Donald Chang

Mir-302 reprograms human skin cancer cells into a pluripotent ES-cell-like state

Renewal of stem cells differs from cancer cell growth in self-controlled cell division. The mir-302 microRNA (miRNA) family (mir-302s) is expressed most abundantly in slow-growing human embryonic stem (ES) cells, and quickly decreases after cell differentiation and proliferation. Therefore, mir-302s was investigated as one of the key factors essential for maintenance of ES cell renewal and pluripotency in this study. The Pol-II-based intronic miRNA expression system was used to transgenically transfect the mir-302s into several human cancer cell lines. The mir-302-transfected cells, namely, miRNA-induced pluripotent stem (mirPS) cells, not only expressed many key ES cell markers, such as Oct3/4, SSEA-3, SSEA-4 ,Sox2, and Nanog, but also had a highly demethylated genome similar to a reprogrammed zygotic genome. Microarray analyses further revealed that genome-wide gene expression patterns between the mirPS and human ES H1 and H9 cells shared over 86% similarity. Using molecular guidance in vitro, these mirPS cells could differentiate into distinct tissue cell types, such as neuron-, chondrocyte-, fibroblast-, and spermatogonia-like primordial cells. Based on these findings, we conclude that mir-302s not only function to reprogram cancer cells into an ES-like pluripotent state but also to maintain this state under a feeder-free cultural condition, which may offer a great opportunity for therapeutic intervention.

Loss of mir-146a function in hormone-refractory prostate cancer

The pattern of microRNA (miRNA) expression is associated with the degree of tumor cell differentiation in human prostate cancer. MiRNAs bind complementarily to either oncogenes or tumor suppressor genes, which are consequently silenced, resulting in alterations of tumorigenecity. We have detected eight down-regulated and three up-regulated known miRNAs in androgen-independent human prostate cancer cells compared to those in androgen-dependent cells, using miRNA microarray analyses. These identified miRNAs showed the same expression patterns in hormone-refractory prostate carcinomas (HRPC) compared to androgen-sensitive noncancerous prostate epithelium as determined by fluorescent in situ hybridization assays in human prostate cancer tissue arrays. One of the eight down-regulated miRNAs, mir-146a, was selected and constitutively expressed to examine its effects on suppression of prostate cancer transformation from androgen-dependent to -independent cells as determined by in vitro tumorigenecity assays. Transfection of mir-146a, which perpetually express the miRNA, suppressed >82% of the expression of the targeted protein-coding gene, ROCK1, in androgen-independent PC3 cells, consequently markedly reducing cell proliferation, invasion, and metastasis to human bone marrow endothelial cell monolayers. Given that ROCK1 is one of the key kinases for the activation of hyaluronan (HA)-mediated HRPC transformation in vivo and in PC3 cells, mir-146a may function as a tumor-suppressor gene in modulating HA/ROCK1-mediated tumorigenecity in androgen-dependent prostate cancer.

Regulation of somatic cell reprogramming through inducible mir-302 expression

Global demethylation is required for early zygote development to establish stem cell pluripotency, yet our findings reiterate this epigenetic reprogramming event in somatic cells through ectopic introduction of mir-302 function. Here, we report that induced mir-302 expression beyond 1.3-fold of the concentration in human embryonic stem (hES) H1 and H9 cells led to reprogramming of human hair follicle cells (hHFCs) to induced pluripotent stem (iPS) cells. This reprogramming mechanism functioned through mir-302-targeted co-suppression of four epigenetic regulators, AOF2 (also known as KDM1 or LSD1), AOF1, MECP1-p66 and MECP2. Silencing AOF2 also caused DNMT1 deficiency and further enhanced global demethylation during somatic cell reprogramming (SCR) of hHFCs. Re-supplementing AOF2 in iPS cells disrupted such global demethylation and induced cell differentiation. Given that both hES and iPS cells highly express mir-302, our findings suggest a novel link between zygotic reprogramming and SCR, providing a regulatory mechanism responsible for global demethylation in both events. As the mechanism of conventional iPS cell induction methods remains largely unknown, understanding this microRNA (miRNA)-mediated SCR mechanism may shed light on the improvements of iPS cell generation.

MicroRNA miR-302 inhibits the tumorigenecity of human pluripotent stem cells by coordinate suppression of the CDK2 and CDK4/6 cell cycle pathways.

miR-302 is the major microRNA found in human embryonic stem cells and induced pluripotent stem cells, but its function has been unclear. In mice, there is evidence that miR-302 may silence p21Cip1 (CDKN1A) to promote cell proliferation, whereas studies in human reprogrammed pluripotent stem cells suggested that elevated miR-302 expression inhibited cell cycle transit. Here, we clarify this difference, reporting that in human cells, miR-302 simultaneously suppressed both the cyclin E-CDK2 and cyclin D-CDK4/6 pathways to block>70% of the G1-S cell cycle transition. Concurrent silencing of BMI-1, a cancer stem cell marker targeted by miR-302, further promoted tumor suppressor functions of p16Ink4a and p14/p19Arf directed against CDK4/6-mediated cell proliferation. Among all G1 phase checkpoint regulators, human p21Cip1 was found not to be a valid target of miR-302. Overall, our findings indicate that miR-302 inhibits human pluripotent stem cell tumorigenicity by enhancing multiple G1 phase arrest pathways rather than by silencing p21Cip1.

The MicroRNA: Overview of the RNA Gene That Modulates Gene Functions

MicroRNAs (miRNAs), widely distributed, small regulatory RNA genes, target both messenger RNA (mRNA) degradation and suppression of protein translation based on sequence complementarity between the miRNA and its targeted mRNA. Different names have been used to describe various types of miRNA. During evolution, RNA retroviruses or transgenes invaded the eukaryotic genome and inserted itself in the noncoding regions of DNA, conceivably acting as transposon-like jumping genes, providing defense from viral invasion and fine-tuning of gene expression as a secondary level of gene modulation in eukaryotes. When a transposon is inserted in the intron, it becomes an intronic miRNA, taking advantage of the protein synthesis machinery, i.e., mRNA transcription and splicing, as a means for processing and maturation. Recently, miRNAs have been found to play an important, but not life-threatening, role in embryonic development. They might play a pivotal role in diverse biological systems in various organisms, facilitating a quick response and accurate plotting of body physiology and structures. Based on these unique properties, manufactured intronic miRNAs have been developed for in vitro evaluation of gene function, in vivo gene therapy, and generation of transgenic animal models. The biogenesis and identification of miRNAs, potential applications, and future directions for research are presented in this chapter, hopefully providing a guideline for further miRNA and gene function studies.

Mir-434-5p mediates skin whitening and lightening

Utilization of gene silencing effectors, such as microRNA (miRNA) and small hairpin RNA (shRNA), provides a powerful new strategy for human skin care in vivo, particularly for hyperpigmentation treatment and aging prevention. In this study, tyrosinase (Tyr), the rate-limiting enzyme of melanin (black pigment) biosynthesis, was served as a target for treatment of hyperpigmentation in mouse and human skins. There are over 54 native microRNA capable of silencing human tyrosinase for skin whitening and lightening. To this, we have designed a mir-434-5p homologue and used it to successfully demonstrate the feasibility of miRNA-mediated skin whitening and lightening in vitro and in vivo. Under the same experimental condition in the trials, Pol-II-directed intronic mir-434-5p expression did not cause any detectable sign of cytotoxicity, whereas siRNAs targeting the same sequence often induced certain nonspecific mRNA degradation as previously reported. Because the intronic miRNA-mediated gene silencing pathway is tightly regulated by multiple intracellular surveillance systems, including Pol-II transcription, RNA splicing, exosomal digestion and nonsense-mediated RNA decay (NMD), the current findings underscore the fact that intronic miRNA agents, such as manually re-designed mir-434-5p homologues, are effective, target-specific and safe to be used for skin whitening without any detectable cytotoxic effect. Given that the human skins also express a variety of other native miRNAs, we may re-design these miRNAs based on their individual functions for skin care, which may provide significant insights into areas of opportunity for new cosmetic and/or therapeutical applications.

A New Model System for Studying Lacrimal Physiology Using Cultured Lacrimal Gland Acinar Cells on Matrigel® Rafts

We have recently established procedures for the isolation of highly purified lacrimal gland acinar cells (pLGAC) (Guo et al., 2000) and a culture method that promotes proliferation of the cells (Schonthal et al., 2000). Many studies have shown the benefits of seeding lacrimal cells onto Matrigel coated plates (Kelleher et al., 1991; Menerey et al., 1994; Millar, et al., 1996; Chen et al., 1998). Our procedure utilizes a method which coats the pLGAC with Matrigel to more closely mimic the in vivo condition where acinar cells are enveloped by matrix molecules on their basal surfaces. This has been achieved by trapping pLGAC in Matrigel rafts. These free-floating raft cultures have been maintained in vitro for up to 28 days for morphological and physiological studies.

Androgen receptor regulates CD168 expression and signaling in prostate cancer.

Dysregulation of the androgen receptor (AR) and its signaling in the prostate often occurs during normal aging or after androgen ablation, consequently leading to the development of hormone-refractory prostate cancer (HRPC). Hyaluronan (HA) plays an important role in this transformation of androgen-independent cancer. Previous studies have shown that activation of the receptor for hyaluronan-mediated motility, CD168, was correlated with the Gleasons score, cancer stage, transformation and metastasis in >90% of HRPC patients. However, the relationship between loss of AR dependency and HA-mediated CD168 signaling remains unclear. We report here that AR regulates normal CD168 expression and its downstream signaling in androgen-dependent (AD) prostatic epithelial cell lines. Furthermore, we observed that the concurrent treatments of HA and dihydrotestosterone (DHT), a native androgen, significantly promoted the tumorigenicity of AD prostate cancer cell lines, which showed elevated rates of cell proliferation, invasion and metastasis to the human bone marrow endothelial cell layer. Inhibition of CD168 downstream Rho-activated protein kinases completely prevented this type of tumorigenicity. These findings suggest that the interaction of androgen and AR is essential for regulating HA-mediated cancer progression via the CD168/ROCK signal transduction pathway and also indicate that the loss of AR regulation not only causes CD168 overexpression but it also activates HA-mediated CD168 signaling in malignant cancer progression and metastasis of HRPC.

Potential Role of Disrupted Lacrimal Acinar Cells in Dry Eye during Pregnancy

Recently, dry eye disease has been linked with hormonal changes in several patient populations. For instance, there is a high incidence of dry eye disease that accompanies aging in postmenopausal women (Molina et al., 1986), and there appears to be an increased incidence of disease during pregnancy (unpublished data). Furthermore, increased addition infiltration of lymphocytes into the lacrimal glands has also been associated with aging (Murray et al., 1981; Damato et al., 1984). Serum levels of androgens have been shown to be important in maintenance of normal lacrimal gland function (Mircheff et al., 1996).

Truncated Bcl-2, a potential pre-metastatic marker in prostate cancer.

A novel truncated form of Bcl-2, termed Bcl-2psi, was discovered in invasive prostate cancer cells, using laser capture microdissection, RNA-polymerase cycling reaction, and microarray analysis. The expression of Bcl-2psi increased prior to metastasis in higher-grade prostate cancer. The immunoreactive Bcl-2psi was specifically identified in higher-grade prostate cancer cells. These findings suggest that Bcl-2psi may be a potential pre-metastatic marker for detection, diagnosis, and therapy during the initiation of metastasis in prostate cancer.