Yu-Sheng Cong

Human Telomerase and Its Regulation

SUMMARY The telomere is a special functional complex at the end of linear eukaryotic chromosomes, consisting of tandem repeat DNA sequences and associated proteins. It is essential for maintaining the integrity and stability of linear eukaryotic genomes. Telomere length regulation and maintenance contribute to normal human cellular aging and human diseases. The synthesis of telomeres is mainly achieved by the cellular reverse transcriptase telomerase, an RNA-dependent DNA polymerase that adds telomeric DNA to telomeres. Expression of telomerase is usually required for cell immortalization and long-term tumor growth. In humans, telomerase activity is tightly regulated during development and oncogenesis. The modulation of telomerase activity may therefore have important implications in antiaging and anticancer therapy. This review describes the currently known components of the telomerase complex and attempts to provide an update on the molecular mechanisms of human telomerase regulation.

Induction of hTERT Expression and Telomerase Activity by Estrogens in Human Ovary Epithelium Cells

ABSTRACT In mammals, molecular mechanisms and factors involved in the tight regulation of telomerase expression and activity are still largely undefined. In this study, we provide evidence for a role of estrogens and their receptors in the transcriptional regulation of hTERT, the catalytic subunit of human telomerase and, consequently, in the activation of the enzyme. Through a computer analysis of the hTERT 5′-flanking sequences, we identified a putative estrogen response element (ERE) which was capable of binding in vitro human estrogen receptor α (ERα). In vivo DNA footprinting revealed specific modifications of the ERE region in ERα-positive but not ERα-negative cells upon treatment with 17β-estradiol (E2), indicative of estrogen-dependent chromatin remodelling. In the presence of E2, transient expression of ERα but not ERβ remarkably increased hTERT promoter activity, and mutation of the ERE significantly reduced this effect. No telomerase activity was detected in human ovary epithelial cells grown in the absence of E2, but the addition of the hormone induced the enzyme within 3 h of treatment. The expression of hTERT mRNA and protein was induced in parallel with enzymatic activity. This prompt estrogen modulation of telomerase activity substantiates estrogen-dependent transcriptional regulation of the hTERT gene. The identification of hTERT as a target of estrogens represents a novel finding which advances the understanding of telomerase regulation in hormone-dependent cells and has implications for a potential role of hormones in their senescence and malignant conversion.

Actions of human telomerase beyond telomeres

Telomerase has fundamental roles in bypassing cellular aging and in cancer progression by maintaining telomere homeostasis and integrity. However, recent studies have led some investigators to suggest novel biochemical properties of telomerase in several essential cell signaling pathways without apparent involvement of its well established function in telomere maintenance. These observations may further enhance our understanding of the molecular actions of telomerase in aging and cancer. This review will provide an update on the extracurricular activities of telomerase in apoptosis, DNA repair, stem cell function, and in the regulation of gene expression.

Histone Deacetylation Is Involved in the Transcriptional Repression of hTERT in Normal Human Cells

Trancriptional regulation of the human telomerase reverse transcriptase (hTERT) gene, encoding the catalytic protein of human telomerase, plays a critical role in the activation of the enzyme during cell immortalization and tumorigenesis. However, the molecular mechanisms involved in the regulation of hTERTexpression are still not fully understood. We have previously cloned and characterized the genomic sequences and promoter of thehTERT gene. Here, we provide evidence that histone deacetylation is involved in the repression of hTERT in human cells. Inhibition of histone deacetylases by trichostatin A in telomerase-negative cells resulted in activation of telomerase activity and up-regulation of hTERT mRNA. Transient transfection experiments with a reporter under control of thehTERT promoter indicated that this promoter can be activated by trichostatin A. Finally, our results show that repression of the hTERT promoter by the Mad protein requires histone deacetylase activity, whereas de-repression by trichostatin A is independent of the E-boxes located in its core region.

Identification of a novel cytoplasmic protein that specifically binds to nuclear localization signal motifs.

Active transport of proteins into the nucleus is mediated by interaction between the classical nuclear localization signals (NLSs) of the targeted proteins and the NLS receptor (importin) complex. This nuclear transport system is highly regulated and conserved in eukaryotes and is essential for cell survival. Using a fragment of BRCA1 containing the two NLS motifs as a bait for yeast two-hybrid screening, we have isolated four clones, one of which is importin α. Here we characterize one of the other clones identified, BRAP2, which is a novel gene and expressed as a 2-kilobase mRNA in human mammary epithelial cells and some but not all tissues of mice. The isolated full-length cDNA encodes a novel protein containing 600 amino acid residues with pI 6.04. Characteristic motifs of C2H2 zinc fingers and leucine heptad repeats are present in the middle and C-terminal regions of the protein, respectively. BRAP2 also shares significant homology with a hypothetical protein from yeastSaccharomyces cerevisiae, especially in the zinc finger region. Antibodies prepared against the C-terminal region of BRAP2 fused to glutathione S-transferase specifically recognize a cellular protein with a molecular size of 68 kDa, consistent with the size of the in vitro translated protein. Cellular BRAP2 is mainly cytoplasmic and binds to the NLS motifs of BRCA1 with similar specificity to that of importin α in both two-hybrid assays in yeast and glutathione S-transferase pull-down assays in vitro. Other motifs such as the SV40 large T antigen NLS motif and the bipartite NLS motif found in mitosin are also recognized by BRAP2. Similarly, the yeast homolog of BRAP2 also binds to these NLS motifs in vitro. These results imply that BRAP2 may function as a cytoplasmic retention protein and play a role in regulating transport of nuclear proteins.

Glucocorticoids suppress selected components of the senescence-associated secretory phenotype.

Cellular senescence suppresses cancer by arresting the proliferation of cells at risk for malignant transformation. Recently, senescent cells were shown to secrete numerous cytokines, growth factors, and proteases that can alter the tissue microenvironment and may promote age‐related pathology. To identify small molecules that suppress the senescence‐associated secretory phenotype (SASP), we developed a screening protocol using normal human fibroblasts and a library of compounds that are approved for human use. Among the promising library constituents was the glucocorticoid corticosterone. Both corticosterone and the related glucocorticoid cortisol decreased the production and secretion of selected SASP components, including several pro‐inflammatory cytokines. Importantly, the glucocorticoids suppressed the SASP without reverting the tumor suppressive growth arrest and were efficacious whether cells were induced to senesce by ionizing radiation or strong mitogenic signals delivered by oncogenic RAS or MAP kinase kinase 6 overexpression. Suppression of the prototypical SASP component IL‐6 required the glucocorticoid receptor, which, in the presence of ligand, inhibited IL‐1α signaling and NF‐κB transactivation activity. Accordingly, co‐treatments combining glucocorticoids with the glucocorticoid antagonist RU‐486 or recombinant IL‐1α efficiently reestablished NF‐κB transcriptional activity and IL‐6 secretion. Our findings demonstrate feasibility of screening for compounds that inhibit the effects of senescent cells. They further show that glucocorticoids inhibit selected components of the SASP and suggest that corticosterone and cortisol, two FDA‐approved drugs, might exert their effects in part by suppressing senescence‐associated inflammation.

Isolating lipid droplets from multiple species

The lipid droplet (LD) is a cell organelle that has been linked to human metabolic syndromes and that can be exploited for the development of biofuels. The isolation of LDs is crucial for carrying out morphological and biochemical studies of this organelle. In the past two decades, LDs have been isolated from several organisms and investigated by microscopy, proteomics and lipidomics. However, these studies need to be extended to more model organisms, as well as to more animal tissues. Thus, a standard method that can be easily applied to these new samples with the need for minimal optimization is essential. Here we provide an LD isolation protocol that is relatively simple and suitable for a wide range of tissues and organisms. On the basis of previous studies, this 7-h protocol can yield 15–100 μg of protein-equivalent high-quality LDs that satisfy the requirements for current LD research in most organisms.

The Hepatitis B Virus X-associated Protein, XAP3, Is a Protein Kinase C-binding Protein

The hepatitis B virus X protein induces transcriptional activation of a wide variety of viral and cellular genes. In addition to its ability to interact directly with many nuclear transcription factors, several reports indicate that the X protein stimulates different cytoplasmic kinase signal cascades. Using the yeast two-hybrid screen, we have isolated a clone designated X-associated protein 3 (XAP3) that encodes a human homolog of the rat protein kinase C-binding protein. One of the activation domains of X (amino acids 90–122) is required for binding to XAP3, while the NH2-terminal part of XAP3 is necessary for binding to X. Both X and XAP3 bound specifically to the η PKC isoenzyme synthesized in rabbit reticulocyte lysates. Overexpression of XAP3 enhanced X transactivation activity. These results support earlier findings that one of the mechanisms of transactivation by X is through involvement with the cellular protein kinase C pathway.

Simultaneous proteomic profiling of four different growth states of human fibroblasts, using amine-reactive isobaric tagging reagents and tandem mass spectrometry

In general, permanent growth arrest due to exhaustive cell replication can be induced prematurely by either stress or overexpression of selected oncogenes. In an attempt to examine key proteins involved in achieving premature senescence, and how they differ from those in serially passaged, replicatively exhausted cells, we used a novel proteomic profiling approach, isobaric tagging for relative and absolute quantitation (iTRAQ), to perform simultaneous four-way comparison of replicatively senescent fibroblasts, oxidatively stressed prematurely senescent fibroblasts, and their young replicating and quiescent counterparts. Two hundred and forty proteins were identified and quantified simultaneously; data analysis reveals: (1) groups of proteins whose expressions are uniformly either up- or down-regulated in all three growth arrest states; (2) signature proteins which may serve as candidate proteomic markers to differentiate the quiescent state from permanent growth arrest by either exhaustive replication or stress induction and (3) that while oxidative stress-induced, prematurely senescent fibroblasts morphologically resemble their replicatively exhausted counterparts, they exhibit different protein expression patterns. Results from simultaneous proteomic profiling were validated by Western blotting for selected proteins: collagen type I, HSP90 and vimentin. In conclusion, this report shows that iTRAQ proteomic profiling is a powerful technique for globally mapping protein signatures for different culture growth states.

Down-regulation of the cavin family proteins in breast cancer†‡§

Caveolae are abundant membrane domain on the cell surface of many mammalian cell types and are implicated in a wide range of physiological processes. The caveolae structural protein caveolin‐1 is often mutated or deregulated in cancer, and cavin family protein serum deprivation response factor‐related gene product that binds to C‐kinase (SRBC) has been found to be epigenetically inactivated in lung, breast, and gastric cancer. Both caveolin‐1 and SRBC have been proposed to function as tumor suppressors. Polymerase 1 and transcript release factor (PTRF) is the essential component for caveolae formation. The regulation of PTRF expression in cancer has not been characterized. We report here that the cavin family protein PTRF, SRBC and serum deprivation response protein were down regulated in breast cancer cell lines and breast tumor tissue. We further show that down‐regulation of PTRF in breast cancer cells was associated with the promoter methylation. As caveolin‐1 and cavin family proteins are required for caveolae formation and function, the reported tumor suppression function of caveolin‐1 and SRBC may be due to the deregulation of caveolae and its down‐stream signaling. Thus, the caveolae is a potential therapeutic target and the expression of cavin family proteins could be a useful prognostic indicator of breast cancer progression. J. Cell. Biochem. 113: 322–328, 2012.