Cheng-Yang Huang

Crystal structure of the human FOXO3a-DBD/DNA complex suggests the effects of post-translational modification

FOXO3a is a transcription factor of the FOXO family. The FOXO proteins participate in multiple signaling pathways, and their transcriptional activity is regulated by several post-translational mechanisms, including phosphorylation, acetylation and ubiquitination. Because these post-translational modification sites are located within the C-terminal basic region of the FOXO DNA-binding domain (FOXO-DBD), it is possible that these post-translational modifications could alter the DNA-binding characteristics. To understand how FOXO mediate transcriptional activity, we report here the 2.7 Å crystal structure of the DNA-binding domain of FOXO3a (FOXO3a-DBD) bound to a 13-bp DNA duplex containing a FOXO consensus binding sequence (GTAAACA). Based on a unique structural feature in the C-terminal region and results from biochemical and mutational studies, our studies may explain how FOXO-DBD C-terminal phosphorylation by protein kinase B (PKB) or acetylation by cAMP-response element binding protein (CBP) can attenuate the DNA-binding activity and thereby reduce transcriptional activity of FOXO proteins. In addition, we demonstrate that the methyl groups of specific thymine bases within the consensus sequence are important for FOXO3a-DBD recognition of the consensus binding site.

The crystal structure of a replicative hexameric helicase DnaC and its complex with single-stranded DNA

DNA helicases are motor proteins that play essential roles in DNA replication, repair and recombination. In the replicative hexameric helicase, the fundamental reaction is the unwinding of duplex DNA; however, our understanding of this function remains vague due to insufficient structural information. Here, we report two crystal structures of the DnaB-family replicative helicase from Geobacillus kaustophilus HTA426 (GkDnaC) in the apo-form and bound to single-stranded DNA (ssDNA). The GkDnaC–ssDNA complex structure reveals that three symmetrical basic grooves on the interior surface of the hexamer individually encircle ssDNA. The ssDNA-binding pockets in this structure are directed toward the N-terminal domain collar of the hexameric ring, thus orienting the ssDNA toward the DnaG primase to facilitate the synthesis of short RNA primers. These findings provide insight into the mechanism of ssDNA binding and provide a working model to establish a novel mechanism for DNA translocation at the replication fork.

Complexed crystal structure of replication restart primosome protein PriB reveals a novel single-stranded DNA-binding mode

PriB is a primosomal protein required for replication restart in Escherichia coli. PriB stimulates PriA helicase activity via interaction with single-stranded DNA (ssDNA), but the molecular details of this interaction remain unclear. Here, we report the crystal structure of PriB complexed with a 15 bases oligonucleotide (dT15) at 2.7 Å resolution. PriB shares structural similarity with the E.coli ssDNA-binding protein (EcoSSB). However, the structure of the PriB–dT15 complex reveals that PriB binds ssDNA differently. Results from filter-binding assays show that PriB–ssDNA interaction is salt-sensitive and cooperative. Mutational analysis suggests that the loop L45 plays an important role in ssDNA binding. Based on the crystal structure and biochemical analyses, we propose a cooperative mechanism for the binding of PriB to ssDNA and a model for the assembly of the PriA–PriB–ssDNA complex. This report presents the first structure of a replication restart primosomal protein complexed with DNA, and a novel model that explains the interactions between a dimeric oligonucleotide-binding-fold protein and ssDNA.

Crystal structure of the human FOXK1a-DNA complex and its implications on the diverse binding specificity of winged helix/forkhead proteins

Interleukin enhancer binding factor (ILF) is a human transcription factor and a new member of the winged helix/forkhead family. ILF can bind to purine-rich regulatory motifs such as the human T-cell leukemia virus-long terminal region and the interleukin-2 promoter. Here we report the 2.4 Å crystal structure of two DNA binding domains of ILF (FOXK1a) binding to a 16-bp DNA duplex containing a promoter sequence. Electrophoretic mobility shift assay studies demonstrate that two ILF-DNA binding domain molecules cooperatively bind to DNA. In addition to the recognition helix recognizing the core sequences through the major groove, the structure shows that wing 1 interacts with the minor groove of DNA, and the H2-H3 loop region makes ionic bonds to the phosphate group, which permits the recognition of DNA. The structure also reveals that the presence of the C-terminal α-helix in place of a typical wing 2 in a member of this family alters the orientation of the C-terminal basic residues (RKRRPR) when binding to DNA outside the core sequence. These results provide a new insight into how the DNA binding specificities of winged helix/forkhead proteins may be regulated by their less conserved regions.

The role of metal on imide hydrolysis: metal content and pH profiles of metal ion-replaced mammalian imidase

Imidase catalyzes the hydrolysis of a variety of imides. The removal of metal from imidase eliminates its activity but does not affect its tetrameric and secondary structure. The reactivation of the apoenzyme with transition metal ions Co(2+), Zn(2+), Mn(2+), and Cd(2+) shows that imidase activity is linearly dependent on the amount of metal ions added. Ni(2+) and Cu(2+) are also inserted, one per enzyme subunit, into the apoimidase, but do not restore imidase activity. Enzyme activity with different metal replaced imidase varies significantly. However, the changes of the metal contents do not appear to affect the pK(a)s obtained from the bell-shaped pH profiles of metal reconstituted imidase. The metal-hydroxide mechanism for imidase action is not supported based on the novel findings from this study. It is proposed that metal ion in mammalian imidase functions as a Lewis acid, which stabilizes the developing negative charge of imide substrate in transition state.

Effect of metal binding and posttranslational lysine carboxylation on the activity of recombinant hydantoinase.

Bacterial hydantoinase possesses a binuclear metal center in which two metal ions are bridged by a posttranslationally carboxylated lysine. How the carboxylated lysine and metal binding affect the activity of hydantoinase was investigated. A significant amount of iron was always found in Agrobacterium radiobacter hydantoinase purified from unsupplemented cobalt-, manganese-, or zinc-amended Escherichia coli cell cultures. A titration curve for the reactivation of apohydantoinase with cobalt indicates that the first metal was preferentially bound but did not give any enzyme activity until the second metal was also attached to the hydantoinase. The pH profiles of the metal-reconstituted hydantoinase were dependent on the specific metal ion bound to the active site, indicating a direct involvement of metal in catalysis. Mutation of the metal binding site residues, H57A, H59A, K148A, H181A, H237A, and D313A, completely abolished hydantoinase activity but preserved about half of the metal content, except for K148A, which lost both metals in its active site. However, the activity of K148A could be chemically rescued by short-chain carboxylic acids in the presence of cobalt, indicating that the carboxylated lysine was needed to coordinate the binuclear ion within the active site of hydantoinase. The mutant D313E enzyme was also active but resulted in a pH profile different from that of wild-type hydantoinase. A mechanism for hydantoinase involving metal, carboxylated K148, and D313 was proposed.

Crystal structure and DNA-binding mode of Klebsiella pneumoniae primosomal PriB protein

PriB is a primosomal DNA replication protein required for the re‐initiation of replication in bacteria. In this study, we investigated the gene expression of PriB in Klebsiella pneumoniae (KpPriB) and characterized the gene product through crystal structural and functional analyses. Quantitative polymerase chain reaction analysis (Q‐PCR) indicated that the 104‐aa priB was expressed in K. pneumoniae with a CT value of 22.4. The crystal structure of KpPriB (Protein Data Bank entry: 4APV) determined at a resolution of 2.1 Å was similar to that of Escherichia coli PriB (EcPriB). KpPriB formed a single complex with single‐stranded DNA (ssDNA) of different lengths, suggesting a highly cooperative process. Structure‐based mutational analysis revealed that substitution at K18, F42, R44, W47, K82, K84, or K89 but not R34 in KpPriB had a significant effect on both ssDNA and double‐stranded DNA (dsDNA) binding. Based on these findings, the known ssDNA interaction sites of PriB were expanded to include R44 and F42, thus allowing nucleic acids to wrap around the whole PriB protein.

DnaT is a single-stranded DNA binding protein

DnaT is one of the replication restart primosomal proteins required for reinitiating chromosomal DNA replication in bacteria. In this study, we identified and characterized the single‐stranded DNA (ssDNA)‐binding properties of DnaT using electrophoretic mobility shift analysis (EMSA), bioinformatic tools and two deletion mutant proteins, namely, DnaT26‐179 and DnaT42‐179. ConSurf analysis indicated that the N‐terminal region of DnaT is highly variable. The analysis of purified DnaT and the deletion mutant protein DnaT42‐179 by gel filtration chromatography showed a stable trimer in solution, indicating that the N‐terminal region, amino acid 1–41, is not crucial for the oligomerization of DnaT. Contrary to PriB, which forms a single complex with a series of ssDNA homopolymers, DnaT, DnaT26‐179 and DnaT42‐179 form distinct complexes with ssDNA of different lengths and the size of binding site of 26 ± 2 nucleotides (nt). Using bioinformatic programs (ps)2 and the analysis of the positively charged/hydrophobic residue distribution, as well as the biophysical results in this study, we propose a binding model for the DnaT trimer–ssDNA complex, in which 25‐nt‐long ssDNA is tethered on the surface groove located in the highly conserved C‐terminal domain of DnaT. These results constitute the first study regarding ssDNA‐binding activity of DnaT. Consequently, a hand‐off mechanism for primosome assembly was modified.

Characterization of Flavonol Inhibition of DnaB Helicase: Real-Time Monitoring, Structural Modeling, and Proposed Mechanism

DnaB helicases are motor proteins essential for DNA replication, repair, and recombination and may be a promising target for developing new drugs for antibiotic-resistant bacteria. Previously, we established that flavonols significantly decreased the binding ability of Klebsiella pneumoniae DnaB helicase (KpDnaB) to dNTP. Here, we further investigated the effect of flavonols on the inhibition of the ssDNA binding, ATPase activity, and dsDNA-unwinding activity of KpDnaB. The ssDNA-stimulated ATPase activity of KpDnaB was decreased to 59%, 75%, 65%, and 57%, in the presence of myricetin, quercetin, kaempferol, and galangin, respectively. The ssDNA-binding activity of KpDnaB was only slightly decreased by flavonols. We used a continuous fluorescence assay, based on fluorescence resonance energy transfer (FRET), for real-time monitoring of KpDnaB helicase activity in the absence and presence of flavonols. Using this assay, the flavonol-mediated inhibition of the dsDNA-unwinding activity of KpDnaB was observed. Modeled structures of bound and unbound DNA showed flavonols binding to KpDnaB with distinct poses. In addition, these structural models indicated that L214 is a key residue in binding any flavonol. On the basis of these results, we proposed mechanisms for flavonol inhibition of DNA helicase. The resulting information may be useful in designing compounds that target K. pneumoniae and other bacterial DnaB helicases.

Identification of a novel protein, PriB, in Klebsiella pneumoniae.

PriB is a primosomal protein required for the reinitiation of replication in bacteria. Here, we report the identification and characterization of a novel PriB protein in Klebsiella pneumoniae (KPN_04595; KpPriB). Unlike the well-studied Escherichia coli PriB protein (EcPriB), which exists as a homodimer comprising 104-aa polypeptides, KpPriB forms a monomer of only 55 aa, due to the absence of the 49 aa N-terminus in KpPriB. Although this N-terminal region (1-49 aa) in EcPriB contains several important residues, such as K18, R34, and W47, which are crucial for ssDNA binding, we found that KpPriB binds ssDNA, but not ssRNA, with comparable affinity as that for EcPriB. Results from filter-binding assays demonstrate that the KpPriB-ssDNA interaction is cooperative and salt-sensitive. Substituting the residue K33 in KpPriB with alanine, the position corresponding to the classic ssDNA-binding residue K82 of EcPriB located in loop L(45), significantly reduced ssDNA-binding activity and cooperativity. These results reveal that the 1-49 aa region of the classical PriB protein is unnecessary for ssDNA binding. On the basis of these findings, the structure-function relationships of KpPriB are discussed.