Hongwei Sun scite author profile

Sequences of 47 members of the Zn-containing alcohol dehydrogenase (ADH) family were aligned progressively, and an evolutionary tree with detailed branch order and branch lengths was produced. The alignment shows that only 9 amino acid residues (of 374 in the horse liver ADH sequence) are conserved in this family; these include eight Gly and one Val with structural roles. Three residues that bind the catalytic Zn and modulate its electrostatic environment are conserved in 45 members. Asp 223, which determines specificity for NAD, is found in all but the two NADP-dependent enzymes, which have Gly or Ala. Ser or Thr 48, which makes a hydrogen bond to the substrate, is present in 46 members. The four Cys ligands for the structural zinc are conserved except in zeta-crystallin, the sorbitol dehydrogenases, and two bacterial enzymes. Analysis of the evolutionary tree gives estimates of the times of divergence for different animal ADHs. The human class II (pi) and class III (chi) ADHs probably diverged about 630 million years ago, and the newly identified human ADH6 appeared about 520 million years ago, implying that these classes of enzymes may exist or have existed in all vertebrates. The human class I ADH isoenzymes (alpha, beta, and gamma) diverged about 80 million years ago, suggesting that these isoenzymes may exist or have existed in all primates. Analysis of branch lengths shows that these plant ADHs are more conserved than the animal ones and that class III ADHs are more conserved than class I ADHs. The rate of acceptance of point mutations (PAM units) shows that selection pressure has existed for ADHs, implying that these enzymes play definite metabolic roles.

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Inversion of the substrate specificity of yeast alcohol dehydrogenase.

Green

Sun

Plapp

1993

Journal of Biological Chemistry

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Circular RNA hsa_circ_0004277 contributes to malignant phenotype of colorectal cancer by sponging miR‐512‐5p to upregulate the expression of PTMA

Yang

Sun

Liu

et al. 2020

Journal Cellular Physiology

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In recent years, extensive reports have been published concerning the molecular mechanism underlying the occurrence and progression of colorectal cancer. Circular RNAs (circRNAs) have been identified as important modulators in the biological processes of colorectal cancer. Microarray analysis unveiled that differential circ‐0004277 expression was identified in tissue samples of colorectal cancer. High circ‐0004277 expression was then verified in tissue samples and cell lines of colorectal cancer via qRT‐PCR. Kaplan–Meier analysis was used for identifying the association between circ‐0004277 expression and the overall survival rate of colorectal cancer patients. A relationship existed between higher circ‐0004277 expression and decreased overall survival rate of colorectal cancer patients. From a functional perspective, circ‐0004277 knockdown accelerated cell apoptosis and restrained cell proliferation of colorectal cancer. From mechanistic perspective, circ‐0004277 upregulated PTMA by sponging miR‐512‐5p. Rescue assay was used for verifying the roles of the circ‐0004277‐miR‐512‐5p‐PTMA axis. Both miR‐512‐5p and PTMA participated in circ‐0004277‐mediated colorectal cancer cell proliferation based on experiments. In summary, our study showed that circ‐0004277 promoted the proliferation of colorectal cancer cells as a miR‐512‐5p sponge to upregulate the PTMA expression.

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DnaA and LexA Proteins Regulate Transcription of the uvrB Gene in Escherichia coli: The Role of DnaA in the Control of the SOS Regulon

et al. 2018

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The uvrB gene belongs to the SOS network, encoding a key component of the nucleotide excision repair. The uvrB promoter region contains three identified promoters with four LexA binding sites, one consensus and six potential DnaA binding sites. A more than threefold increase in transcription of the chromosomal uvrB gene is observed in both the ΔlexA ΔsulA cells and dnaAA345S cells, and a fivefold increase in the ΔlexA ΔsulA dnaAA345S cells relative to the wild-type cells. The full activity of the uvrB promoter region requires both the uvrBp1-2 and uvrBp3 promoters and is repressed by both the DnaA and LexA proteins. LexA binds tightly to LexA-box1 at the uvrBp1-2 promoter irrespective of the presence of DnaA and this binding is important for the control of the uvrBp1-2 promoter. DnaA and LexA, however, compete for binding to and regulation of the uvrBp3 promoter in which the DnaA-box6 overlaps with LexA-box4. The transcription control of uvrBp3 largely depends on DnaA-box6. Transcription of other SOS regulon genes, such as recN and dinJ, is also repressed by both DnaA and LexA. Interestingly, the absence of LexA in the presence of the DnaAA345S mutant leads to production of elongated cells with incomplete replication, aberrant nucleoids and slow growth. We propose that DnaA is a modulator for maintenance of genome integrity during the SOS response by limiting the expression of the SOS regulon.

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Hongwei Sun

Progressive sequence alignment and molecular evolution of the Zn-containing alcohol dehydrogenase family

Inversion of the substrate specificity of yeast alcohol dehydrogenase.

Circular RNA hsa_circ_0004277 contributes to malignant phenotype of colorectal cancer by sponging miR‐512‐5p to upregulate the expression of PTMA

DnaA and LexA Proteins Regulate Transcription of the uvrB Gene in Escherichia coli: The Role of DnaA in the Control of the SOS Regulon

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