated in vitro into osteogenic and neurogenic lineages following transfection with a reporter gene, EGFP (enhanced green fluorescence protein). The NSCs were isolated from the brains of porcine fetuses at intermediate and late gestational age and transfected with EGFP gene using lipofection. The transfected NSCs cells were induced to differentiate into cells of osteogenic and neurogenic lineages. Markers associated with NSCs and their osteogenic and neurogenic derivatives were tested by PCR. The results demonstrated that NSCs could be isolated from the brain of porcine fetus at intermediate and late gestational age and that transfected NSCs expressed EGFP and could be induced to differentiate in vitro. NSCs expressed CD‐90, Hes1, Oct4, Sox2 and Nestin, while following differentiation cells expressed markers for osteogenic (osteocalcin and osteonectin) and neurogenic cells such as astrocyte [GFAP (glial fibrillary acidic protein)], oligodendrocyte [GALC (galactosylceramide)] and neuron [NF (neurofilament), ENO2 (enolase 2) and MAP (microtubule‐associated protein)].     

A Human iPSC Double-Reporter System Enables Purification of Cardiac Lineage Subpopulations with Distinct Function and Drug Response Profiles

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Plasticity of distal nephron epithelia from human kidney organoids enables the induction of ureteric tip and stalk

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A case report: bone marrow mesenchymal stem cells from a Rett syndrome patient are prone to senescence and show a lower degree of apoptosis

Rett syndrome (RTT) is one of the most common genetic diseases responsible for a progressive disabling neurodevelopmental disorder. Mutations in the MeCP2 gene were identified in the great majority of RTT patients. MeCP2 protein binds to methylated DNA and produces changes in chromatin structure. This is a key event in regulation of gene expression. It has been suggested that MeCP2 might be important for neuronal development. Moreover, the frequent occurrence of osteoporosis and scoliosis in RTT patients suggests impaired bone formation and/or remodeling. Mesenchymal stem cells (MSCs) can differentiate as mesodermal cells such as bone, cartilage cells, and adipocytes. MSCs have been shown to possess great somatic plasticity; in fact, they can differentiate as neurons and astrocytes. We studied RTT patients' MSCs because they are progenitors of osteocytes, and it has been suggested that RTT patients' osteogenesis could be impaired. Moreover, MSCs might represent a useful model for the study of neurogenesis. MSCs from RTT patient showed precocious signs of senescence in a comparison with the MSCs of healthy-patient control groups. This was in agreement with the reduced gene-expression in the control of stem cell self-renewal and upregulation of lineage specific genes, such as those involved in osteogenesis and neural development. Control groups enabled us to observe a lower degree of apoptosis in RTT patient cells. This means that aberrant stem/progenitor cells, instead of being eliminated, can survive and become senescent. Our research provides a new insight into RTT syndrome. Senescence phenomena could be involved in triggering RTT syndrome-associated diseases.     

Multifaceted applications of nanomaterials in cell engineering and therapy

Nanomaterials with superior physiochemical properties have been rapidly developed and integrated in every aspect of cell engineering and therapy for translating their great promise to clinical success. Here we demonstrate the multifaceted roles played by innovatively-designed nanomaterials in addressing key challenges in cell engineering and therapy such as cell isolation from heterogeneous cell population, cell instruction in vitro to enable desired functionalities, and targeted cell delivery to therapeutic sites for prompting tissue repair. The emerging trends in this interdisciplinary and dynamic field are also highlighted, where the nanomaterial-engineered cells constitute the basis for establishing in vitro disease model; and nanomaterial-based in situ cell engineering are accomplished directly within the native tissue in vivo. We will witness the increasing importance of nanomaterials in revolutionizing the concept and toolset of cell engineering and therapy which will enrich our scientific understanding of diseases and ultimately fulfill the therapeutic demand in clinical medicine.     

The impact of reactive oxygen species and genetic mitochondrial mutations in Parkinson's disease

The exact pathogenesis of Parkinson's disease (PD) is still unknown and proper mechanisms that correspond to the disease remain unidentified. It is understood that PD is age-related; as age increases, the chance of onset responds accordingly. Although there are no current means of curing PD, the understanding of reactive oxygen species (ROS) provides significant insight to possible treatments. Complex I deficiencies of the respiratory chain account for the majority of unfavorable neural apoptosis generation in PD. Dopaminergic neurons are severely damaged as a result of the deficiency. Symptoms such as inhibited cognitive ability and loss of smooth motor function are the results of such impairment. The genetic mutations of Parkinson's related proteins such as PINK1 and LRRK2 contribute to mitochondrial dysfunction which precedes ROS formation. Various pathways are inhibited by these mutations, and inevitably causing neural cell damage. Antioxidants are known to negate the damaging effects of free radical overexpression. This paper expands on the specific impact of mitochondrial genetic change and production of free radicals as well as its correlation to the neurodegeneration in Parkinson's disease.