Involvement of the Hippo pathway in regeneration and fibrogenesis after ischaemic acute kidney injury: YAP is the key effector.

Renal tubule cells can recover after they undergo AKI (acute kidney injury). An incomplete repair of renal tubules can result in progressive fibrotic CKD (chronic kidney disease). Studies have revealed the relationship between tubular epithelial cells and kidney fibrogenesis. However, the underlying mechanism remains unclear. Hippo pathway components were evaluated in complete/incomplete repair of I/R (ischaemia/reperfusion) AKI rat models, HK-2 cells and AKI human renal biopsy samples. We found that the expression levels of the Hippo pathway components changed dynamically during kidney regeneration and fibrogenesis in rat models of I/R-induced AKI and human renal biopsy samples. The transcription cofactor YAP (Yes-associated protein) might be a key effector of renal regeneration and fibrogenesis. Our results showed further that YAP might elicit both beneficial and detrimental effects on I/R AKI. After I/R injury occurred, YAP could promote the repair of the injured epithelia. The constant YAP increase and activation might be related to interstitial fibrosis and abnormal renal tubule differentiation. These results indicate that the proper modulation of the Hippo pathway, specifically the transcription cofactor YAP, during repair might be a potent therapeutic target in AKI-CKD transition after I/R injury.

Knockout of glutathione peroxidase 5 down-regulates the piRNAs in the caput epididymidis of aged mice.

The mammalian epididymis not only plays a fundamental role in the maturation of spermatozoa, but also provides protection against various stressors. The foremost among these is the threat posed by oxidative stress, which arises from an imbalance in reactive oxygen species and can elicit damage to cellular lipids, proteins, and nucleic acids. In mice, the risk of oxidative damage to spermatozoa is mitigated through the expression and secretion of glutathione peroxidase 5 (GPX5) as a major luminal scavenger in the proximal caput epididymidal segment. Accordingly, the loss of GPX5-mediated protection leads to impaired DNA integrity in the spermatozoa of aged Gpx5-/- mice. To explore the underlying mechanism, we have conducted transcriptomic analysis of caput epididymidal epithelial cells from aged (13 months old) Gpx5-/- mice. This analysis revealed the dysregulation of several thousand epididymal mRNA transcripts, including the downregulation of a subgroup of piRNA pathway genes, in aged Gpx5-/- mice. In agreement with these findings, we also observed the loss of piRNAs, which potentially bind to the P-element-induced wimpy testis (PIWI)-like proteins PIWIL1 and PIWIL2. The absence of these piRNAs was correlated with the elevated mRNA levels of their putative gene targets in the caput epididymidis of Gpx5-/- mice. Importantly, the oxidative stress response genes tend to have more targeting piRNAs, and many of them were among the top increased genes upon the loss of GPX5. Taken together, our findings suggest the existence of a previously uncharacterized somatic piRNA pathway in the mammalian epididymis and its possible involvement in the aging and oxidative stress-mediated responses.

[Expression of human ß-defensin and its relationship with inflammatory factor in human dental pulp tissue].

PURPOSE: To investigate the expression of human ß-defensin(HBD) in human dental pulp tissue and to explore the regulation of HBD in pulp inflammation and the relationship among HBD family members. METHODS: The gene expression of HBD in human dental pulp tissue was assessed in NCBI GEO profiles and was verified by RT-PCR. Human dental pulp cells were stimulated with TNF-α, IL-1α, IL-1ß and IL-6 in different combinations and the expression of HBD2 was analyzed by qPCR. Human dental pulp cells were pretreated with HBD110 and then stimulated with LPS and the expression of TNF-α,IL-1α and HBD2 were analyzed by qPCR. GraphPad Prism 5.01 was used to analyze the results of the experimental and the control groups. RESULTS: 27 HBDs were found to express in human dental pulp tissue in NCBI GEO Profiles. The joint overexpression of TNF-α, IL-1α, IL-1ß and IL-6 increased the expression of HBD2; HBD110 increased the expression of HBD2 by increasing the expression of TNF-α and IL-1α. CONCLUSIONS: Many other HBDs have positive expression in human dental pulp issue besides of HBD1, HBD2, HBD3, HBD4 and the inflammation factors and other HBDs can regulate the expression of HBD2 in dental pulp.

[The establishment of conditional MT transgenic mice model].

OBJECTIVE: To construct the doxycycline-inducible MT transgenic mice model, and provide a basis for the study of hemangioma as well as MT molecular function in vivo. METHODS: Tetracycline-controlled expression systems were employed to this study. A conditional transgenic vector combining the two transcriptional units on a single plasmid was constructed, and the MT gene was subcloned into this vector. To minimize any potential interference, the two elements were spaced with a 1.2 kb cHS4 insulator. To shield the transgene from the affection of chromosomal position effect and improve its expression efficiency, another cHS4 insulator was inserted into the upstream of transgene cassette. After transient transfection of cells in vitro, and analyzing the relative quantification of MT transcripts (target) in mRNA samples by semi-quantitative RT-PCR method, the pronuclear microinjection technique was used to introduce the purified transgene into the chromosomes of fertilized mice eggs, in order to obtain transgenic positive animals. The MT expression in positive mouse was induced through adding deoxycycline in drinking water. Phenotype analysis was done by pathology, and MT expression was confirmed by RT-PCR. RESULTS: The conditional transgenic vector was constructed successfully, and the expression of MT in vitro was regulated by doxycycline. Five transgenic positive mice were obtained through pronuclear microinjection. After MT induction, one transgenic mice developed hemangiomas, and the expression of MT was confirmed by RT-PCR method. The others were active and in breeding. CONCLUSION: Conditional MT transgenic animal model was constructed successfully, and may provide platform for the experimental research of hemangioma as well as the MT molecular function in vivo.

A novel transgenic mice model for venous malformation.

Vascular anomalies are most commonly seen in the head and neck region, and there is no animal model available of this disease until now. The purpose of this study was to construct a conditional murine polyomavirus middle T antigen gene (PyMT) transgenic mice model, in order to provide a basis for the treatment of vascular anomalies in vivo, as well as the study of PyMT's molecular function. A new conditional transgenic vector based on Tet-On system was constructed successfully. After the experiment in vitro, pronuclear microinjection method was used to introduce the purified transgene into the chromosomes of fertilized mice eggs, and five transgenic positive mice were obtained. The transgenic positive animals went down to future generation by hybridization. After induction of PyMT's expression in the F1 generation, three transgenic mice developed venous malformation which was confirmed histopathologically. The mice model generated could be used as a tool to study venous malformation, as well as the function of PyMT gene.