Structure of the HMG box motif in the B-domain of HMG1.

The conserved, abundant chromosomal protein HMG1 consists of two highly homologous, folded, basic DNA-binding domains, each of approximately 80 amino acid residues, and an acidic C-terminal tail. Each folded domain represents an 'HMG box', a sequence motif recently recognized in certain sequence-specific DNA-binding proteins and which also occurs in abundant HMG1-like proteins that bind to DNA without sequence specificity. The HMG box is defined by a set of highly conserved residues (most distinctively aromatic and basic) and appears to define a novel DNA-binding structural motif. We have expressed the HMG box region of the B-domain of rat HMG1 (residues 88-164 of the intact protein) in Escherichia coli and we describe here the determination of its structure by 2D 1H-NMR spectroscopy. There are three alpha-helices (residues 13-29, 34-48 and 50-74), which together account for approximately 75% of the total residues and contain many of the conserved basic and aromatic residues. Strikingly, the molecule is L-shaped, the angle of approximately 80 degrees between the two arms being defined by a cluster of conserved, predominantly aromatic, residues. The distinctive shape of the HMG box motif, which is distinct from hitherto characterized DNA-binding motifs, may be significant in relation to its recognition of four-way DNA junctions.     

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.     

Insect proteins homologous to mammalian high mobility group protein 1. Characterization and DNA-binding properties.

Two chromosomal high mobility group (HMG) proteins from larvae of Chironomus thummi (Diptera) and from an epithelial cell line of Chironomus tentans were purified to homogeneity and chemically characterized. cDNA clones encoding these proteins were isolated from an expression library using an immunoscreening approach and were sequenced. The deduced amino acid sequences revealed their homology to HMG protein 1 of vertebrates. These insect proteins have therefore been designated cHMG1a and cHMG1b. They have a molecular mass of 12,915 and 12,019 kDa, respectively, and preferentially bind to AT-rich DNA. Indirect immunofluorescence microscopy with a polyclonal antibody showed the presence of cHMG1a and cHMG1b in condensed chromomeres but not in puffs, nucleoli, and cytoplasm. The cHMG1a and cHMG1b genes were both localized to a single band in region 14 of chromosome 1 of C. tentans and appear to be single copy genes. An immunologically related protein was purified from Drosophila melanogaster Kc cells. Its size and amino acid composition indicate that it is an HMG1 of D. melanogaster. On the other hand, our antibody did not recognize calf HMG1. The identification and characterization of HMG1 proteins in insects with polytene chromosomes opens new possibilities for studying function(s) of this group of chromosomal proteins.     

Purification and cDNA cloning of maize HMGd reveal a novel plant chromosomal HMG-box protein with sequence similarity to HMGa

We have purified the chromosomal high mobility group (HMG) protein HMGd from maize suspension culture cells, determined the N-terminal amino acid (aa) sequence, and isolated the corresponding cDNA. Sequence analysis showed that the cDNA encoded a protein of 126 aa residues with a theoretical mass of 14 104 Da. The protein contains an HMG-box DNA-binding domain and a short acidic C-terminal tail. HMGd is in approx. 65% of its residues identical to maize HMGa, whereas it is only approx. 46% identical to maize HMGcl/2. The differences to the previously reported HMG proteins in aa sequence, in overall charge and in protein size indicate that we have identified a third type of plant chromosomal HMG-box protein belonging to the HMG1 protein family. Immunoblot analysis with a HMGd antiserum reveals that HMGd is expressed in all tissues tested.     

The HMG1 ta(i)le

We have studied structural changes in DNA/protein complexes using the CD spectroscopy, upon the interaction of HMG1-domains with calf thymus DNA at different ionic strengths. HMG1 protein isolated from calf thymus and recombinant HMG1-(A+B) protein were used. Recombinant protein HMG1-(A+B) represents a rat HMG1 lacking C-terminal acidic tail. At low ionic strength (15 mM NaCl) we observed similar behavior of both proteins upon interaction with DNA. Despite this, at higher ionic strength (150 mM NaCl) their interaction with DNA leads to a completely different structure of the complexes. In the case of HMG1-(A+B)/DNA complexes we observed the appearance of DNA fractions possessing very high optical activity. This could be a result of formation of the highly-ordered DNA structures modulated by the interaction with HMG1-domains. Thus the comparison studies of HMG1 and HMG1-(A+B) interaction with DNA show that negatively charged C-terminal tail of HMG1 modulates interaction of the protein with DNA. The striking difference of the behaviour of these two systems allows us to explain the functional role of multiple HMG1 domains in some regulatory and architectural proteins.     

Mapping intramolecular interactions between domains in HMGB1 using a tail-truncation approach

The mechanism underlying negative regulation of HMGB1-DNA interaction by the acidic C-terminal tail is ill defined. To address this issue, we have devised a novel NMR chemical-shift perturbation mapping strategy to elucidate interactions between the tail, which consists solely of aspartic acid and glutamic acid residues, and the two well characterized HMG-box DNA-binding domains. A series of HMGB1 tail-truncation mutants differing from each other by five residues was generated. Chemical-shift perturbation mapping using these mutants shows that tails of different lengths bind with different affinities. Nevertheless, the truncated tails bind along the same path on the HMG boxes as the full-length tail, differences in length being manifested in differences in the “reach”. The tail makes extensive contacts with the DNA-binding surfaces of both HMG boxes, thus explaining the basis of negative regulation of HMGB1–DNA interaction by the tail.     

Interactions of the basic N-terminal and the acidic C-terminal domains of the maize chromosomal HMGB1 protein

Maize HMGB1 is a typical member of the family of plant chromosomal HMGB proteins, which have a central high-mobility group (HMG)-box DNA-binding domain that is flanked by a basic N-terminal region and a highly acidic C-terminal domain. The basic N-terminal domain positively influences various DNA interactions of the protein, while the acidic C-terminal domain has the opposite effect. Using DNA-cellulose binding and electrophoretic mobility shift assays, we demonstrate that the N-terminal basic domain binds DNA by itself, consistent with its positive effects on the DNA interactions of HMGB1. To examine whether the negative effect of the acidic C-terminal domain is brought about by interactions with the basic part of HMGB1 (N-terminal region, HMG-box domain), intramolecular cross-linking in combination with formic acid cleavage of the protein was used. These experiments revealed that the acidic C-terminal domain interacts with the basic N-terminal domain. The intramolecular interaction between the two oppositely charged termini of the protein is enhanced when serine residues in the acidic tail of HMGB1 are phosphorylated by protein kinase CK2, which can explain the negative effect of the phosphorylation on certain DNA interactions. In line with that, covalent cross-linking of the two terminal domains resulted in a reduced affinity of HMGB1 for linear DNA. Comparable to the finding with maize HMGB1, the basic N-terminal and the acidic C-terminal domains of the Arabidopsis HMGB1 and HMGB4 proteins interact, indicating that these intramolecular interactions, which can modulate HMGB protein function, generally occur in plant HMGB proteins.     

Structural requirements for cooperative binding of HMG1 to DNA minicircles

DNA minicircles, where the length of DNA is below the persistence length, are highly effective, preferred, ligands for HMG-box proteins. The proteins bind to them "structure-specifically" with affinities in the nanomolar range, presumably to an exposed widened minor groove. To understand better the basis of this preference, we have studied the binding of HMG1 (which has two tandem HMG boxes linked by a basic extension to a long acidic tail) and Drosophila HMG-D (one HMG box linked by a basic region to a short and less acidic tail), and their HMG-box domains, to 88 bp and 75 bp DNA minicircles. In some cases we see cooperative binding of two molecules to the circles. The requirements for strong cooperativity are two HMG boxes and the basic extension; the latter also appears to stabilize and constrain the complex, preventing binding of further protein molecules. HMG-D, with a single HMG box, does not bind cooperatively. In the case of HMG1, the acidic tail is not required for cooperativity and does not affect binding significantly, in contrast to a much greater effect with linear DNA, or even four-way junctions (another distorted DNA substrate). Such effects could be relevant in the hierarchy of binding of HMG-box proteins to DNA distortions in vivo, where both single-box and two-box proteins might co-exist, with or without basic extensions and acidic tails.     

Utilization of a novel recombinant myoglobin fusion protein expression system to characterize the tissue inhibitor of metalloproteinase (TIMP)-4 and TIMP-2 C-terminal domain and tails by mutagenesis. The importance of acidic residues in binding the MMP-2 hemopexin C-domain

Tissue inhibitor of metalloproteinase (TIMP)-4 binds pro-matrix metalloproteinase (MMP)-2 and efficiently inhibits MT1-MMP, but unlike TIMP-2 neither forms a trimolecular complex nor supports pro-MMP-2 activation. To investigate the structural and functional differences between these two TIMPs, the C-terminal domains (C-TIMP-4 and C-TIMP-2) were expressed independently from their N domains and mutations were introduced into the C-terminal tails. Myoglobin was used as a novel recombinant fusion protein partner because spectroscopic measurement of the heme Soret absorbance at 408 nm readily enabled calculation of the molar equivalent of the red-colored recombinant protein, even in complex protein mixtures. Both C-TIMP-4 and C-TIMP-2 bound pro-MMP-2 and blocked concanavalin A-induced cellular activation of the enzyme. Measurement of k(on) rates revealed that the inhibition of MMP-2 by TIMP-4 is preceded by a C domain docking interaction, but in contrast to TIMP-2, this is not enhanced by a C-terminal tail interaction and so occurs at a slower rate. Indeed, the binding stability of C-TIMP-4 was unaltered by deletion of the C-terminal tail, but replacement with the tail of TIMP-2 increased its affinity for pro-MMP-2 by approximately 2-fold, as did substitution with the TIMP-2 C-terminal tail acidic residues in the tail of C-TIMP-4 (V193E/Q194D). Conversely, substitution of the C-terminal tail of C-TIMP-2 with that of TIMP-4 reduced pro-MMP-2 binding by approximately 75%, as did reduction of its acidic character by mutation to the corresponding TIMP-4 amino acid residues (E192V/D193Q). Together, this shows the importance of Glu(192) and Asp(193) in TIMP-2 binding to pro-MMP-2; the lack of these acidic residues in the TIMP-4 C-terminal tail, which reduces the stability of complex formation with the MMP-2 hemopexin C domain, probably precludes TIMP-4 from supporting the activation of pro-MMP-2.     

Structural Insights into the Mechanism of Negative Regulation of Single-box High Mobility Group Proteins by the Acidic Tail Domain

The Drosophila and plant (maize) functional counterparts of the abundant vertebrate chromosomal protein HMGB1 (HMG-D and ZmHMGB1, respectively) differ from HMGB1 in having a single HMG box, as well as basic and acidic flanking regions that vary greatly in length and charge. We show that despite these variations, HMG-D and ZmHMGB1 exist in dynamic assemblies in which the basic HMG boxes and linkers associate with their intrinsically disordered, predominantly acidic, tails in a manner analogous to that observed previously for HMGB1. The DNA-binding surfaces of the boxes and linkers are occluded in “auto-inhibited” forms of the protein, which are in equilibrium with transient, more open structures that are “binding-competent.” This strongly suggests that the mechanism of auto-inhibition may be a general one. HMG-D and ZmHMGB1 differ from HMGB1 in having phosphorylation sites in their tail and linker regions. In both cases, in vitro phosphorylation of serine residues within the acidic tail stabilizes the assembled form, suggesting another level of regulation for interaction with DNA, chromatin, and other proteins that is not possible for the uniformly acidic (hence unphosphorylatable) tail of HMGB1.     

Human lymphocyte-specific protein 1, the protein overexpressed in neutrophil actin dysfunction with 47-kDa and 89-kDa protein abnormalities (NAD 47/89), has multiple F-actin binding domains

Human lymphocyte-specific protein 1 (LSP1) is an F-actin binding protein, which has an acidic N-terminal half and a basic C-terminal half. In the basic C-terminal half, there are amino acid sequences highly homologous to the actin-binding domains of two known F-actin binding proteins: caldesmon and the villin headpieces (CI, CII, VI, VII). However, the exact numbers and locations of the F-actin binding domains within LSP1 are not clearly defined. In this report, we utilized 125I-labeled F-actin ligand blotting and high-speed F-actin cosedimentation assays to analyze the F-actin binding properties of truncated LSP1 peptides and to define the F-actin binding domains. Results show that LSP1 has at least three and potentially a fourth F-actin binding domain. All F-actin binding domains are located in the basic C-terminal half and correspond to the caldesmon and villin headpiece homologous regions. LSP1 181-245 and LSP1 246-295, containing sequences homologous to caldesmon F-actin binding site I and II, respectively (CI, CII), binds F-actin; similarly, LSP1 306-339 can bind F-actin and contains two inseparable villin headpiece-like F-actin binding domains (VI, VII). Although LSP1 1-305, which does not contain VI and VII regions, retains F-actin binding activity, its binding affinity for F-actin is much weaker than that of full-length LSP1. Site-directed mutagenesis of the basic amino acids in the KRYK (VI) or KYEK (VII) sequences to acidic amino acids create mutants that bind F-actin with lower affinity than full-length wild-type LSP1. High KCl concentrations decrease full-length LSP1 binding to F-actin, suggesting the affinity between LSP1 and F-actin is mainly through electrostatic interaction.     

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.     

Distinct roles of the N-terminal-binding domain and the C-terminal-solubilizing domain of alpha-synuclein,a molecular chaperone

alpha-Synuclein, an acidic neuronal protein of 140 amino acids, is extremely heat-resistant and is natively unfolded. Recent studies have demonstrated that alpha-synuclein has chaperone activity both in vitro and in vivo, and that this activity is lost upon removing its C-terminal acidic tail. However, the detailed mechanism of the chaperone action of alpha-synuclein remains unknown. In this study, we investigated the molecular mechanism of the chaperone action of alpha-synuclein by analyzing the roles of its N-terminal and C-terminal domains. The N-terminal domain (residues 1-95) was found to bind to substrate proteins to form high molecular weight complexes, whereas the C-terminal acidic tail (residues 96-140) appears to be primarily involved in solubilizing the high molecular weight complexes. Because the substrate-binding domain and the solubilizing domain for chaperone function are well separated in alpha-synuclein, the N-terminal-binding domain can be substituted by other proteins or peptides. Interestingly, the resultant engineered chaperone proteins appeared to display differential efficiency and specificity in terms of the chaperone function, which depended upon the nature of the binding domain. This finding implies that the C-terminal acidic tail of alpha-synuclein can be fused with other proteins or peptides to engineer synthetic chaperones for specific purposes.     

DNA looping by the HMG-box domains of HMG1 and modulation of DNA binding by the acidic C-terminal domain.

We have compared HMG1 with the product of tryptic removal of its acidic C-terminal domain termed HMG3, which contains two 'HMG-box' DNA-binding domains. (i) HMG3 has a higher affinity for DNA than HMG1. (ii) Both HMG1 and HMG3 supercoil circular DNA in the presence of topoisomerase I. Supercoiling by HMG3 is the same at approximately 50 mM and approximately 150 mM ionic strength, as is its affinity for DNA, whereas supercoiling by HMG1 is less at 150 mM than at 50 mM ionic strength although its affinity for DNA is unchanged, showing that the acidic C-terminal tail represses supercoiling at the higher ionic strength. (iii) Electron microscopy shows that HMG3 at a low protein:DNA input ratio (1:1 w/w; r = 1), and HMG1 at a 6-fold higher ratio, cause looping of relaxed circular DNA at 150 mM ionic strength. Oligomeric protein 'beads' are apparent at the bases of the loops and at cross-overs of DNA duplexes. (iv) HMG3 at high input ratios (r = 6), but not HMG1, causes DNA compaction without distortion of the B-form. The two HMG-box domains of HMG1 are thus capable of manipulating DNA by looping, compaction and changes in topology. The acidic C-tail down-regulates these effects by modulation of the DNA-binding properties.     

Degrons at the C terminus of the pathogenic but not the nonpathogenic hantavirus G1 tail direct proteasomal degradation

Pathogenic hantaviruses cause two human diseases: hantavirus pulmonary syndrome (HPS) and hemorrhagic fever with renal syndrome (HFRS). The hantavirus G1 protein contains a long, 142-amino-acid cytoplasmic tail, which in NY-1 virus (NY-1V) is ubiquitinated and proteasomally degraded (E. Geimonen, I. Fernandez, I. N. Gavrilovskaya, and E. R. Mackow, J. Virol. 77: 10760-10768, 2003). Here we report that the G1 cytoplasmic tails of pathogenic Andes (HPS) and Hantaan (HFRS) viruses are also degraded by the proteasome and that, in contrast, the G1 tail of nonpathogenic Prospect Hill virus (PHV) is stable and not proteasomally degraded. We determined that the signals which direct NY-1V G1 tail degradation are present in a hydrophobic region within the C-terminal 30 residues of the protein. In contrast to that of PHV, the NY-1V hydrophobic domain directs the proteasomal degradation of green fluorescent protein and constitutes an autonomous degradation signal, or "degron," within the NY-1V G1 tail. Replacing 4 noncontiguous residues of the NY-1V G1 tail with residues present in the stable PHV G1 tail resulted in a NY-1V G1 tail that was not degraded by the proteasome. In contrast, changing a different but overlapping set of 4 PHV residues to corresponding NY-1V residues directed proteasomal degradation of the PHV G1 tail. The G1 tails of pathogenic, but not nonpathogenic, hantaviruses contain intervening hydrophilic residues within the C-terminal hydrophobic domain, and amino acid substitutions that alter the stability or degradation of NY-1V or PHV G1 tails result from removing or adding intervening hydrophilic residues. Our results identify residues that selectively direct the proteasomal degradation of pathogenic hantavirus G1 tails. Although a role for the proteasomal degradation of the G1 tail in HPS or HFRS is unclear, these findings link G1 tail degradation to viral pathogenesis and suggest that degrons within hantavirus G1 tails are potential virulence determinants.     

Constitutive phosphorylation of the acidic tails of the high mobility group 1 proteins by casein kinase II alters their conformation, stability, and DNA binding specificity.

The high mobility group (HMG) 1 and 2 proteins are the most abundant non-histone components of chromosomes. Here, we report that essentially the entire pool of HMG1 proteins in Drosophila embryos and Chironomus cultured cells is phosphorylated at multiple serine residues located within acidic tails of these proteins. The phosphorylation sites match the consensus phosphorylation site of casein kinase II. Electrospray ionization mass spectroscopic analyses revealed that Drosophila HMGD and Chironomus HMG1a and HMG1b are double-phosphorylated and that Drosophila HMGZ is triple-phosphorylated. The importance of this post-translational modification was studied by comparing some properties of the native and in vitro dephosphorylated proteins. It was found that dephosphorylation affects the conformation of the proteins and decreases their conformational and metabolic stability. Moreover, it weakens binding of the proteins to four-way junction DNA by 2 orders of magnitude, whereas the strength of binding to linear DNA remains unchanged. Based on these observations, we propose that the detected phosphorylation is important for the proper function and turnover rates of these proteins. As the occurrence of acidic tails containing canonical casein kinase II phosphorylation sites is common to diverse HMG and other chromosomal proteins, our results are probably of general significance.     

A novel, highly phosphorylated protein, of the high-mobility group type, present in a variety of proliferating and non-proliferating mammalian cells

The present work describes a perchloric-acid-soluble high-mobility-group (HMG)-like protein present in HeLa and Ehrlich ascites cells, rat and calf liver. The protein is designated P1 and has, depending on the source, a molecular mass 48-53 kDa and an amino acid composition which, like the HMG proteins, is characterized by a high content of acidic and basic residues and of proline. The protein contains about 10 mol serine/100 mol amino acid residues, is highly phosphorylated and has, in contrast to the known HMG proteins, an acidic isoelectric point of 5.0. An estimate suggests that protein P1 in HeLa interphase cells contains 25-30 residues of phosphate. Like HMG 1 and 2 it is distributed between the nucleus and the cytoplasm. In HeLa metaphase cells P1 is further modified, resulting in an increase in apparent molecular mass from 53 kDa to 56 kDa.     

The effect of the acidic tail on the DNA-binding properties of the HMG1,2 class of proteins: insights from tail switching and tail removal

The high-mobility group (HMG) proteins HMG1, HMG2 and HMG2a are relatively abundant vertebrate DNA-binding and bending proteins that bind with structure specificity, rather than sequence specificity, and appear to play an architectural role in the assembly of nucleoprotein complexes. They have two homologous "HMG-box" DNA-binding domains (which show about 80 % homology) connected by a short basic linker to an acidic carboxy-terminal tail that differs in length between HMG1 and 2. To gain insights into the role of the acidic tail, we examined the DNA-binding properties of HMG1, HMG2b and HMG2a from chicken erythrocytes (corresponding to HMG1, HMG2 and HMG2a in other vertebrates). HMG1, with the longest acidic tail, is less effective than HMG2a and 2b (at a given molar input ratio) in supercoiling relaxed, closed circular DNA, in inducing ligase-mediated circularisation of an 88 bp DNA fragment, and in binding to four-way DNA junctions in a gel-shift assay. Removal of the acidic tail increases the affinity of the HMG boxes for DNA and largely abolishes the differences between the three species. Switching the acidic tail of HMG1 for that of HMG2a or 2b gives hybrid proteins with essentially the same DNA-binding properties as HMG2a, 2b. The length (and possibly sequence) of the acidic tail thus appears to be the dominant factor in mediating the differences in properties between HMG1, 2a and 2b and finely tunes the rather similar DNA-binding properties of the tandem HMG boxes, presumably to fulfill different cellular roles. The tail is essential for structure-selective DNA-binding of the HMG boxes to DNA minicircles in the presence of equimolar linear DNA, and has little effect on the affinity for this already highly distorted DNA ligand, in contrast to binding to linear and four-way junction DNA.