Your search keyword '"Xiang S"' showing total 20 results

1. Proteolysis and Tyrosine Phosphorylation of p34 /Cyclin B

Author

Alice Tang, Kimberly K. McNeal, Kevin B. Ryan, Adam N. Wexler, Russell R. Fincher, Stephen A. Osmani, Scott E. Gygax, Steven W. James, and Xiang S. Ye

Subjects

DNA re-replication, Tyrosine phosphorylation, Eukaryotic DNA replication, Cell Biology, G2-M DNA damage checkpoint, Biology, Biochemistry, Molecular biology, chemistry.chemical_compound, Replication factor C, chemistry, Control of chromosome duplication, Origin recognition complex, Molecular Biology, S phase

Abstract

Previously, it has been shown that Aspergillus cells lacking the function of nimQand the anaphase-promoting complex (APC) component bimE APC1 enter mitosis without replicating DNA. Here nimQ is shown to encode an MCM2 homologue. Although mutation of nimQ MCM2 inhibits initiation of DNA replication, a few cells do enter mitosis. Cells arrested at G1/S by lack of nimQ MCM2 contain p34 cdc2 /cyclin B, but p34 cdc2 remains tyrosine dephosphorylated, even after DNA damage. However, arrest of DNA replication using hydroxyurea followed by inactivation of nimQ MCM2 and bimE APC1 does not abrogate the S phase arrest checkpoint over mitosis. nimQ MCM2, likely via initiation of DNA replication, is therefore required to trigger tyrosine phosphorylation of p34 cdc2 during the G1to S transition, which may occur by inactivation of nimT cdc25. Cells lacking both nimQ MCM2 and bimE APC1 are deficient in the S phase arrest checkpoint over mitosis because they lack both tyrosine phosphorylation of p34 cdc2 and the function of bimE APC1. Initiation of DNA replication, which requires nimQ MCM2, is apparently critical to switch mitotic regulation from the APC to include tyrosine phosphorylation of p34 cdc2 at G1/S. We also show that cells arrested at G1/S due to lack of nimQ MCM2 continue to replicate spindle pole bodies in the absence of DNA replication and can undergo anaphase in the absence of APC function.

Published

1997

2. Isolation of a Functional Homolog of the Cell Cycle-specific NIMA Protein Kinase of Aspergillus nidulans and Functional Analysis of Conserved Residues

Author

Stephen A. Osmani, John Vierula, Gang Xu, Xiang S. Ye, Robert T. Pu, Kerry O'Donnell, and Li-Ping Wu

Subjects

DNA Mutational Analysis, Molecular Sequence Data, Cyclin B, Mitosis, Cell Cycle Proteins, Protein Serine-Threonine Kinases, Biochemistry, Aspergillus nidulans, Catalysis, NIMA-Related Kinases, Amino Acid Sequence, Cysteine, Cloning, Molecular, Phosphorylation, Kinase activity, DNA, Fungal, Molecular Biology, Conserved Sequence, Cyclin, Base Sequence, Neurospora crassa, Sequence Homology, Amino Acid, biology, Kinase, Cell Cycle, Autophosphorylation, Temperature, Cell Biology, biology.organism_classification, Molecular biology, Enzyme Activation, NIMA-Related Kinase 1, biology.protein

Abstract

To investigate the degree of conservation of the cell cycle-specific NIMA protein kinase of Aspergillus nidulans, and to help direct its functional analysis, we cloned a homolog (designated nim-1) from Neurospora crassa. Over the catalytic domain NIM-1 is 75% identical to NIMA, but overall the identity drops to 52%. nim-1 was able to functionally complement nimA5 in A. nidulans. Mutational analysis of potential activating phosphorylation sites found in NIMA, NIM-1, and related protein kinases was performed on NIMA. Mutation of threonine 199 (conserved in all NIMA-related kinases) inhibited NIMA beta-casein kinase activity and abolished its in vivo function. This site conforms to a minimal consensus phosphorylation site for NIMA (FXXT) and is analogous to the autophosphorylation site of cyclic-AMP-dependent protein kinases. However, mutation of a unique cysteine residue found only in the catalytic site of NIMA and NIM-1 had no effect on NIMA kinase activity or function. Three temperature-sensitive alleles of nimA that cause arrest in G2 were sequenced and shown to generate three different amino acid substitutions. None of the mutations prevented accumulation of NIMA protein during G2 arrest, but all prevented the p34cdc2/cyclin B-dependent phosphorylation of NIMA normally seen during mitotic initiation even though p34cdc2/cyclin B H1 kinase activity was fully activated.

Published

1995

3. Cdk1 Activity Is Required for Mitotic Activation of Aurora A during G2/M Transition of Human Cells

Author

Van Horn, Robert D., primary, Chu, Shaoyou, additional, Fan, Li, additional, Yin, Tinggui, additional, Du, Jian, additional, Beckmann, Richard, additional, Mader, Mary, additional, Zhu, Guoxin, additional, Toth, John, additional, Blanchard, Kerry, additional, and Ye, Xiang S., additional

Published

2010

4. Proteolysis and Tyrosine Phosphorylation of p34 /Cyclin B

Author

Ye, Xiang S., primary, Fincher, Russell R., additional, Tang, Alice, additional, McNeal, Kimberly K., additional, Gygax, Scott E., additional, Wexler, Adam N., additional, Ryan, Kevin B., additional, James, Steven W., additional, and Osmani, Stephen A., additional

Published

1997

5. Isolation of a Functional Homolog of the Cell Cycle-specific NIMA Protein Kinase of Aspergillus nidulans and Functional Analysis of Conserved Residues

Author

Pu, Robert T., primary, Xu, Gang, additional, Wu, Liping, additional, Vierula, John, additional, O'Donnell, Kerry, additional, Ye, Xiang S., additional, and Osmani, Stephen A., additional

Published

1995

6. Cdk1 Activity Is Required for Mitotic Activation of Aurora A during G2/M Transition of Human Cells.

Author

Horn, Robert D. Van, Chu, Shaoyou, Fan, Ti, Yin, Tinggui, Du, Jian, Beckmann, Richard, Mader, Mary, Zhu, Guoxin, Toth, John, Blanchard, Kerry, and Ye, Xiang S.

Subjects

*MITOSIS, *CENTROSOMES, *CELLS, *KARYOKINESIS, *CELL cycle

Abstract

In mammalian cells entry into and progression through mitosis are regulated by multiple mitotic kinases. How mitotic kinases interact with each other and coordinately regulate mitosis remains to be fully understood. Here we employed a chemical biology approach using selective small molecule kinase inhibitors to dissect the relationship between Cdk1 and Aurora A kinases during G1/M transition. We find that activation of Aurora A first occurs at centrosomes at late G2 and is required for centrosome separation independently of Cdk1 activity. Upon entry into mitosis, Aurora A then becomes fully activated downstream of Cdk1 activation. Inactivation of Aurora A or Plk1 individually during a synchronized cell cycle shows no significant effect on Cdk1 activation and entry into mitosis. However, simultaneous inactivation of both Aurora A and Plk1 markedly delays Cdk1 activation and entry into mitosis, suggesting that Aurora A and Plk1 have redundant functions in the feedback activation of Cdk1. Together, our data suggest that Cdk1, Aurora A, and Plk1 mitotic kinases participate in a feedback activation loop and that activation of Cdk1 initiates the feedback loop activity, leading to rapid and timely entry into mitosis in human cells, in addition, live cell imaging reveals that the nuclear cycle of cells becomes uncoupled from cytokinesis upon inactivation of both Aurora A and Aurora B kinases and continues to oscillate in a Cdk1-dependent manner in the absence of cytokinesis, resulting in multinucleated, polyploidy cells. [ABSTRACT FROM AUTHOR]

Published

2010

7. Interaction of human dendritic cell receptor DEC205/CD205 with keratins.

Author

Kong D, Qian Y, Yu B, Hu Z, Cheng C, Wang Y, Fang Z, Yu J, Xiang S, Cao L, and He Y

Subjects

Humans, Dendritic Cells metabolism, Ligands, Mannose Receptor chemistry, Mutagenesis, Protein Binding, Protein Folding, Protein Structure, Tertiary, Protein Interaction Domains and Motifs, Crystallography, X-Ray, Keratins, Lectins, C-Type chemistry, Lectins, C-Type genetics, Lectins, C-Type metabolism, Models, Molecular

Abstract

DEC205 (CD205) is one of the major endocytic receptors on dendritic cells and has been widely used as a receptor target in immune therapies. It has been shown that DEC205 can recognize dead cells through keratins in a pH-dependent manner. However, the mechanism underlying the interaction between DEC205 and keratins remains unclear. Here we determine the crystal structures of an N-terminal fragment of human DEC205 (CysR∼CTLD3). The structural data show that DEC205 shares similar overall features with the other mannose receptor family members such as the mannose receptor and Endo180, but the individual domains of DEC205 in the crystal structure exhibit distinct structural features that may lead to specific ligand binding properties of the molecule. Among them, CTLD3 of DEC205 adopts a unique fold of CTLD, which may correlate with the binding of keratins. Furthermore, we examine the interaction of DEC205 with keratins by mutagenesis and biochemical assays based on the structural information and identify an XGGGX motif on keratins that can be recognized by DEC205, thereby providing insights into the interaction between DEC205 and keratins. Overall, these findings not only improve the understanding of the diverse ligand specificities of the mannose receptor family members at the molecular level but may also give clues for the interactions of keratins with their binding partners in the corresponding pathways., Competing Interests: Conflict of interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

8. Structural insights into Rad18 targeting by the SLF1 BRCT domains.

Author

Huang W, Qiu F, Zheng L, Shi M, Shen M, Zhao X, and Xiang S

Subjects

Protein Binding, Protein Domains, Peptides, DNA Repair, DNA Damage, Ubiquitin-Protein Ligases

Abstract

Rad18 interacts with the SMC5/6 localization factor 1 (SLF1) to recruit the SMC5/6 complex to DNA damage sites for repair. The mechanism of the specific Rad18 recognition by SLF1 is unclear. Here, we present the crystal structure of the tandem BRCT repeat (tBRCT) in SLF1 (SLF1 tBRCT ) bound with the interacting Rad18 peptide. Our structure and biochemical studies demonstrate that SLF1 tBRCT interacts with two phosphoserines and adjacent residues in Rad18 for high-affinity and specificity Rad18 recognition. We found that SLF1 tBRCT utilizes mechanisms common among tBRCTs as well as unique ones for Rad18 binding, the latter include interactions with an α-helical structure in Rad18 that has not been observed in other tBRCT-bound ligand proteins. Our work provides structural insights into Rad18 targeting by SLF1 and expands the understanding of BRCT-mediated complex assembly., Competing Interests: Conflict of interest The authors declare no conflict of interest., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

9. The GTPase KRAS suppresses the p53 tumor suppressor by activating the NRF2-regulated antioxidant defense system in cancer cells.

Author

Yang H, Xiang S, Kazi A, and Sebti SM

Subjects

Amino Acid Transport System y+ metabolism, Cell Line, Tumor, Cyclin-Dependent Kinase Inhibitor p21 genetics, Cyclin-Dependent Kinase Inhibitor p21 metabolism, Down-Regulation, Glutathione metabolism, Glutathione Disulfide metabolism, Humans, NAD(P)H Dehydrogenase (Quinone) metabolism, Phosphorylation, Protein Serine-Threonine Kinases antagonists & inhibitors, Protein Serine-Threonine Kinases metabolism, Proto-Oncogene Mas, Proto-Oncogene Proteins p21(ras) antagonists & inhibitors, Proto-Oncogene Proteins p21(ras) genetics, RNA Interference, RNA, Small Interfering metabolism, Reactive Oxygen Species metabolism, Signal Transduction, Tumor Suppressor Protein p53 genetics, ral GTP-Binding Proteins antagonists & inhibitors, ral GTP-Binding Proteins genetics, ral GTP-Binding Proteins metabolism, Antioxidants metabolism, NF-E2-Related Factor 2 metabolism, Proto-Oncogene Proteins p21(ras) metabolism, Tumor Suppressor Protein p53 metabolism

Abstract

In human cancer cells that harbor mutant KRAS and WT p53 (p53), KRAS contributes to the maintenance of low p53 levels. Moreover, KRAS depletion stabilizes and reactivates p53 and thereby inhibits malignant transformation. However, the mechanism by which KRAS regulates p53 is largely unknown. Recently, we showed that KRAS depletion leads to p53 Ser-15 phosphorylation (P-p53) and increases the levels of p53 and its target p21/WT p53-activated fragment 1 (WAF1)/CIP1. Here, using several human lung cancer cell lines, siRNA-mediated gene silencing, immunoblotting, quantitative RT-PCR, promoter-reporter assays, and reactive oxygen species (ROS) assays, we demonstrate that KRAS maintains low p53 levels by activating the NRF2 (NFE2-related factor 2)-regulated antioxidant defense system. We found that KRAS depletion led to down-regulation of NRF2 and its targets NQO1 (NAD(P)H quinone dehydrogenase 1) and SLC7A11 (solute carrier family 7 member 11), decreased the GSH/GSSG ratio, and increased ROS levels. We noted that the increase in ROS is required for increased P-p53, p53, and p21 Waf1/cip1 levels following KRAS depletion. Downstream of KRAS, depletion of RalB (RAS-like proto-oncogene B) and IκB kinase-related TANK-binding kinase 1 (TBK1) activated p53 in a ROS- and NRF2-dependent manner. Consistent with this, the IκB kinase inhibitor BAY11-7085 and dominant-negative mutant IκBαM inhibited NF-κB activity and increased P-p53, p53, and p21 Waf1/cip1 levels in a ROS-dependent manner. In conclusion, our findings uncover an important role for the NRF2-regulated antioxidant system in KRAS-mediated p53 suppression., (© 2020 Yang et al.)

Published

2020

10. HDAC6 regulates DNA damage response via deacetylating MLH1.

Author

Zhang M, Hu C, Moses N, Haakenson J, Xiang S, Quan D, Fang B, Yang Z, Bai W, Bepler G, Li GM, and Zhang XM

Subjects

Acetylation drug effects, Cell Line, Histone Deacetylase 6 genetics, Humans, MutL Protein Homolog 1 genetics, MutL Proteins genetics, MutL Proteins metabolism, MutS DNA Mismatch-Binding Protein genetics, MutS DNA Mismatch-Binding Protein metabolism, Mutation, Thioguanine pharmacology, DNA Damage, Histone Deacetylase 6 metabolism, MutL Protein Homolog 1 metabolism

Abstract

MutL homolog 1 (MLH1) is a key DNA mismatch repair protein, which plays an important role in maintenance of genomic stability and the DNA damage response. Here, we report that MLH1 is a novel substrate of histone deacetylase 6 (HDAC6). HDAC6 interacts with and deacetylates MLH1 both in vitro and in vivo Interestingly, deacetylation of MLH1 blocks the assembly of the MutSα-MutLα complex. Moreover, we have identified four novel acetylation sites in MLH1 by MS analysis. The deacetylation mimetic mutant, but not the WT and the acetylation mimetic mutant, of MLH1 confers resistance to 6-thioguanine. Overall, our findings suggest that the MutSα-MutLα complex serves as a sensor for DNA damage response and that HDAC6 disrupts the MutSα-MutLα complex by deacetylation of MLH1, leading to the tolerance of DNA damage., (© 2019 Zhang et al.)

Published

2019

11. Histone deacetylase 6 (HDAC6) deacetylates extracellular signal-regulated kinase 1 (ERK1) and thereby stimulates ERK1 activity.

Author

Wu JY, Xiang S, Zhang M, Fang B, Huang H, Kwon OK, Zhao Y, Yang Z, Bai W, Bepler G, and Zhang XM

Subjects

Acetylation, Amino Acid Motifs, Animals, Crystallography, X-Ray, Histone Deacetylase 6 chemistry, Histone Deacetylase 6 genetics, Humans, Mice, Mitogen-Activated Protein Kinase 1 chemistry, Mitogen-Activated Protein Kinase 1 genetics, Mitogen-Activated Protein Kinase 1 metabolism, Mitogen-Activated Protein Kinase 3 chemistry, Mitogen-Activated Protein Kinase 3 genetics, Mutation, Phosphorylation, Protein Binding, ets-Domain Protein Elk-1 genetics, ets-Domain Protein Elk-1 metabolism, Histone Deacetylase 6 metabolism, Mitogen-Activated Protein Kinase 3 metabolism

Abstract

Histone deacetylase 6 (HDAC6), a class IIb HDAC, plays an important role in many biological and pathological processes. Previously, we found that ERK1, a downstream kinase in the mitogen-activated protein kinase signaling pathway, phosphorylates HDAC6, thereby increasing HDAC6-mediated deacetylation of α-tubulin. However, whether HDAC6 reciprocally modulates ERK1 activity is unknown. Here, we report that both ERK1 and -2 are acetylated and that HDAC6 promotes ERK1 activity via deacetylation. Briefly, we found that both ERK1 and -2 physically interact with HDAC6. Endogenous ERK1/2 acetylation levels increased upon treatment with a pan-HDAC inhibitor, an HDAC6-specific inhibitor, or depletion of HDAC6, suggesting that HDAC6 deacetylates ERK1/2. We also noted that the acetyltransferases CREB-binding protein and p300 both can acetylate ERK1/2. Acetylated ERK1 exhibits reduced enzymatic activity toward the transcription factor ELK1, a well-known ERK1 substrate. Furthermore, mass spectrometry analysis indicated Lys-72 as an acetylation site in the ERK1 N terminus, adjacent to Lys-71, which binds to ATP, suggesting that acetylation status of Lys-72 may affect ERK1 ATP binding. Interestingly, an acetylation-mimicking ERK1 mutant (K72Q) exhibited less phosphorylation than the WT enzyme and a deacetylation-mimicking mutant (K72R). Of note, the K72Q mutant displayed decreased enzymatic activity in an in vitro kinase assay and in a cellular luciferase assay compared with the WT and K72R mutant. Taken together, our findings suggest that HDAC6 stimulates ERK1 activity. Along with our previous report that ERK1 promotes HDAC6 activity, we propose that HDAC6 and ERK1 may form a positive feed-forward loop, which might play a role in cancer., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

12. Ubiquitin-specific Peptidase 10 (USP10) Deubiquitinates and Stabilizes MutS Homolog 2 (MSH2) to Regulate Cellular Sensitivity to DNA Damage.

Author

Zhang M, Hu C, Tong D, Xiang S, Williams K, Bai W, Li GM, Bepler G, and Zhang X

Subjects

DNA Repair, DNA-Binding Proteins genetics, Humans, Peptide Hydrolases genetics, Ubiquitins genetics, DNA Damage, MutS Homolog 2 Protein genetics

Abstract

MSH2 is a key DNA mismatch repair protein, which plays an important role in genomic stability. In addition to its DNA repair function, MSH2 serves as a sensor for DNA base analogs-provoked DNA replication errors and binds to various DNA damage-induced adducts to trigger cell cycle arrest or apoptosis. Loss or depletion of MSH2 from cells renders resistance to certain DNA-damaging agents. Therefore, the level of MSH2 determines DNA damage response. Previous studies showed that the level of MSH2 protein is modulated by the ubiquitin-proteasome pathway, and histone deacetylase 6 (HDAC6) serves as an ubiquitin E3 ligase. However, the deubiquitinating enzymes, which regulate MSH2 remain unknown. Here we report that ubiquitin-specific peptidase 10 (USP10) interacts with and stabilizes MSH2. USP10 deubiquitinates MSH2 in vitro and in vivo Moreover, the protein level of MSH2 is positively correlated with the USP10 protein level in a panel of lung cancer cell lines. Knockdown of USP10 in lung cancer cells exhibits increased cell survival and decreased apoptosis upon the treatment of DNA-methylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) and antimetabolite 6-thioguanine (6-TG). The above phenotypes can be rescued by ectopic expression of MSH2. In addition, knockdown of MSH2 decreases the cellular mismatch repair activity. Overall, our results suggest a novel USP10-MSH2 pathway regulating DNA damage response and DNA mismatch repair., (© 2016 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2016

13. Histone deacetylase 10 regulates DNA mismatch repair and may involve the deacetylation of MutS homolog 2.

Author

Radhakrishnan R, Li Y, Xiang S, Yuan F, Yuan Z, Telles E, Fang J, Coppola D, Shibata D, Lane WS, Zhang Y, Zhang X, and Seto E

Subjects

Acetylation, DNA genetics, HeLa Cells, Histone Deacetylases genetics, Humans, MutS Homolog 2 Protein genetics, DNA metabolism, DNA Mismatch Repair, Histone Deacetylases metabolism, MutS Homolog 2 Protein metabolism

Abstract

MutS homolog 2 (MSH2) is an essential DNA mismatch repair (MMR) protein. It interacts with MSH6 or MSH3 to form the MutSα or MutSβ complex, respectively, which recognize base-base mispairs and insertions/deletions and initiate the repair process. Mutation or dysregulation of MSH2 causes genomic instability that can lead to cancer. MSH2 is acetylated at its C terminus, and histone deacetylase (HDAC6) deacetylates MSH2. However, whether other regions of MSH2 can be acetylated and whether other histone deacetylases (HDACs) and histone acetyltransferases (HATs) are involved in MSH2 deacetylation/acetylation is unknown. Here, we report that MSH2 can be acetylated at Lys-73 near the N terminus. Lys-73 is highly conserved across many species. Although several Class I and II HDACs interact with MSH2, HDAC10 is the major enzyme that deacetylates MSH2 at Lys-73. Histone acetyltransferase HBO1 might acetylate this residue. HDAC10 overexpression in HeLa cells stimulates cellular DNA MMR activity, whereas HDAC10 knockdown decreases DNA MMR activity. Thus, our study identifies an HDAC10-mediated regulatory mechanism controlling the DNA mismatch repair function of MSH2., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

14. Extracellular signal-regulated kinase (ERK) phosphorylates histone deacetylase 6 (HDAC6) at serine 1035 to stimulate cell migration.

Author

Williams KA, Zhang M, Xiang S, Hu C, Wu JY, Zhang S, Ryan M, Cox AD, Der CJ, Fang B, Koomen J, Haura E, Bepler G, Nicosia SV, Matthias P, Wang C, Bai W, and Zhang X

Subjects

Acetylation, Animals, CHO Cells, Cricetinae, Cricetulus, Embryo, Mammalian cytology, Embryo, Mammalian metabolism, ErbB Receptors genetics, ErbB Receptors metabolism, Fibroblasts cytology, Fibroblasts metabolism, Histone Deacetylase 6, Histone Deacetylases genetics, Humans, Mice, Mice, Mutant Strains, Mitogen-Activated Protein Kinase 3 genetics, Tubulin genetics, Cell Movement physiology, Histone Deacetylases metabolism, MAP Kinase Signaling System physiology, Mitogen-Activated Protein Kinase 3 metabolism, Tubulin metabolism

Abstract

Histone deacetylase 6 (HDAC6) is well known for its ability to promote cell migration through deacetylation of its cytoplasmic substrates such as α-tubulin. However, how HDAC6 itself is regulated to control cell motility remains elusive. Previous studies have shown that one third of extracellular signal-regulated kinase (ERK) is associated with the microtubule cytoskeleton in cells. Yet, no connection between HDAC6 and ERK has been discovered. Here, for the first time, we reveal that ERK binds to and phosphorylates HDAC6 to promote cell migration via deacetylation of α-tubulin. We have identified two novel ERK-mediated phosphorylation sites: threonine 1031 and serine 1035 in HDAC6. Both sites were phosphorylated by ERK1 in vitro, whereas Ser-1035 was phosphorylated in response to the activation of EGFR-Ras-Raf-MEK-ERK signaling pathway in vivo. HDAC6-null mouse embryonic fibroblasts rescued by the nonphosphorylation mimicking mutant displayed significantly reduced cell migration compared with those rescued by the wild type. Consistently, the nonphosphorylation mimicking mutant exerted lower tubulin deacetylase activity in vivo compared with the wild type. These data indicate that ERK/HDAC6-mediated cell motility is through deacetylation of α-tubulin. Overall, our results suggest that HDAC6-mediated cell migration could be governed by EGFR-Ras-Raf-MEK-ERK signaling.

Published

2013

15. Structure and function of allophanate hydrolase.

Author

Fan C, Li Z, Yin H, and Xiang S

Subjects

Amides metabolism, Biocatalysis, Catalytic Domain, Crystallography, X-Ray, Decarboxylation, Hydrolysis, Kinetics, Models, Molecular, Protein Multimerization, Protein Structure, Tertiary, Solutions, Structure-Activity Relationship, Allophanate Hydrolase chemistry, Allophanate Hydrolase metabolism, Fungal Proteins chemistry, Fungal Proteins metabolism, Kluyveromyces enzymology

Abstract

Allophanate hydrolase converts allophanate to ammonium and carbon dioxide. It is conserved in many organisms and is essential for their utilization of urea as a nitrogen source. It also has important functions in a newly discovered eukaryotic pyrimidine nucleic acid precursor degradation pathway, the yeast-hypha transition that several pathogens utilize to escape the host defense, and an s-triazine herbicide degradation pathway recently emerged in many soil bacteria. We have determined the crystal structure of the Kluyveromyces lactis allophanate hydrolase. Together with structure-directed functional studies, we demonstrate that its N and C domains catalyze a two-step reaction and contribute to maintaining a dimeric form of the enzyme required for their optimal activities. Our studies also provide molecular insights into their catalytic mechanism. Interestingly, we found that the C domain probably catalyzes a novel form of decarboxylation reaction that might expand the knowledge of this common reaction in biological systems.

Published

2013

16. Crystal structure of urea carboxylase provides insights into the carboxyltransfer reaction.

Author

Fan C, Chou CY, Tong L, and Xiang S

Subjects

Amino Acid Sequence, Carbon-Nitrogen Ligases genetics, Crystallography, X-Ray, Fungal Proteins genetics, Kinetics, Kluyveromyces chemistry, Kluyveromyces genetics, Models, Molecular, Molecular Sequence Data, Protein Structure, Tertiary, Carbon-Nitrogen Ligases chemistry, Carbon-Nitrogen Ligases metabolism, Fungal Proteins chemistry, Fungal Proteins metabolism, Kluyveromyces enzymology

Abstract

Urea carboxylase (UC) is conserved in many bacteria, algae, and fungi and catalyzes the conversion of urea to allophanate, an essential step in the utilization of urea as a nitrogen source in these organisms. UC belongs to the biotin-dependent carboxylase superfamily and shares the biotin carboxylase (BC) and biotin carboxyl carrier protein (BCCP) domains with these other enzymes, but its carboxyltransferase (CT) domain is distinct. Currently, there is no information on the molecular basis of catalysis by UC. We report here the crystal structure of the Kluyveromyces lactis UC and biochemical studies to assess the structural information. Structural and sequence analyses indicate the CT domain of UC belongs to a large family of proteins with diverse functions, including the Bacillus subtilis KipA-KipI complex, which has important functions in sporulation regulation. A structure of the KipA-KipI complex is not currently available, and our structure provides a framework to understand the function of this complex. Most interestingly, in the structure the CT domain interacts with the BCCP domain, with biotin and a urea molecule bound at its active site. This structural information and our follow-up biochemical experiments provided molecular insights into the UC carboxyltransfer reaction. Several structural elements important for the UC carboxyltransfer reaction are found in other biotin-dependent carboxylases and might be conserved within this family, and our data could shed light on the mechanism of catalysis of these enzymes.

Published

2012

17. Crystal structure of the MecA degradation tag.

Author

Wang F, Mei Z, Qi Y, Yan C, Xiang S, Zhou Z, Hu Q, Wang J, and Shi Y

Subjects

Amino Acid Sequence, Chromatography, Gel, Crystallography, X-Ray methods, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Peptide Hydrolases chemistry, Polymerase Chain Reaction, Protein Conformation, Protein Folding, Protein Structure, Secondary, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Bacillus subtilis metabolism, Bacterial Proteins chemistry

Abstract

MecA is an adaptor protein that regulates the assembly and activity of the ATP-dependent ClpCP protease in Bacillus subtilis. MecA contains two domains. Although the amino-terminal domain of MecA recruits substrate proteins such as ComK and ComS, the carboxyl-terminal domain (residues 121-218) has dual roles in the regulation and function of ClpCP protease. MecA-(121-218) facilitates the assembly of ClpCP oligomer, which is required for the protease activity of ClpCP. This domain was identified to be a non-recycling degradation tag that targets heterologous fusion proteins to the ClpCP protease for degradation. To elucidate the mechanism of MecA, we determined the crystal structure of MecA-(121-218) at 2.2 A resolution, which reveals a previously uncharacterized alpha/beta fold. Structure-guided mutagenesis allows identification of surface residues that are essential for the function of MecA. We also solved the structure of a carboxyl-terminal domain of YpbH, a paralogue of MecA in B. subtilis, at 2.4 A resolution. Despite low sequence identity, the two structures share essentially the same fold. The presence of MecA homologues in other bacterial species suggests conservation of a large family of unique degradation tags.

Published

2009

18. Crystal structure of 1-deoxy-D-xylulose 5-phosphate synthase, a crucial enzyme for isoprenoids biosynthesis.

Author

Xiang S, Usunow G, Lange G, Busch M, and Tong L

Subjects

Amino Acid Sequence, Catalysis, Deinococcus, Escherichia coli, Escherichia coli Proteins chemistry, Models, Molecular, Molecular Sequence Data, Molecular Structure, Protein Structure, Tertiary, Sequence Alignment, Structure-Activity Relationship, Terpenes metabolism, Transferases metabolism, Bacterial Proteins chemistry, Transferases chemistry

Abstract

Isopentenyl pyrophosphate (IPP) is a common precursor for the synthesis of all isoprenoids, which have important functions in living organisms. IPP is produced by the mevalonate pathway in archaea, fungi, and animals. In contrast, IPP is synthesized by a mevalonate-independent pathway in most bacteria, algae, and plant plastids. 1-Deoxy-D-xylulose 5-phosphate synthase (DXS) catalyzes the first and the rate-limiting step of the mevalonate-independent pathway and is an attractive target for the development of novel antibiotics, antimalarials, and herbicides. We report here the first structural information on DXS, from Escherichia coli and Deinococcus radiodurans, in complex with the coenzyme thiamine pyrophosphate (TPP). The structure contains three domains (I, II, and III), each of which bears homology to the equivalent domains in transketolase and the E1 subunit of pyruvate dehydrogenase. However, DXS has a novel arrangement of these domains as compared with the other enzymes, such that the active site of DXS is located at the interface of domains I and II in the same monomer, whereas that of transketolase is located at the interface of the dimer. The coenzyme TPP is mostly buried in the complex, but the C-2 atom of its thiazolium ring is exposed to a pocket that is the substrate-binding site. The structures identify residues that may have important roles in catalysis, which have been confirmed by our mutagenesis studies.

Published

2007

19. Structural insights into sulfite oxidase deficiency.

Author

Karakas E, Wilson HL, Graf TN, Xiang S, Jaramillo-Busquets S, Rajagopalan KV, and Kisker C

Subjects

Amino Acid Sequence, Animals, Arginine chemistry, Base Sequence, Binding Sites, Chickens, Crystallography, X-Ray, Humans, Hydrogen-Ion Concentration, Kinetics, Mass Spectrometry, Models, Chemical, Models, Molecular, Molecular Sequence Data, Molybdenum chemistry, Mutation, Oxidoreductases Acting on Sulfur Group Donors genetics, Oxidoreductases Acting on Sulfur Group Donors isolation & purification, Protein Binding, Protein Conformation, Recombinant Proteins chemistry, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Static Electricity, Substrate Specificity, Sulfates metabolism, Oxidoreductases Acting on Sulfur Group Donors chemistry, Oxidoreductases Acting on Sulfur Group Donors deficiency, Oxidoreductases Acting on Sulfur Group Donors metabolism

Abstract

Sulfite oxidase deficiency is a lethal genetic disease that results from defects either in the genes encoding proteins involved in molybdenum cofactor biosynthesis or in the sulfite oxidase gene itself. Several point mutations in the sulfite oxidase gene have been identified from patients suffering from this disease worldwide. Although detailed biochemical analyses have been carried out on these mutations, no structural data could be obtained because of problems in crystallizing recombinant human and rat sulfite oxidases and the failure to clone the chicken sulfite oxidase gene. We synthesized the gene for chicken sulfite oxidase de novo, working backward from the amino acid sequence of the native chicken liver enzyme by PCR amplification of a series of 72 overlapping primers. The recombinant protein displayed the characteristic absorption spectrum of sulfite oxidase and exhibited steady state and rapid kinetic parameters comparable with those of the tissue-derived enzyme. We solved the crystal structures of the wild type and the sulfite oxidase deficiency-causing R138Q (R160Q in humans) variant of recombinant chicken sulfite oxidase in the resting and sulfate-bound forms. Significant alterations in the substrate-binding pocket were detected in the structure of the mutant, and a comparison between the wild type and mutant protein revealed that the active site residue Arg-450 adopts different conformations in the presence and absence of bound sulfate. The size of the binding pocket is thereby considerably reduced, and its position relative to the cofactor is shifted, causing an increase in the distance of the sulfur atom of the bound sulfate to the molybdenum.

Published

2005

20. Binding of low density lipoproteins to lipoprotein lipase is dependent on lipids but not on apolipoprotein B.

Author

Boren J, Lookene A, Makoveichuk E, Xiang S, Gustafsson M, Liu H, Talmud P, and Olivecrona G

Subjects

Animals, Cattle, Cell Line, Heparin metabolism, Humans, Liposomes, Mice, Mice, Transgenic, Protein Binding, Apolipoproteins B metabolism, Lipid Metabolism, Lipoprotein Lipase metabolism, Lipoproteins, LDL metabolism

Abstract

Lipoprotein lipase (LPL) efficiently mediates the binding of lipoprotein particles to lipoprotein receptors and to proteoglycans at cell surfaces and in the extracellular matrix. It has been proposed that LPL increases the retention of atherogenic lipoproteins in the vessel wall and mediates the uptake of lipoproteins in cells, thereby promoting lipid accumulation and plaque formation. We investigated the interaction between LPL and low density lipoproteins (LDLs) with special reference to the protein-protein interaction between LPL and apolipoprotein B (apoB). Chemical modification of lysines and arginines in apoB or mutation of its main proteoglycan binding site did not abolish the interaction of LDL with LPL as shown by surface plasmon resonance (SPR) and by experiments with THP-I macrophages. Recombinant LDL with either apoB100 or apoB48 bound with similar affinity. In contrast, partial delipidation of LDL markedly decreased binding to LPL. In cell culture experiments, phosphatidylcholine-containing liposomes competed efficiently with LDL for binding to LPL. Each LDL particle bound several (up to 15) LPL dimers as determined by SPR and by experiments with THP-I macrophages. A recombinant NH(2)-terminal fragment of apoB (apoB17) bound with low affinity to LPL as shown by SPR, but this interaction was completely abolished by partial delipidation of apoB17. We conclude that the LPL-apoB interaction is not significant in bridging LDL to cell surfaces and matrix components; the main interaction is between LPL and the LDL lipids.

Published

2001