Zhao-Xia Huang

The Tumor Suppressor, p53 Regulates the γA-Crystallin Gene During Mouse Lens Development

The tumor suppressor, p53 regulates a large number of target genes to control cell proliferation and apoptosis. In addition, it is also implicated in the regulation of cell differentiation in muscle, the circulatory system and various carcinoma tissues. We have recently shown that p53 also controls lens differentiation. Regarding the mechanism, we reveal that p53 directly regulates several genes including c-Maf and Prox1, two important transcription factors for lens differentiation, and αA and βA3/A1, the lens differentiation markers. In the present study, we present evidence to show that the γA-crystallin gene distal promoter and the first intron also contain p53 binding sites and are capable of mediating p53 control during mouse lens development. First, gel mobility shifting assays revealed that the p53 protein in nuclear extracts from human lens epithelial cells (HLE) directly binds to the p53 binding sites present in the γA-crystallin gene. Second, the exogenous wild type p53 induces the dose-dependent expression of the luciferase reporter gene driven by the basic promoter containing the γA-crystallin gene p53 binding site. In contrast, the exogenous dominant negative mutant p53 causes a dose-dependent inhibition of the same promoter. Third, ChIP assays revealed that p53 binds to the γA-crystallin gene promoter in vivo. Finally, in the p53 knockout mouse lenses, the expression level of the γAcrystallin gene was found attenuated in comparison with that in the wild type mouse lenses. Together, our results reveal that p53 regulates γA-crystallin gene expression during mouse lens development. Thus, p53 directly regulates all 3 types of crystallin genes to control lens differentiation.

The Male Abnormal Gene Family 21 (Mab21) Members Regulate Eye Development

The male abnormal gene family contains 3 members, named mab21l1, mab21l2 and mab21l3. Since their first discovery in C. elegans, homologues of mab21l1 and mab21l2 have been found in Drosophila, Zebrafish, Xenopus, chicken, mouse and human. A number of studies have revealed that mab21 gene family members, mab21l1 and mab21l2, play important roles in regulating eye development. Here, we review the functions of the mab genes in regulating ocular development.

Contrast functions of αA- and αB-crystallins in cancer development

α-Crystallins, initially identified as the structural proteins of the ocular lens, belong to the small heat shock protein family. They play significant roles in maintaining the lens transparency and preventing protein aggregation. α-Crystallins exist in two isoforms: αA and αB, and they display differential tissue distribution. Their mutations are implicated in several human diseases including cardiac myopathies, neurodegenerative diseases, cataracts and various types of cancers. Increased αB expression was detected in retinoblastoma, breast cancer, glioblastoma, prostate and renal cell carcinomas, indicating its role in promoting tumor growth. A complex picture emerges for αA. Although earlier studies suggest that αA may promote cancer development, recent studies from our laboratory demonstrate that αA can act as a tumor suppressor inhibiting cell transformation and retarding cell migration through modulating MAP kinase activity. In this review, we summarize the recent progress about the functions of αA and αB in cancer development.

Sumoylation in lens differentiation and pathogenesis

Sumoylation, a post-translational modification discovered over a decade ago, turns out to be a very important regulatory mechanism mediating multiple cellular processes. Recent studies from our laboratory and others also revealed that it plays a crucial role in regulating both differentiation and pathogenesis of the ocular lens. This review will summarize these progresses.

Regulation of CREB Functions by Phosphorylation and Sumoylation in Nervous and Visual Systems

CREB is an ubiquitous transcription factor regulating diverse cellular responses. Its phosphorylation at S133 is an essential event for its activation in both nervous and visual systems. The activated CREB is implicated in the regulation of development, protection, learning, memory and plasticity in the nerve system. Moreover, sumoylation, an important post-translational modification of protein, plays a key role in sustaining CREB activation in the rat hippocampus in order to enhance the long-term memory and other aspects. In the visual system, although the CREB activation by phosphorylation at S133 is similar to that as observed in the nervous system, the role of CREB sumoylation remains to be explored. This review will discuss the aspects of CREB functions and their regulation by phosphorylation and sumoylation in both systems.

The small heat shock protein αA-crystallin negatively regulates pancreatic tumorigenesis.

Our recent study has shown that αA-crystallin appears to act as a tumor suppressor in pancreas. Here, we analyzed expression patterns of αA-crystallin in the pancreatic tumor tissue and the neighbor normal tissue from 74 pancreatic cancer patients and also pancreatic cancer cell lines. Immunocytochemistry revealed that αA-crystallin was highly expressed in the normal tissue from 56 patients, but barely detectable in the pancreatic tumor tissue. Moreover, a low level of αA-crystallin predicts poor prognosis for patients with pancreatic duct adenocarcinoma (PDAC). In the 12 pancreatic cell lines analyzed, except for Capan-1 and Miapaca-2 where the level of αA-crystallin was about 80% and 65% of that in the control cell line, HPNE, the remaining pancreatic cancer cells have much lower αA-crystallin levels. Overexpression of αA-crystallin in MiaPaca-1 cells lacking endogenous αA-crystallin significantly decreased its tumorigenicity ability as shown in the colony formation and wound healing assays. In contrast, knockdown of αA-crystallin in the Capan-1 cells significantly increased its tumorigenicity ability as demonstrated in the above assays. Together, our results further demonstrate that αA-crystallin negatively regulates pancreatic tumorigenesis and appears to be a prognosis biomarker for PDAC.

p53 Regulates Developmental Apoptosis and Gene Expression to Modulate Lens Differentiation

The tumor suppressor p53 is a master regulator of apoptosis and also plays a key role in cell cycle progress and cell differentiation. It mainly acts as a transcription factor. In addition, it can also directly interact with apoptosis regulators in mitochondria to control apoptosis. Recent studies from our laboratory and others have shown that p53 plays an active role in regulating lens differentiation. It does so by modulating developmental apoptosis and also controlling expression of lens differentiation-specific genes. In this chapter, we summary the current progresses in this field.

Protein Serine/Threonine Phosphatases-1 and -2A in Lens Development and Pathogenesis

The protein serine/threonine phosphatases are major cellular phosphatases, responsible for 98 % dephosphorylation of proteins in eukaryotes. In the ocular lens, they are highly expressed and play important roles in both development and pathogenesis. In the present review, we have summarized these two aspects, which provide a basis for further studies on these important signaling molecules in the eye.