Your search keyword '"Lu, AL"' showing total 8 results

1. Molecular Recognition and Imaging of Human Telomeric G-Quadruplex DNA in Live Cells: A Systematic Advancement of Thiazole Orange Scaffold To Enhance Binding Specificity and Inhibition of Gene Expression.

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Author

Long W, Zheng BX, Huang XH, She MT, Liu AL, Zhang K, Wong WL, and Lu YJ

Subjects

Benzothiazoles chemical synthesis, Benzothiazoles metabolism, Cell Line, Tumor, DNA genetics, Fluorescent Dyes chemical synthesis, Fluorescent Dyes metabolism, Humans, Ligands, Microscopy, Confocal, Microscopy, Fluorescence, Quinolines chemical synthesis, Quinolines metabolism, RNA metabolism, Styrenes chemical synthesis, Styrenes metabolism, Telomerase metabolism, Benzothiazoles pharmacology, DNA metabolism, Down-Regulation drug effects, Fluorescent Dyes pharmacology, G-Quadruplexes, Quinolines pharmacology, Styrenes pharmacology

Abstract

A series of fluorescent ligands, which were systematically constructed from thiazole orange scaffold, was investigated for their interactions with G-quadruplex structures and antitumor activity. Among the ligands, compound 3 was identified to exhibit excellent specificity toward telomere G4-DNA over other nucleic acids. The affinity of 3 -Htg24 was almost 5 times higher than that of double-stranded DNA and promoter G4-DNA. Interaction studies showed that 3 may bind to both G-tetrad and the lateral loop near the 5'-end. The intracellular colocalization with BG4 and competition studies with BRACO19 reveal that 3 may interact with G4-structures. Moreover, 3 reduces the telomere length and downregulates hTERC and hTERT mRNA expression in HeLa cells. The cytotoxicity of 3 against cancer cells (IC 50 = 12.7-16.2 μM) was found to be generally higher than noncancer cells (IC 50 = 52.3 μM). The findings may support that the ligand is telomere G4-DNA specific and may provide meaningful insights for anticancer drug design. more...

Published

2021

2. Genome Protection by the 9-1-1 Complex Subunit HUS1 Requires Clamp Formation, DNA Contacts, and ATR Signaling-independent Effector Functions.

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Author

Lim PX, Patel DR, Poisson KE, Basuita M, Tsai C, Lyndaker AM, Hwang BJ, Lu AL, and Weiss RS

Subjects

Animals, Ataxia Telangiectasia Mutated Proteins metabolism, Base Sequence, Cell Cycle Proteins chemistry, Cells, Cultured, DNA Primers, Humans, Mice, Protein Conformation, Cell Cycle Proteins metabolism, DNA metabolism, Genome, Human, Signal Transduction

Abstract

The RAD9A-HUS1-RAD1 (9-1-1) complex is a heterotrimeric clamp that promotes checkpoint signaling and repair at DNA damage sites. In this study, we elucidated HUS1 functional residues that drive clamp assembly, DNA interactions, and downstream effector functions. First, we mapped a HUS1-RAD9A interface residue that was critical for 9-1-1 assembly and DNA loading. Next, we identified multiple positively charged residues in the inner ring of HUS1 that were crucial for genotoxin-induced 9-1-1 chromatin localization and ATR signaling. Finally, we found two hydrophobic pockets on the HUS1 outer surface that were important for cell survival after DNA damage. Interestingly, these pockets were not required for 9-1-1 chromatin localization or ATR-mediated CHK1 activation but were necessary for interactions between HUS1 and its binding partner MYH, suggesting that they serve as interaction domains for the recruitment and coordination of downstream effectors at damage sites. Together, these results indicate that, once properly loaded onto damaged DNA, the 9-1-1 complex executes multiple, separable functions that promote genome maintenance., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.) more...

Published

2015

3. SIRT6 protein deacetylase interacts with MYH DNA glycosylase, APE1 endonuclease, and Rad9-Rad1-Hus1 checkpoint clamp.

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Author

Hwang BJ, Jin J, Gao Y, Shi G, Madabushi A, Yan A, Guan X, Zalzman M, Nakajima S, Lan L, and Lu AL

Subjects

Amino Acid Motifs, Animals, Cell Cycle Proteins chemistry, Cell Cycle Proteins metabolism, Chromatin genetics, DNA Glycosylases genetics, DNA Glycosylases metabolism, DNA-(Apurinic or Apyrimidinic Site) Lyase genetics, DNA-(Apurinic or Apyrimidinic Site) Lyase metabolism, Exonucleases metabolism, HEK293 Cells, HeLa Cells, Humans, Mice, Sirtuins genetics, Telomere metabolism, Cell Cycle Checkpoints, DNA metabolism, DNA Repair, Sirtuins metabolism

Abstract

Background: SIRT6, a member of the NAD(+)-dependent histone/protein deacetylase family, regulates genomic stability, metabolism, and lifespan. MYH glycosylase and APE1 are two base excision repair (BER) enzymes involved in mutation avoidance from oxidative DNA damage. Rad9-Rad1-Hus1 (9-1-1) checkpoint clamp promotes cell cycle checkpoint signaling and DNA repair. BER is coordinated with the checkpoint machinery and requires chromatin remodeling for efficient repair. SIRT6 is involved in DNA double-strand break repair and has been implicated in BER. Here we investigate the direct physical and functional interactions between SIRT6 and BER enzymes., Results: We show that SIRT6 interacts with and stimulates MYH glycosylase and APE1. In addition, SIRT6 interacts with the 9-1-1 checkpoint clamp. These interactions are enhanced following oxidative stress. The interdomain connector of MYH is important for interactions with SIRT6, APE1, and 9-1-1. Mutagenesis studies indicate that SIRT6, APE1, and Hus1 bind overlapping but different sequence motifs on MYH. However, there is no competition of APE1, Hus1, or SIRT6 binding to MYH. Rather, one MYH partner enhances the association of the other two partners to MYH. Moreover, APE1 and Hus1 act together to stabilize the MYH/SIRT6 complex. Within human cells, MYH and SIRT6 are efficiently recruited to confined oxidative DNA damage sites within transcriptionally active chromatin, but not within repressive chromatin. In addition, Myh foci induced by oxidative stress and Sirt6 depletion are frequently localized on mouse telomeres., Conclusions: Although SIRT6, APE1, and 9-1-1 bind to the interdomain connector of MYH, they do not compete for MYH association. Our findings indicate that SIRT6 forms a complex with MYH, APE1, and 9-1-1 to maintain genomic and telomeric integrity in mammalian cells. more...

Published

2015

4. The C-terminal domain of Escherichia coli MutY is involved in DNA binding and glycosylase activities.

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Author

Li L and Lu AL

Subjects

Amino Acid Sequence, Binding Sites, Escherichia coli Proteins genetics, Genetic Complementation Test, Models, Molecular, Molecular Sequence Data, Mutation, N-Glycosyl Hydrolases genetics, Protein Structure, Tertiary, Sequence Alignment, DNA metabolism, DNA Glycosylases, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, N-Glycosyl Hydrolases chemistry, N-Glycosyl Hydrolases metabolism

Abstract

Escherichia coli MutY is an adenine and a weak guanine DNA glycosylase involved in reducing mutagenic effects of 7,8-dihydro-8-oxo-guanine (8-oxoG). The C-terminal domain of MutY is required for 8-oxoG recognition and is critical for mutation avoidance of oxidative damage. To determine which residues of this domain are involved in 8-oxoG recognition, we constructed four MutY mutants based on similarities to MutT, which hydrolyzes specifically 8-oxo-dGTP to 8-oxo-dGMP. F294A-MutY has a slightly reduced binding affinity to A/G mismatch but has a severe defect in A/8-oxoG binding at 20 degrees C. The catalytic activity of F294A-MutY is much weaker than that of the wild-type MutY. The DNA binding activity of R249A-MutY is comparable to that of the wild-type enzyme but the catalytic activity is reduced with both A/G and A/8-oxoG mismatches. The biochemical activities of F261A-MutY are nearly similar to those of the wild-type enzyme. The solubility of P262A-MutY was improved as a fusion protein containing streptococcal protein G (GB1 domain) at its N-terminus. The binding of GB1-P262A-MutY with both A/G and A/8-oxoG mismatches are slightly weaker than those of the wild-type protein. The catalytic activity of GB1-P262A-MutY is weaker than that of the wild-type enzyme at lower enzyme concentrations. Importantly, all four mutants can complement mutY mutants in vivo when expressed at high levels; however, F294A, R249A and P262A, but not F261A, are partially defective in vivo when they are expressed at low levels. These results strongly support that the C-terminal domain of MutY is involved not only in 8-oxoG recognition, but also affects the binding and catalytic activities toward A/G mismatches. more...

Published

2003

5. Differential DNA recognition and glycosylase activity of the native human MutY homolog (hMYH) and recombinant hMYH expressed in bacteria.

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Author

Gu Y and Lu AL

Subjects

Adenine metabolism, Base Pair Mismatch genetics, Blotting, Western, Cell Extracts, DNA chemistry, DNA Glycosylases, DNA-Binding Proteins genetics, DNA-Binding Proteins isolation & purification, DNA-Binding Proteins metabolism, Electrophoresis, Polyacrylamide Gel, Guanine metabolism, Guanosine analogs & derivatives, Guanosine genetics, Guanosine metabolism, Humans, N-Glycosyl Hydrolases genetics, N-Glycosyl Hydrolases isolation & purification, Phosphorylation, Precipitin Tests, Protein Binding, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Sequence Homology, Amino Acid, Substrate Specificity, Thermodynamics, Tumor Cells, Cultured, DNA genetics, DNA metabolism, DNA Repair genetics, Escherichia coli enzymology, Escherichia coli genetics, N-Glycosyl Hydrolases metabolism

Abstract

Human MutY homolog (hMYH), an adenine DNA glycosylase, can effectively remove misincorporated adenines opposite template G or 8-oxoG bases, thereby preventing G:C-->T:A transversions. Human cell extracts possess the adenine DNA glycosylase activity of hMYH and can form protein-DNA complexes with both A/G and A/8-oxoG mismatches. hMYH in cell extracts was shown to be the primary binding protein for A/G- and A/8-oxoG-containing DNA substrates by UV cross-linking. However, recombinant hMYH expressed in bacteria has much weaker glycosylase and substrate-binding activities towards A/G mismatches than native hMYH. Moreover, the protein-DNA complex of bacterially expressed hMYH migrates much faster than that of native hMYH in a non-denaturing polyacrylamide gel. Dephosphorylation of native hMYH reduces the glycosylase activity on A/G more extensively than on A/8-oxoG mismatches but does not alter the gel mobility of the protein-DNA complex. Our results suggest that hMYH in human cell extracts may be associated with other factors in the protein-DNA complex to account for its slower mobility in the gel. hMYH and apurinic/apyrimidinic endonuclease (hAPE1) co-migrate with the protein-DNA complex formed by the extracts and A/8-oxoG-containing DNA. more...

Published

2001

6. Repair of oxidative DNA damage: mechanisms and functions.

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Author

Lu AL, Li X, Gu Y, Wright PM, and Chang DY

Subjects

Amino Acid Sequence, Animals, Bacterial Proteins metabolism, Base Pair Mismatch, Carbon-Oxygen Lyases metabolism, DNA Damage, DNA-(Apurinic or Apyrimidinic Site) Lyase, DNA-Formamidopyrimidine Glycosylase, Escherichia coli metabolism, Guanosine metabolism, Humans, Models, Chemical, Models, Molecular, Molecular Sequence Data, N-Glycosyl Hydrolases metabolism, Oxygen metabolism, Phosphoric Monoester Hydrolases metabolism, Protein Binding, Pyrophosphatases, Reactive Oxygen Species, DNA, DNA Glycosylases, DNA Repair, Escherichia coli Proteins, Guanosine analogs & derivatives

Abstract

Cellular genomes suffer extensive damage from exogenous agents and reactive oxygen species formed during normal metabolism. The MutT homologs (MutT/MTH) remove oxidized nucleotide precursors so that they cannot be incorporated into DNA during replication. Among many repair pathways, the base excision repair (BER) pathway is the most important cellular protection mechanism responding to oxidative DNA damage. The 8-oxoG glycosylases (Fpg or MutM/OGG) and the MutY homologs (MutY/MYH) glycosylases along with MutT/MTH protect cells from the mutagenic effects of 8-oxoG, the most stable and deleterious product known caused by oxidative damage to DNA. The key enzymes in the BER process are DNA glycosylases, which remove different damaged bases by cleavage of the N-glycosylic bonds between the bases and the deoxyribose moieties of the nucleotide residues. Biochemical and structural studies have demonstrated the substrate recognition and reaction mechanism of BER enzymes. Cocrystal structures of several glycosylases show that the substrate base flips out of the sharply bent DNA helix and the minor groove is widened to be accessed by the glycosylases. To complete the repair after glycosylase action, the apurinic/apyrimidinic (AP) site is further processed by an incision step, DNA synthesis, an excision step, and DNA ligation through two alternative pathways. The short-patch BER (1-nucleotide patch size) and long-patch BER (2-6-nucleotide patch size) pathways need AP endonuclease to generate a 3' hydroxyl group but require different sets of enzymes for DNA synthesis and ligation. Protein-protein interactions have been reported among the enzymes involved in BER. It is possible that the successive players in the repair pathway are assembled in a complex to perform concerted actions. The BER pathways are proposed to protect cells and organisms from mutagenesis and carcinogenesis. more...

Published

2001

7. Mammalian topoisomerase I has base mismatch nicking activity.

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Author

Yeh YC, Liu HF, Ellis CA, and Lu AL

Subjects

Animals, Base Sequence, Camptothecin pharmacology, Cattle, Chromatography, Chromatography, Gel, Chromatography, Ion Exchange, Cloning, Molecular, DNA chemistry, DNA Primers, DNA Topoisomerases, Type I biosynthesis, DNA Topoisomerases, Type I isolation & purification, Durapatite, Electrophoresis, Polyacrylamide Gel, Escherichia coli, HeLa Cells, Humans, Molecular Sequence Data, Molecular Weight, Oligodeoxyribonucleotides chemical synthesis, Polymerase Chain Reaction, Recombinant Fusion Proteins biosynthesis, Recombinant Fusion Proteins isolation & purification, Recombinant Fusion Proteins metabolism, Restriction Mapping, Substrate Specificity, Base Composition, DNA metabolism, DNA Topoisomerases, Type I metabolism, Oligodeoxyribonucleotides metabolism, Thymus Gland enzymology

Abstract

The all-type nicking enzyme (ATE) from human HeLa cells or calf thymus can nick DNA at the first phosphodiester bond 5' to all 8 possible mismatched bases. The strand disparity of this nicking is influenced by the neighboring nucleotide sequences. After nicking, the ATE covalently binds to the 3' end of the DNA product to form a cleavable complex, whose formation is insensitive to camptothecin, a specific inhibitor of eukaryotic topoisomerase I (Topo-I). During the purification of ATE from calf thymus, a Mg(2+)-independent relaxation activity, characteristic of eukaryotic Topo-I, copurifies with the mismatch-nicking activity. The ATE from calf thymus may be a breakdown product of Topo-I. N-terminal amino acid analysis indicates that one of the polypeptides with ATE activity contains the C-terminal portion of Topo-I. Moreover, active human Topo-I, expressed as a fusion protein in Escherichia coli, is also capable of nicking all 8 base mispairs in the absence of Mg2+. This mismatch-specific nicking activity may be a novel property of the mammalian Topo-I. more...

Published

1994

8. Two nicking enzyme systems specific for mismatch-containing DNA in nuclear extracts from human cells.

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Author

Yeh YC, Chang DY, Masin J, and Lu AL

Subjects

Base Sequence, Cell Nucleus metabolism, Chromatography, DEAE-Cellulose, DNA metabolism, Electrophoresis, Polyacrylamide Gel, HeLa Cells, Humans, Molecular Sequence Data, Substrate Specificity, DNA genetics, DNA Topoisomerases, Type I metabolism

Abstract

We have identified two novel enzyme systems in human HeLa nuclear extracts that can nick at specific sites of DNA molecules with base mismatches, in addition to the T/G mismatch-specific nicking enzyme system (Wiebauer, K., and Jiricny, J. (1989) Nature 339, 234-236). One enzyme (called all-type) can nick all eight base mismatches with different efficiencies. The other (A/G-specific) nicks only DNA containing an A/G mismatch. The all-type enzyme can be separated from the T/G-specific and A/G-specific nicking enzymes by Bio-Rex 70 chromatography. Further purification on a DEAE-5PW column separated the A/G-specific nicking enzyme from the T/G-specific nicking enzyme. Therefore, at least three different enzyme systems are able to cleave mismatched DNA in HeLa nuclear extracts. The all-type and A/G-specific enzymes work at different optimal salt concentrations and cleave at different sites within the mismatched DNA. The all-type enzyme can only cleave at the first phosphodiester bond 5' to the mispaired bases. This enzyme shows nick disparity to only one DNA strand and may be involved in genetic recombination. The A/G-specific enzyme simultaneously makes incisions at the first phosphodiester bond both 5' and 3' to the mispaired adenine but not the guanine base. This enzyme may be involved in an A/G mismatch-specific repair similar to the Escherichia coli mutY (or micA)-dependent pathway. more...

Published

1991