Nature of full-length HMGB1 binding to cisplatin-modified DNA

HMGB1, a highly conserved non-histone DNA-binding protein, interacts with specific DNA structural motifs such as those encountered at cisplatin damage, four-way junctions, and supercoils. The interaction of full-length HMGB1, containing two tandem HMG box domains and a C-terminal acidic tail, with cisplatin-modified DNA was investigated by hydroxyl radical footprinting and electrophoretic gel mobility shift assays. The full-length HMGB1 protein binds to DNA containing a 1,2-intrastrand d(GpG) cross-link mainly through domain A, as revealed by footprinting, with a dissociation constant K(d) of 120 nM. Site-directed mutagenesis of intercalating residues in both HMG domains A and B in full-length HMGB1 further supports the conclusion that only one HMG box domain is bound to the site of cisplatin damage. Interaction of the C-terminal tail with the rest of the HMGB1 protein was examined by EDC cross-linking experiments. The acidic tail mainly interacts with domain B and linker regions rather than domain A in HMGB1. These results illuminate the respective roles of the tandem HMG boxes and the C-terminal acidic tail of HMGB1 in binding to DNA and to the major DNA adducts formed by the anticancer drug cisplatin.     

Rice HMGB1 protein recognizes DNA structures and bends DNA efficiently

We analyzed the DNA-binding and DNA-bending properties of recombinant HMGB1 proteins based on a rice HMGB1 cDNA. Electrophoretic mobility shift assay demonstrated that rice HMGB1 can bind synthetic four-way junction (4H) DNA and DNA minicircles efficiently but the binding to 4H can be completed out by HMGA and histone H1. Conformational changes were detected by circular dichroism analysis with 4H DNA bound to various concentrations of HMGB1 or its truncated forms. T4 ligase-mediated circularization assays with short DNA fragments of 123 bp showed that the protein is capable of increasing DNA flexibility. The 123-bp DNA formed closed circular monomers efficiently in its presence, similar to that in an earlier study on maize HMG. Additionally, our results show for the first time that the basic N-terminal domain enhances the affinity of the plant HMGB1 protein for 4H DNA, while the acidic C-terminal domain has the converse effects.     

Tail-Mediated Collapse of HMGB1 Is Dynamic and Occurs via Differential Binding of the Acidic Tail to the A and B Domains

The architectural DNA-binding protein HMGB1 consists of two tandem HMG-box domains joined by a basic linker to a C-terminal acidic tail, which negatively regulates HMGB1-DNA interactions by binding intramolecularly to the DNA-binding faces of both basic HMG boxes. Here we demonstrate, using NMR chemical-shift mapping at different salt concentrations, that the tail has a higher affinity for the B box and that A box-tail interactions are preferentially disrupted. Previously, we proposed a model in which the boxes are brought together in a collapsed, tail-mediated assembly, which is in dynamic equilibrium with a more extended form. Small-angle X-ray scattering data are consistent with such a dynamic equilibrium between collapsed and extended structures and are best represented by an ensemble. The ensembles contain a significantly higher proportion of collapsed structures when the tail is present. ¹⁵N NMR relaxation measurements show that full-length HMGB1 has a significantly lower rate of rotational diffusion than the tail-less protein, consistent with the loss of independent domain motions in an assembled complex. Mapping studies using the paramagnetic spin label MTSL [(1-oxyl-2,2,5,5-tetramethyl-3-pyrrolidin-3-yl)methyl methanethiosulfonate] placed at three locations in the tail confirm our previous findings that the tail binds to both boxes with some degree of specificity. The end of the tail lies further from the body of the protein and is therefore potentially free to interact with other proteins. MTSL labelling at a single site in the A domain (C44) causes detectable relaxation enhancements of B domain residues, suggesting the existence of a “sandwich”-like collapsed structure in which the tail enables the close approach of the basic domains. These intramolecular interactions are presumably important for the dynamic association of HMGB1 with chromatin and provide a mechanism by which protein-protein interactions or posttranslational modifications might regulate the function of the protein at particular sites, or at particular stages in the cell cycle.     

Visualization of DNA complexes with HMGB1 and its C-truncated form HMGB1(A+B)

Circular dichroism and scanning probe microscopy were used to characterize the interaction of DNA with the nonhistone chromatin protein HMGB1 and its recombinant version HMGB1(A+B) devoid of the C-terminal acidic region. The AFM data corroborate the earlier suggestion concerning the action of tandem DNA-binding domains, and support a modulatory role of the C-terminal domain in HMG protein-DNA interactions.     

Interaction between domains in chromosomal protein HMG-1.

Peptides corresponding to the N-terminal, central and central plus C-terminal domains of high mobility group protein HMG-1 from calf thymus have been isolated after digestion in solution with protease V8 under structuring conditions (0.35 M NaCl, pH 7.1). The effect of the interaction of these peptides with DNA on the topological properties of the nucleic acid has been studied and compared with the change in superhelicity produced by the whole protein. It appears that the region responsible for this effect is the central domain of HMG-1. The isolated N-terminal and central domains of this protein maintain their secondary and tertiary structure as observed by spectroscopic techniques. However, when the central domain is covalently linked only to the acidic C-terminal part of the molecule, its secondary and tertiary structures are lost as well as its property to alter DNA superhelicity. The results are discussed in relation to the interactions occurring between the different domains and the possible functional interactions of this protein.     

The interaction of HMGB1 and linker histones occurs through their acidic and basic tails

H1 and HMGB1 bind to linker DNA in chromatin, in the vicinity of the nucleosome dyad. They appear to have opposing effects on the nucleosome, H1 stabilising it by "sealing" two turns of DNA around the octamer, and HMGB1 destabilising it, probably by bending the adjacent DNA. Their presence in chromatin might be mutually exclusive. Displacement/replacement of one by the other as a result of their highly dynamic binding in vivo might, in principle, involve interactions between them. Chemical cross-linking and gel-filtration show that a 1:1 linker histone/HMGB1 complex is formed, which persists at physiological ionic strength, and that complex formation requires the acidic tail of HMGB1. NMR spectroscopy shows that the linker histone binds, predominantly through its basic C-terminal domain, to the acidic tail of HMGB1, thereby disrupting the interaction of the tail with the DNA-binding faces of the HMG boxes. A potential consequence of this interaction is enhanced DNA binding by HMGB1, and concomitantly lowered affinity of H1 for DNA. In a chromatin context, this might facilitate displacement of H1 by HMGB1.     

Protein kinase CK2 differentially phosphorylates maize chromosomal high mobility group B (HMGB) proteins modulating their stability and DNA interactions.

The high mobility group (HMG) proteins of the HMGB family are architectural factors in eukaryotic chromatin, which are involved in the regulation of various DNA-dependent processes. We have examined the post-translational modifications of five HMGB proteins from maize suspension cultured cells, revealing that HMGB1 and HMGB2/3, but not HMGB4 and HMGB5, are phosphorylated by protein kinase CK2. The phosphorylation sites have been mapped to the acidic C-terminal domains by analysis of tryptic peptides derived from HMGB1 and HMGB2/3 using nanospray ion trap mass spectrometry. In native HMGB1, Ser(149) is constitutively phosphorylated, whereas Ser(133) and Ser(136) are differentially phosphorylated. The functional significance of the CK2-mediated phosphorylation of HMGB proteins was analyzed by circular dichroism measurements showing that the phosphorylation increases the thermal stability of the HMGB proteins. Electrophoretic mobility shift assays demonstrate that the phosphorylation reduces the affinity of the HMGB proteins for linear DNA. The specific recognition of DNA minicircles is not affected by the phosphorylation, but a different pattern of protein-DNA complexes is formed. Collectively, these findings show that phosphorylation of residues within the acidic C-terminal domain of the HMGB proteins can modulate protein stability and the DNA binding properties of the HMGB proteins.     

Human and mouse LSP1 genes code for highly conserved phosphoproteins

With use of the mouse LSP1 cDNA we isolated a human homologue of the mouse LSP1 gene from a human CTL cDNA library. The predicted protein sequence of human LSP1 is compared with the predicted mouse LSP1 protein sequence and regions of homology are identified in order to predict structural features of the LSP1 protein that might be important for its function. Both the human and mouse LSP1 proteins consist of two domains, an N-terminal acidic domain and a C-terminal basic domain. The C-terminal domains of the mouse and human LSP1 proteins are highly conserved and include several conserved, putative serine/threonine phosphorylation sites. Immunoprecipitation of LSP1 protein from 32P-orthophosphate-loaded cells show that both the mouse and human LSP1 proteins are phosphoproteins. The sequences of the putative Ca2(+)-binding sites present in the N-terminal domain of the mouse LSP1 protein are not conserved in the human LSP1 protein; however, a different Ca2(+)-binding site may exist in the human protein, indicating a functional conservation rather than a strict sequence conservation of the two proteins. The expression of the human LSP1 gene follows the same pattern as the expression of the mouse LSP1 gene. Southern analysis of human genomic DNA shows multiple LSP1-related fragments of varying intensity in contrast to the simple pattern found after similar analysis of mouse genomic DNA. By using different parts of the human LSP1 cDNA as a probe, we show that most of these multiple bands contain sequences homologous to the conserved C-terminal region of the LSP1 cDNA. This suggests that there are several LSP1-related genes present in the human genome.     

LAST motifs and SMART domains in gene 32 protein: an unfolding story of autoregulation?

Bacteriophage T4 gene 32 protein is a classical single strand-specific DNA binding protein. It is a single polypeptide chain of 301 amino acid residues that consists of three structural domains, each of which has a binding function. The N-terminal domain is involved in homotypic protein-protein interaction (the basis of binding cooperativity), the core domain binds single strands directly, and the C-terminal domain has a role in heterotypic protein-protein association. The three domains have traditionally been thought to be independent of each other. However, the observation of a striking repetition of a basic, polar sequence (the "LAST" Motif), seen in both the N-terminal and core domains, suggests a linkage between these domains. Moreover, the C-domain and adjoining portion (flap) of the core are highly acidic, and are potential mimics of single-stranded DNA. With these observations, I construct a model in which this flap is associated with the ssDNA binding site in the absence of DNA, and upon cooperative protein binding to DNA, the flap now associates with the N-terminal domain of the adjacent DNA-bound protein. The flap thus acts as a gate, which might slow the binding of the protein to DNA. This could lead to the regulation of the protein's various interactions with other proteins, as well as affect its ability to lower DNA melting temperature.     

A zyxin head-tail interaction regulates zyxin-VASP complex formation

Zyxin is an adhesion protein that regulates actin assembly by binding to VASP family members through N-terminal proline-rich motifs. Evidence suggests that zyxin’s C-terminal LIM domains function as a negative regulator of zyxin-VASP complexes. Zyxin LIM domains access to binding partners is negatively regulated by an unknown mechanism. One possibility is that zyxin LIM domains mediate a head-tail interaction, blocking interactions with other proteins. Such a mechanism might prevent both zyxin-VASP complexes activity and LIM domain access. In this report, the effect of LIM domains on zyxin-VASP complex assembly is defined. We find that zyxin LIM domains associate with zyxin’s VASP binding sites, preventing zyxin from binding to PKA-phosphorylated VASP. Unphosphorylated VASP overcomes the head-tail interaction, a result of a direct interaction with the LIM domain region. Zyxin, like a growing number of actin regulators, is controlled by intramolecular interactions.     

The long acidic tail of high mobility group box 1 (HMGB1) protein forms an extended and flexible structure that interacts with specific residues within and between the HMG boxes

HMGB1 (high mobility group B1) is a conserved chromosomal protein composed of two similar DNA binding domains (HMG box A and box B) linked by a short basic stretch to an acidic C-terminal tail of 30 residues. The acidic tail modulates the DNA binding properties of HMGB1, and its length differentiates the various HMGB family members. We synthesized a peptide that corresponds to the acidic tail in HMGB1 (T-peptide) and studied its binding to the single boxes and to the fragment corresponding to tailless HMGB1 (designated as AB(bt) fragment). CD spectroscopy showed that T-peptide stabilizes significantly the AB(bt) fragment and that the complex has an identical thermal stability as full-length HMGB1. Calorimetric and NMR data showed that T-peptide binds with a dissociation constant of 9 microM to box A and much more weakly to box B. (1)H-(15)N HSQC spectra of full-length HMGB1 and of the AB(bt) fragment are very similar; the small chemical shift differences that exist correspond to those residues of the AB(bt) fragment that were affected by the addition of the T-peptide. We conclude that the T-peptide mimics closely the acidic tail and that the basic stretch and the acidic tail form an extended and flexible segment. The tail interacts with specific residues in the boxes and shields them from other interactions.     

Structural organization of DNA complexes with proteins HMGB1 and HMGB1-(A+B)

The interaction between DNA and the nonhistone proteins HMGB1 and HMGB1-(A+B) has been studied using circular dichroism and scanning force microscopy. The recombinant protein HMGB1-(A+B) has no negatively charged C-terminal domain characteristic for HMGB1. Our earlier suggestion about the structural interaction of tandem HMGB1-domains of the recombinant protein with DNA was confirmed. It was shown that the C-terminal part modulates the interactions of HMGB1-domains with DNA. Without the C-terminal sequence, the HMGB1-(A+B) protein forms DNA-protein complexes with the ordered supramolecular structure.