Binding of high-mobility-group proteins HMG 14 and HMG 17 to DNA and histone H1 as influenced by phosphorylation

We have used affinity chromatography to study the effects of phosphorylation of calf thymus high-mobility-group proteins HMG 14 and HMG 17 on their binding properties towards calf thymus single- and double-stranded DNA and histone H1. Without in vitro phosphorylation, HMG 14 and HMG17 eluted from doble-stranded DNA-columns at 200 mM NaCl. HMG 14 was released from single-stranded DNA-column at 300 mM NaCl and from H1-column at 130 mM NaCl, whereas the corresponding values for HMG 17 were 230 mM and 20 mM, respectively. Phosphorylation of HMG 14 and HMG 17 by cAMP-dependent protein kinase (A-kinase) decreased markedly their affinity (270 mM and 200 mM NaCl, respectively) for single-stranded DNA, whereas HMG 14 phosphorylated by nuclear protein kinase II (NII-kinase) eluted only slightly (290 mM NaCl) ahead of the unphosphorylated protein. HMG 14 phosphorylated by both A-kinase and NII-kinase eluted from double-stranded DNA-columns almost identically (190 mM NaCl) with the unphosphorylated protein. Interestingly, phosphorylation of HMG 14 by NII-kinase increased considerably its affinity for histone H1 and the phosphorylated protein eluted at 200 mM NaCl. Phosphorylation of HMG 14 by A-kinase did not alter its interaction towards histone H1. These results indicate that modification of HMG 14 by phosphorylation at specific sites may have profound effects on its binding properties towards DNA and histone H1, and that HMG 17 has much weaker affinity for single-stranded DNA and histone H1 than HMG 14.     

The DNA binding site of HMG1 protein is composed of two similar segments (HMG boxes), both of which have counterparts in other eukaryotic regulatory proteins.

The mammalian nuclear protein HMG1 contains two segments that show a high sequence similarity to each other. Each of the segments, produced separately from the rest of the protein in Escherichia coli, binds to DNA with high specificity: four-way junction DNA of various sequences is bound efficiently, but linear duplex DNA is not. Both isolated segments exists as dimers in solution, as shown by gel filtration and chemical crosslinking experiments. HMG1-like proteins are present in yeast and in protozoa: they consist of a single repetition of a motif extremely similar to the DNA binding segments of HMG1, suggesting that they too might form dimers with structural specificity in DNA binding. Sequences with recognizable similarity to either of the two DNA binding segments of HMG1, called HMG boxes, also occur in a few eukaryotic regulatory proteins. However, these proteins are reported to bind to specific sequences, suggesting that the HMG box of proteins distantly related to HMG1 might differ significantly from the HMG box of HMG1-like proteins.     

Hexamine cobalt chloride promotes intermolecular ligation of blunt end DNA fragments by T4 DNA ligase.

Hexamine cobalt chloride (HCC) increases the efficiency of blunt end ligation by T4 DNA ligase about 50 fold. Maximum stimulation occurs when standard buffers for ligation are supplemented with 1 mM HCC. All the ligation events are intermolecular regardless of the initial DNA concentration. In the presence of monovalent cations (eg. 25 mM KCl) HCC still increases the extent of T4 catalyzed ligation but intramolecular ligation products are also formed. Therefore, intermolecular ligation can be performed rapidly and at low DNA concentrations.     

A one-step preparative method for separating SER 6-phosphorylated HMG 14 from unphosphorylated HMG 14 and in vitro phosphorylation reaction components

While clear evidence exists for the regulation of the phosphorylation of the very basic high mobility group (HMG) and histone chromatin proteins, the physiological role of their phosphorylation remains poorly understood. Elucidation of these roles has been difficult, in part, because of the inability to obtain sufficient quantities of purified phosphorylated derivatives. We have used Mono S cation-exchange chromatography to prepare milligram quantities of pure Ser 6-phosphorylated HMG 14 (Ser 6-PO4-HMG) from unphosphorylated Mono S-purified calf thymus HMG 14 following in vitro phosphorylation with cAMP-dependent protein kinase (A-kinase). In one step, this technique separates the phosphorylated derivative from A-kinase, ATP, unphosphorylated HMG 14, and a minor phosphorylated by-product which evidence suggests may be the previously reported Ser 6, 24-diphospho-HMG 14. Mono S chromatography also enhances the purity of calf thymus HMG 14 prepared by perchloric acid extraction, acetone and ethanol precipitations, and CM-Sephadex chromatography. In addition, it permits the detection of apparent microheterogenous forms of both unphosphorylated and Ser 6-PO4-HMG 14. The significant reductions in binding affinity resulting from the incorporation of phosphate groups into HMG 14 suggest that Mono S chromatography could have more general application in the isolation of phosphorylated derivatives of other basic proteins, including other chromatin-associated DNA-binding proteins which are known to undergo specific phosphorylation. It would especially be useful when the proteins and their phosphorylated derivatives bind more tightly to Mono S than the kinases used for their phosphorylation.     

Dual binding modes for an HMG domain from human HMGB2 on DNA

High mobility group B (HMGB) proteins contain two HMG box domains known to bind without sequence specificity into the DNA minor groove, slightly intercalating between basepairs and producing a strong bend in the DNA backbone. We use optical tweezers to measure the forces required to stretch single DNA molecules. Parameters describing DNA flexibility, including contour length and persistence length, are revealed. In the presence of nanomolar concentrations of isolated HMG box A from HMGB2, DNA shows a decrease in its persistence length, where the protein induces an average DNA bend angle of 114 +/- 21 degrees for 50 mM Na+, and 87 +/- 9 degrees for 100 mM Na+. The DNA contour length increases from 0.341 +/- 0.003 to 0.397 +/- 0.012 nm per basepair, independent of salt concentration. In 50 mM Na+, the protein does not unbind even at high DNA extension, whereas in 100 mM Na+, the protein appears to unbind only below concentrations of 2 nM. These observations support a flexible hinge model for noncooperative HMG binding at low protein concentrations. However, at higher protein concentrations, a cooperative filament mode is observed instead of the hinge binding. This mode may be uniquely characterized by this high-force optical tweezers experiment.     

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.     

DNA intercalators induce specific release of HMG 14, HMG 17 and other DNA-binding proteins from chicken erythrocyte chromatin.

Chicken erythrocyte nuclei were incubated with DNA intercalating agents in order to isolate from chromatin specific DNA-binding proteins whose binding specificity may be determined by DNA secondary and/or tertiary structure. The intercalating agents ethidium bromide (EtBr) and propidium iodide induce the specific release of high mobility group proteins HMG 14 and HMG 17 under low ionic strength conditions. Chloroquine (CQ) intercalation also results in the selective liberation of HMG 14 and HMG 17, but, in addition, selectively releases other nuclear proteins (including histone H1A) in a pH- and ionic strength-dependent fashion. The use of this new 'elutive intercalation' technique for the isolation and purification of 'sequence-specific' and 'helix-specific' DNA-binding proteins is suggested.     

Escherichia coli topoisomerase I can segregate replicating pBR322 daughter DNA molecules in vitro

The reconstituted pBR322 DNA replication system has been used to identify a mechanism for the processing and segregation of daughter DNA molecules by Escherichia coli topoisomerase I (Topo I) during the terminal stages of DNA replication. At low concentrations of Topo I (sufficient to confer specificity to the replication system for DNA templates containing a ColE1-type origin of DNA replication), the major products of the replication reaction were: multigenome-length, linear, double-stranded DNA molecules (an aberrant product); multiply interlinked, catenated, supercoiled DNA dimers; and a last Cairns-type replication intermediate. Thirty- to fifty-fold higher concentrations of Topo I led to the appearance of form II and form I pBR322 DNA as the only synthetic products. A model was developed in which Topo I, bound to a single-stranded gap on the parental H strand DNA just upstream of the origin of DNA replication, catalyzed the decatenation of the intermolecular linkages between the two daughter DNA molecules that were generated by primosome-catalyzed unwinding of the residual nonreplicated parental duplex DNA in the last Cairns-type intermediate. At low concentrations of Topo I, however, the intermolecular linkages persisted and, within the context of this replication system, were not removed by DNA gyrase. In support of this model it was demonstrated that: there was a single-stranded gap between the nonreplicated parental duplex region and the 5' end of the nascent leading-strand DNA; the number of intermolecular linkages in the catenated supercoiled DNA dimers was inversely related to the concentration of Topo I; the supercoiled DNA dimers did not serve as a precursor of the final form I DNA product; and maturation of the last Cairns-type replication intermediate to form I DNA was not affected by the presence of coumermycin, a potent inhibitor of the activities of DNA gyrase.     

Non-histone chromosomal protein HMG1 modulates the histone H1-induced condensation of DNA

Circular dichroic spectra revealed that the previously known regular, asymmetric condensation of DNA by H1 histone was modulated by HMG1, a nonhistone chromosomal protein. Under approximately physiological salt and pH conditions (150 mM NaCl, pH 7), ellipticities at 270 nm were observed as follows: DNA, 9 X 10(3) degree, cm2/dmol nucleotide; DNA X H1 histone complex (1:0.4, w/w), -37 X 10(3) degree, cm2/dmol nucleotide, and DNA X H1 X HMG1 complex (1:0.4:0.4 w/w/w), -52 X 10(3) degree, cm2/dmol. HMG1 by itself did not distort the spectrum of DNA, showing that the effect of HMG1 on the DNA X H1 complex was not simply the summation of individual effects of HMG1 and H1 on the DNA spectrum. The effect of added HMG1 on the spectrum of the preformed DNA X H1 complex depended on the amount of HMG1 added and developed slowly (a day) as if a structure required annealing. The ternary complex, DNA X HMG1 X 1, seemed to represent a specific structure, since its formation depeNded on the reduced sulfhydryl state of HMG1; the disulfide form of HMG1, which was shown by circular dichroism to contain more random coil than did the reduced form, had no effect on the circular dichroic spectrum of the DNA X H1 complex.     

Histone H1 and HMG 14/17 are deposited nonrandomly in the nucleus.

We have studied the assembly of histone H1 and the high mobility group nonhistones 14/17 by isopycnic analysis after crosslinking density labeled MSB cell nuclei or chromatin. Carbodiimide crosslinking produces dense poly-H1 and hybrid density H1-H2A histone dimers, indicating that new H1 is deposited nonrandomly, albeit nonconservatively relative to new core histones. Core histone-HMG crosslinking with succinimidyl propionate yields dense HMG 14 in uniformly dense particles and new HMG 17 crosslinked to both dense and light protein, implying that HMG 14 and 17 each deposit nonrandomly; but differently with respect to new core octamers. Propionimidate crosslinking yields dense H1-HMG 17 dimers, suggesting that the interactions of new 14/17 with H1 (new HMG 14-old H1, new HMG 17-new H1) are reciprocal to their interactions with the core histones.     

Interaction of HMG 14 and 17 with actively transcribed genes

The interaction of HMG 14 and 17 with actively transcribed genes was studied by monitoring the sensitivity of specific genes to DNAase I after reconstitution of HMG-depleted chromatin with HMG 14 and 17. Our experiments lead to the following conclusions: most actively transcribed genes become sensitized to DNAase I by HMG 14 and 17; either HMG 14 or HMG 17 can sensitize most genes to DNAase I; genes transcribed at different rates have about the same affinity for HMG 14 and 17; HMG 14 and 17 bind stoichiometrically to actively transcribed nucleosomes; and HMG 14 and 17 can restore DNAase I sensitivity to purified nucleosome core particles depleted of HMGs. This last observation suggests that during reconstitution, low levels of HMG 14 and 17 can associate with the active nucleosomes in the presence of a 10–20 fold excess of inactive nucleosomes. Consequently, we conclude that besides their association with HMGs, active nucleosomes also have at least one other unique feature that distinguishes them from bulk nucleosomes and insures proper HMG binding during reconstitution.     

Thermophilic HB8 DNA ligase: effects of polyethylene glycols and polyamines on blunt-end ligation of DNA

NB8 DNA ligase from an extract of Thermus thermophilus HB8 could catalyze blunt-end ligation in the presence of high concentration of polyethylene glycols (PEG) or in the presence of polyamines. In the presence of high molecular weight PEG 20,000, 6,000, or 1,000 (8-28%), the enzyme catalyzed blunt-end intermolecular joining to yield linear oligomers, but no circular DNA forms. But in the presence of low molecular PEG 400, 200 (8-80%), or the monomer, ethylene glycol (16-80%), the circular forms were also detected by intramolecular ligation. In the presence of polyamines, the blunt-end ligation products were linear oligomers and the optimum concentrations were as follows: caldopentamine (0.05 mM), thermine (0.1-0.2 mM), spermine (0.2 mM), thermospermine (0.4 mM), and sperminediol (0.75 mM). Spermidine and putrescine were less capable of producing oligomers. PEG and polyamines elevated the ligation temperature by HB8 DNA ligase. The optimum temperature of blunt-end ligation was about 65 degrees C.     

HMG17 protein facilitates the DNA catenation reaction catalyzed by DNA topoisomerases

HMG17 protein is shown to greatly facilitate the catention of double-stranded DNA rings catalyzed by DNA topoisomerases. Even at low DNA concentrations such that catenanes are not observable in the absence of HMG17, the addition of the protein promotes the catenation of greater than 95% of the input DNA into networks that do not enter the gel upon electrophoresis. Electron microscopy and restriction enzyme cleavage experiments indicate that these networks are large structures containing many catenated DNA rings. The HMG17-promoted DNA network formation has been observed with calf thymus type II DNA topoisomerase and the type I topoisomerases of Escherichia coli, Micrococcus luteus, and calf thymus.     

Differential binding of chromosomal proteins HMG1 and HMG2 to superhelical DNA

The binding of chromosomal proteins HMG1 and HMG2 to various DNA structures was examined by a nitrocellulose filter binding assay using a 32P labelled supercoiled plasmid. Binding assays and competition experiments indicated that HMG2 has a higher affinity than HMG1 for supercoiled DNA. Studies at various ionic strengths and pH values reveal differences in the interaction of the two proteins with DNA. The results suggest that HMG1 and HMG2 are involved in distinguishable cellular functions.     

Unwinding of DNA by nonhistone protein HMG1 and HMG2

The enzyme kinetic studies with endonucleases specific for single-stranded DNA and the thermal denaturation analyses of DNA showed that a high mobility group (HMG) nonhistone protein fraction HMG (1 + 2), composed of HMG1 and HMG2, has an activity to unwind DNA partially at low protein-to-DNA weight ratio. Isolated HMG1 and HMG2 have the same activity. Divalent cations such as Mg++ or Ca++ were necessary for the unwinding reaction. A peptide containing high glutamic and aspartic (HGA) region, isolated from the tryptic digest of HMG (1 + 2), unwound DNA depending on the presence of Mg++ or Ca++, suggesting that the HMA region in HMG protein is the active site for the DNA unwinding reaction. Poly-L-glutamic acid, employed as a model peptide of the HGA region, showed the activity. Finally, mechanisms of the DNA unwinding reaction by the HMG protein and possible role of the divalent cations are discussed.     

Persistence of chromosomal proteins HMG-14/-17 in myotubes following differentiation-dependent reduction of HMG mRNA.

The expression of chromosomal proteins HMG-14 and HMG-17 during cellular differentiation was studied in cultured mouse myoblasts. During myogenesis the level of both HMG-14 and HMG-17 mRNA decreased to less than 20% of that found in myoblasts. The down-regulation of HMG-14/-17 mRNA occurred simultaneously with activation of muscle-specific actin mRNA and was not linked to DNA synthesis, indicating that it is a differentiation-, rather than a cell cycle-related event. Incorporation of radiolabeled lysine into HMG proteins was similar to that into the major histone fractions in that it was significant in myoblasts and undetectable in myotubes. The decrease in mRNA and protein synthesis did not affect the cellular levels of HMG protein. These results indicate that the regulation of HMG-14/-17 mRNA levels is different from that of the histones and is linked to differentiation rather than to DNA synthesis.     

The in vitro reconstitution of nucleosome and its binding patterns with HMG1／2 and HMG14／17 proteins

Using atomic force microscopy (AFM), the dynamic process of the in vitro nucleosome reconstitution followed by slow dilution from high salt to low salt was visualized. Data showed that the histone octamers were dissociatedfrom DNA at 1M NaC1. When the salt concentration was slowly reduced to 650 mM and 300 mM, the core histones bound to the naked DNA gradually. Once the salt concentration was reduced to 50 mM the classic “beads-on-a-string“ structure was clearly visualized. Furthermore, using the technique of the in vitro reconstitution of nucleosome,the mono- and di- nucleosomes were assembled in vitro with both HS2core (-10681 to -10970 bp) and NCR2 (-372to -194 bp) DNA sequences in the 5‘flanking sequence of human b-globin gene. Data revealed that HMG 1/2 and HMG 14/17 proteins binding to both DNA sequences are changeable following the assembly and disassembly of nucleosomes. We suggest that the changeable binding patterns of HMG 14/17 and HMG1/2 proteins with these regulatory elements may be critical in the process of nucleosome assembly, recruitment of chromatin-modifying activities, and the regulation of human b-globin gene expression.     

Nonhistone proteins HMG1 and HMG2 unwind DNA double helix.

In a previous communication we have shown that both HMG1 and HMG2 nonhistone proteins change the DNA helical structure and the binding of HMG1 and HMG2 to DNA induces a net unwinding equivalent of DNA double helix (Javaherian, K., Liu, L. F. and Wang, J. C. (1978) Science, 199, 1345-1346). Employing melting absorption technique, we now show that in the presence of salt HMG1 and HMG2 destabilize DNA whereas in the absence of salt, they both stabilize DNA molecules. Consequently the folded structure of HMG must play an important role in melting DNA. Furthermore, by measuring topological winding number using competition unwinding experiments, we conclude that HMG1 has a higher affinity for a single-stranded DNA relative to double-stranded DNA. These results together suggest that HMG1 and HMG2 unwind DNA double helix by local denaturation of the DNA base pairs. The net unwinding angles have been measured to be 22 degrees and 26 degrees per molecule of HMG1 and HMG2 respectively.     

Nonhistone chromosomal protein HMG 1 interactions with DNA. Fluorescence and thermal denaturation studies

The interaction of high mobility group protein 1 (HMG 1) isolated from chicken erythrocytes with DNA has been characterized using the intrinsic tryptophan fluorescence of the protein as a probe. It was found that the fluorescence is quenched approximately 30% upon binding to either single- or double-stranded DNA. Fluorescent titrations indicate that the physical site size for HMG 1 binding on native DNA is approximately 14 base pairs (or 14 bases for binding to single-stranded DNA). Binding to single-stranded poly(dA) is only slightly dependent on ionic strength, although the affinity for double-stranded DNA is strongly ionic strength-dependent and has an optimum at approximately 100-120 mM Na+. Above this range, binding to native DNA is virtually all electrostatic in nature. Although the affinity of HMG 1 for single-stranded DNA is higher than that for double-stranded DNA at the extremes of the ionic range studied, no clear evidence for a helix-destabilizing activity was obtained. At low ionic strength, the protein actually stabilized DNA against thermal denaturation, while at high ionic strength, HMG 1 appears to undergo denaturation below the Tm of the DNA. Studies of the environment of the tryptophan fluorophores using collisional quenchers iodide, cesium, and acrylamide suggest that the predominant fluorophore is relatively exposed but constrained in a rigid, positively charged environment.