Large scale preparation of the mammalian high mobility group protein A2 for biophysical studies

Due to asymmetrical charge distribution of the mammalian high mobility group protein A2 (HMGA2), which makes HMGA2 bind to both cation- and anion-exchange columns, we developed a rapid procedure for purifying HMGA2 in the milligram range. This purification procedure greatly facilitated biophysical studies, which require large amounts of the protein.     

AT-hook peptides bind the major and minor groove of AT-rich DNA duplexes

The mammalian high mobility group protein AT-hook 2 (HMGA2) houses three motifs that preferentially bind short stretches of AT-rich DNA regions. These DNA binding motifs, known as ‘AT-hooks’, are traditionally characterized as being unstructured. Upon binding to AT-rich DNA, they form ordered assemblies. It is this disordered-to-ordered transition that has implicated HMGA2 as a protein actively involved in many biological processes, with abnormal HMGA expression linked to a variety of health problems including diabetes, obesity, and oncogenesis. In the current work, the solution binding dynamics of the three ‘AT-hook’ peptides (ATHPs) with AT-rich DNA hairpin substrates were studied using DNA UV melting studies, fluorescence spectroscopy, native ion mobility spectrometry-mass spectrometry (IMS-MS), solution isothermal titration calorimetry (ITC) and molecular modeling. Results showed that the ATHPs bind to the DNA to form a single, 1:1 and 2:1, ‘key-locked’ conformational ensemble. The molecular models showed that 1:1 and 2:1 complex formation is driven by the capacity of the ATHPs to bind to the minor and major grooves of the AT-rich DNA oligomers. Complementary solution ITC results confirmed that the 2:1 stoichiometry of ATHP: DNA is originated under native conditions in solution.     

Characterization of high mobility group protein binding to cisplatin-damaged DNA.

cis-Diamminedichloroplatinum (II) (cisplatin, CDDP) is a widely used chemotherapeutic agent. While many tumors are highly responsive to CDDP, certain tumors are resistant to this drug, limiting its efficacy. The anti-tumor activity of CDDP is believed to result from its coordination bonding to chromosomal DNA. Alterations in tumor cell sensitivity to CDDP may result from the presence or absence of protein(s) which specifically recognize CDDP-damaged DNA. We have developed a damaged-DNA affinity precipitation assay that allows the direct identification of cellular proteins that bind to CDDP-damaged DNA. Using this procedure, we have identified several proteins which specifically bind to CDDP-damaged DNA. Two of these proteins have been identified as high mobility group proteins (HMG) 1 and 2 in the current report, we have characterized the binding of these proteins to CDDP-DNA. The calculated Kd of binding to CDDP-damaged DNA was 3.27 x 10(-10) for HMG1 and 1.87 x 10(-10) for HMG2. Using highly specific chemical modifying reagents, we have determined that Cys residues play an important role in protein binding. We also observed that HMG2 will bind to DNA modified with carboplatin and iproplatin although to a lesser extent than to DNA damaged with CDDP. Thus, our results indicate that HMG 2 binds with high affinity to DNA modified with therapeutically active platinum compounds. In addition, our findings suggest that thiol groups play an essential role in the binding of HMG1 and HMG2 to CDDP-DNA.     

Phosphorylation by cdc2 kinase modulates DNA binding activity of high mobility group I nonhistone chromatin protein

Chromatin high mobility group protein I (HMG-I) is a mammalian nonhistone protein that has been demonstrated both in vitro and in vivo to preferentially bind to A.T-rich sequences of DNA. Recently the DNA-binding domain peptide that specifically mediates the in vitro interaction of high mobility group protein (HMG)-I with the narrow minor groove of A.T-DNA has been experimentally determined. Because of its predicted secondary structure, the binding domain peptide has been called "the A.T hook" motif. Previously we demonstrated that the A.T hook of murine HMG-I protein is specifically phosphorylated by purified mammalian cdc2 kinase in vitro and that the same site(s) are also phosphorylated in vivo in metaphase-arrested cells. We also found that the DNA binding affinity of short synthetic binding domain peptides phosphorylated in vitro by cdc2 kinase was significantly reduced compared with unphosphorylated peptides. Here we extend these findings to intact natural and recombinant HMG-I proteins. We report that the affinity of binding of full-length HMG-I proteins to A.T-rich sequences is highly dependent on ionic conditions and that phosphorylation of intact proteins by cdc2 kinase reduces their affinity of in vitro binding to A.T-DNA by about 20-fold when assayed near normal mammalian physiological salt concentrations. Furthermore, in cell synchronization studies, we demonstrated that murine HMG-I proteins are phosphorylated in vivo in a cell cycle-dependent manner on the same amino acid residues modified by purified cdc2 kinase in vitro. Together these results strongly support the assertion that HMG-I proteins are natural substrates for mammalian cdc2 kinase in vivo and that their cell cycle-dependent phosphorylation by this enzyme(s) significantly modulates their DNA binding affinity, thereby possibly altering their biological function(s).     

Upregulation of the high mobility group AT-hook 2 gene in acute aortic dissection is potentially associated with endothelial-mesenchymal transition

The high mobility group AT-hook 2 (HMGA2) gene is proposed to regulate the genes involved in the epithelial-mesenchymal transition (EMT). One form of EMT is endothelial-mesenchymal transition (EndMT). We analyzed the expression profile of the HMGA2 gene in different human aortic diseases. Aortic specimens were collected from 51 patients, including 19 with acute aortic dissection, 26 with aortic aneurysm, two with Marfan syndrome and four aortic valves. Quantitative real-time polymerase chain reaction was carried out for HMGA2 and immunohistochemical analyses were performed for HMGA2, SNAI1, Vimentin, CD34, MKI-67 and TGFB1. The expression of let-7d microRNA, which is assumed to play a role in the regulation of HMGA2, was also quantified. The level of HMGA2 gene expression was significantly higher in acute aortic dissection compared with all the other samples (193.1 vs. 8.1 fold normalized to calibrator, P<0.001). The immunohistochemical investigation showed that HMGA2, SNAI1, and Vimentin proteins were mainly detected in the endothelial cells of the vasa vasorum. The HMGA2 gene is upregulated in acute aortic dissection. This is the first report describing a link between HMGA2 and acute aortic dissection. The HMGA2, SNAI1 and Vimentin proteins were mainly detected in the endothelium of the vasa vasorum. It seems that HMGA2 overexpression in acute aortic dissection occurs in a let-7d-independent manner and is associated with EndMT of the vasa vasorum.     

Phosphorylation of human high mobility group N1 protein by protein kinase CK2

High mobility group (HMG) N1 protein, formerly known as HMG 14, is a member of the chromosomal HMG protein family. Protein kinase CK2 was previously reported to be able to phosphorylate bovine HMGN1 in vitro; Ser89 and Ser99, corresponding to Ser88 and Ser98 in human HMGN1, were shown to be major and minor recognition sites, respectively. In this report, we employed mass spectrometry and examined both the extent and the sites of phosphorylation in HMGN1 protein catalyzed by recombinant human protein kinase CK2. We found that five serine residues, i.e., Ser6, Ser7, Ser85, Ser88, and Ser98, in HMGN1 can be phosphorylated by the kinase in vitro. All five sites were previously shown to be phosphorylated in MCF-7 human breast cancer cells in vivo. Among these five sites, Ser6, Ser7, and Ser85 were new sites of phosphorylation induced by protein kinase CK2 in vitro.     

Identification of a single-stranded DNA binding protein from rat liver with high mobility group protein 1

The rat liver single-stranded DNA binding protein, S25 and HD25, isolated by differential DNA cellulose affinity chromatography was compared to the high mobility group proteins, HMG1 and HMG2, isolated from rat liver chromatin by the technique of Goodwin et al. (Goodwin, G. H., Sanders, C., and Johns, E. W. (1973) Eur. J. Biochem. 38, 14-19). Analysis of their amino acid composition, electrophoretic mobility, and tryptic peptide map reveal the identity of the single-stranded DNA binding protein with HMG1 protein, implying that the rat liver HMG1 protein becomes able both to destabilize a double helix of DNA and to stimulate homologous DNA polymerases only when rat liver cells enter a phase of DNA synthesis, possibly after a specific modification.     

Interaction with p53 enhances binding of cisplatin-modified DNA by high mobility group 1 protein

A nonhistone chromosomal protein, high mobility group (HMG) 1, is ubiquitous in higher eukaryotic cells and binds preferentially to cisplatin-modified DNA. HMG1 also functions as a coactivator of p53, a tumor suppressor protein. We investigated physical interactions between HMG1 and p53 and the influence of p53 on the ability of HMG1 to recognize damaged DNA. Using immunochemical coprecipitation, we observed binding of HMG1 and p53. Interaction between HMG1 and p53 required the HMG A box of HMG1 and amino acids 363-376 of p53. Cisplatin-modified DNA binding by HMG1 was significantly enhanced by p53. An HMG1-specific antibody that recognized the A box of this protein also stimulated cisplatin-modified DNA binding. These data suggest that an interaction with either p53 or antibody may induce conformational change in the HMG1 A box that optimizes DNA binding by HMG1. Interaction of p53 with HMG1 after DNA damage may promote activation of specific HMG1 binding to damaged DNA in vivo and provide a molecular link between DNA damage and p53-mediated DNA repair.     

Phosphorylation alters the affinity of high mobility group protein HMG 14 for single-stranded DNA

The effect of phosphorylation on the affinity of HMG 14 from calf thymus for single-stranded DNA (ssDNA) was studied, using a cyclic GMP-dependent protein kinase from bovine lung and a nuclear protein kinase II from rat liver. When phosphorylated by G-kinase, HMG 14 eluted at 0.27 M NaCl from the ssDNA-column, whereas the native protein eluted at 0.30 M salt concentration. In contrast, phosphorylation by nuclear protein kinase II did not alter dissociation of HMG 14 from ssDNA and the phosphoprotein consequently coeluted with the native HMG 14. Thus, addition of a negative charge by phosphorylation of the Ser-6 residue by G-kinase presumably weakens the interaction between the DNA-binding amino acids of HMG 14 and the negatively charged phosphate groups of DNA.     

Phosphorylation of high mobility group 14 protein by cyclic nucleotide-dependent protein kinases

Chromosomal high mobility group (HMG) proteins have been examined as substrates for cGMP-dependent and cAMP-dependent protein kinases. Of the four HMG proteins only HMG 14 contained a major high affinity site which could be phosphorylated by both enzymes, preferentially by cGMP-dependent protein kinase. One mol of 32P was incorporated/mol of HMG 14. Kinetic analysis revealed apparent Km and Vmax of 40.5 microM and 14.7 mumol/min/mg, respectively, for cGMP-dependent protein kinase, and 123 microM and 11.1 mumol/min/mg, respectively, for cAMP-dependent protein kinase. Tryptic maps of 32P-labeled phosphopeptides of HMG 14 demonstrated phosphorylation of the same site by both enzymes. The tryptic fragment containing the major phosphorylation site was identified by amino acid composition and sequence as HMG 14 (residues 4-13): H-Lys-Val-Ser(P)-Ser-Ala-Glu-Gly-Ala-Ala-Lys-OH. HMG 14 and HMG 17 also contained minor sites which could be phosphorylated by cGMP-dependent protein kinase. Tryptic phosphopeptides mapping suggested that the same minor site was phosphorylated on both HMG 14 and 17. On the basis of amino acid composition, the tryptic peptides carrying the minor phosphorylation sites were identified as H-Leu-Ser(P)-Ala-Lys representing residues 23-26 and 27-30 of HMG 14 and HMG 17, respectively.     

DNA minor groove recognition of a non-self-complementary AT-rich sequence by a tris-benzimidazole ligand.

The crystal structure of the non-self-complementary dodecamer DNA duplex formed by d(CG[5BrC]ATAT-TTGCG) and d(CGCAAATATGCG) has been solved to 2.3 A resolution, together with that of its complex with the tris-benzimidazole minor groove binding ligand TRIBIZ. The inclusion of a bromine atom on one strand in each structure enabled the possibility of disorder to be discounted. The native structure has an exceptional narrow minor groove, of 2.5-2.6 A in the central part of the A/T region, which is increased in width by approximately 0.8 A on drug binding. The ligand molecule binds in the central part of the sequence. The benzimidazole subunits of the ligand participate in six bifurcated hydrogen bonds with A:T base pair edges, three to each DNA strand. The presence of a pair of C-H...O hydrogen bonds has been deduced from the close proximity of the pyrrolidine group of the ligand to the TpA step in the sequence.     

Microheterogeneity of the mammalian high mobility group (HMG) proteins 1 and 2 investigated by reverse-phase high performance liquid chromatography

Microheterogeneity within the high mobility group (HMG)-1 and HMG-2 groups of nonhistone chromatin proteins has been investigated using reverse-phase high-performance liquid chromatography (RP-HPLC) under conditions (acetonitrile elution with 0.1% trifluoroacetic acid (TFA) as the counter ion) which separate proteins primarily on the basis of differences in their overall hydrophobicity. RP-HPLC proved to be a fast and efficient means for separating multiple subspecies of both the HMG-1 and HMG-2 proteins from both crude nuclear extracts and from ion-exchange column "purified" protein samples obtained from different types of mammalian cell nuclei. In crude nuclear extracts at least eight different HMG-2 protein species (two major and six minor), but only one major HMG-1 species, could be resolved by RP-HPLC. Three of the minor HMG-2 protein species could be isolated in "pure" form from crude extracts in one RP-HPLC step whereas under the same conditions the two major HMG-2 peaks (as well as the other minor species) were contaminated with either HMG-1 or HMG-3 (a degradation product of HMG-1). In crude extracts the major HMG-1 fraction always seems to be contaminated with one of the HMG-2 subfractions. RP-HPLC analysis of apparently "pure" protein preparations isolated by ion-exchange chromatography techniques revealed that "pure" HMG-1 can be resolved into at least three different protein species and "pure" HMG-2 into at least four different species. Amino acid analyses of different resolvable forms of the HMG proteins were not inconsistent with the suggestion that at least some of these may be primary sequence variants of the individual proteins, but other possibilities also exist.     

The yeast high mobility group protein HMO2, a subunit of the chromatin-remodeling complex INO80, binds DNA ends

DNA damage is a common hazard that all cells have to combat. Saccharomyces cerevisiae HMO2 is a high mobility group protein (HMGB) that is a component of the chromatin-remodeling complex INO80, which is involved in double strand break (DSB) repair. We show here using DNA end-joining and exonuclease protection assays that HMO2 binds preferentially to DNA ends. While HMO2 binds DNA with both blunt and cohesive ends, the sequence of a single stranded overhang significantly affects binding, supporting the conclusion that HMO2 recognizes features at DNA ends. Analysis of the effect of duplex length on the ability of HMO2 to protect DNA from exonucleolytic cleavage suggests that more than one HMO2 must assemble at each DNA end. HMO2 binds supercoiled DNA with higher affinity than linear DNA and has a preference for DNA with lesions such as pairs of tandem mismatches; however, comparison of DNA constructs of increasing length suggests that HMO2 may not bind stably as a monomer to distorted DNA. The remarkable ability of HMO2 to protect DNA from exonucleolytic cleavage, combined with reports that HMO2 arrives early at DNA DSBs, suggests that HMO2 may play a role in DSB repair beyond INO80 recruitment.     

Interplay between human high mobility group protein 1 and replication protein A on psoralen-cross-linked DNA

Human high mobility group box (HMGB) 1 and -2 proteins are highly conserved and abundant chromosomal proteins that regulate chromatin structure and DNA metabolism. HMGB proteins bind preferentially to DNA that is bent or underwound and to DNA damaged by agents such as cisplatin, UVC radiation, and benzo[a]pyrenediol epoxide (BPDE). Binding of HMGB1 to DNA adducts is thought to inhibit nucleotide excision repair (NER), leading to cell death, but the biological roles of these proteins remain obscure. We have used psoralen-modified triplex-forming oligonucleotides (TFOs) to direct a psoralen-DNA interstrand cross-link (ICL) to a specific site to determine the effect of HMGB proteins on recognition of these lesions. Our results reveal that human HMGB1 (but not HMGB2) binds with high affinity and specificity to psoralen ICLs, and interacts with the essential NER protein, replication protein A (RPA), at these lesions. RPA, shown previously to bind tightly to these lesions, also binds in the presence of HMGB1, without displacing HMGB1. A discrete ternary complex is formed, containing HMGB1, RPA, and psoralen-damaged DNA. Thus, HMGB1 has the ability to recognize ICLs, can cooperate with RPA in doing so, and likely modulates their repair by the NER machinery. The abundance of HMGB1 suggests that it may play an important role in determining the sensitivity of cells to DNA damage under physiological, experimental, and therapeutic conditions.