Hoechst 33258, distamycin A,and high mobility group protein I (HMG-I) compete for binding to mouse satellite DNA

The experiments described were designed to test the hypothesis that the (A+T)-specific DNA binding ligands Hoechst 33258 and distamycin A affect the condensation of mouse centromeric heterochromatin by competing for binding to satellite DNA with one or more chromosomal proteins. The studies focused on the nonhistone chromosomal protein HMG-I since its binding properties predict it would be a target for competition. Gel mobility shift assays show that HMG-I forms specific complexes with satellite DNA and that the formation of these complexes is competed for by both Hoechst and distamycin. In addition, methidium propyl EDTA Fe(II) [MPE Fe(II)] footprints of ligand-satellite DNA complexes showed essentially the same protection pattern for both drugs and a similar, but not identical, HMG-I footprint. If these in vitro results reflect the in vivo situation then the incomplete condensation of centromeric heterochromatin observed when mouse cells are grown in the presence of either chemical ligand could be a consequence of competition for binding of HMG-I (and possibly other proteins) to satellite DNA.by E.R. Schmidt     

Competition between HMG-I(Y), HMG-1 and histone H1 on four-way junction DNA.

High mobility group proteins HMG-I(Y) and HMG-1, as well as histone H1, all share the common property of binding to four-way junction DNA (4H), a synthetic substrate commonly used to study proteins involved in recognizing and resolving Holliday-type junctions formed during in vivo genetic recombination events. The structure of 4H has also been hypothesized to mimic the DNA crossovers occurring at, or near, the entrance and exit sites on the nucleosome. Furthermore, upon binding to either duplex DNA or chromatin, all three of these nuclear proteins share the ability to significantly alter the structure of bound substrates. In order to further elucidate their substrate binding abilities, electrophoretic mobility shift assays were employed to investigate the relative binding capabilities of HMG-I(Y), HMG-1 and H1 to 4H in vitro. Data indicate a definite hierarchy of binding preference by these proteins for 4H, with HMG-I(Y) having the highest affinity (Kd approximately 6.5 nM) when compared with either H1 (Kd approximately 16 nM) or HMG-1 (Kd approximately 80 nM). Competition/titration assays demonstrated that all three proteins bind most tightly to the same site on 4H. Hydroxyl radical footprinting identified the strongest site for binding of HMG-I(Y), and presumably for the other proteins as well, to be at the center of 4H. Together these in vitro results demonstrate that HMG-I(Y) and H1 are co-dominant over HMG-1 for binding to the central crossover region of 4H and suggest that in vivo both of these proteins may exert a dominant effect over HMG-1 in recognizing and binding to altered DNA structures, such as Holliday junctions, that have conformations similar to 4H.     

Specific A . T DNA sequence binding of RP-HPLC purified HMG-I

HMG-I (alpha-protein) is a high mobility group protein which recognizes and binds specifically to A . T rich double stranded DNA. We have investigated, by electrophoretic shift assays and DNase I footprinting, the ability of reverse-phase high performance liquid chromatography purified HMG-I to bind to specific A . T rich duplex DNA sequences. We show here that when HMG-I is isolated and purified under denaturing conditions it retains its specific A . T DNA binding activity. These results suggest that reverse-phase high performance liquid chromatography to be the method of choice for the preparation of HMG-I.     

HMG protein family members stimulate human immunodeficiency virus type 1 and avian sarcoma virus concerted DNA integration in vitro

We have reconstituted concerted human immunodeficiency virus type 1 (HIV-1) integration in vitro with specially designed mini-donor HIV-1 DNA, a supercoiled plasmid acceptor, purified bacterium-derived HIV-1 integrase (IN), and host HMG protein family members. This system is comparable to one previously described for avian sarcoma virus (ASV) (A. Aiyar et al., J. Virol. 70:3571-3580, 1996) that was stimulated by the presence of HMG-1. Sequence analyses of individual HIV-1 integrants showed loss of 2 bp from the ends of the donor DNA and almost exclusive 5-bp duplications of the acceptor DNA at the site of integration. All of the integrants sequenced were inserted into different sites in the acceptor. These are the features associated with integration of viral DNA in vivo. We have used the ASV and HIV-1 reconstituted systems to compare the mechanism of concerted DNA integration and examine the role of different HMG proteins in the reaction. Of the three HMG proteins examined, HMG-1, HMG-2, and HMG-I(Y), the products formed in the presence of HMG-I(Y) for both systems most closely match those observed in vivo. Further analysis of HMG-I(Y) mutants demonstrates that the stimulation of integration requires an HMG-I(Y) domain involved in DNA binding. While complexes containing HMG-I(Y), ASV IN, and donor DNA can be detected in gel shift experiments, coprecipitation experiments failed to demonstrate stable interactions between HMG-I(Y) and ASV IN or between HMG-I(Y) and HIV-1 IN.     

HMG-1 enhances HMG-I/Y binding to an A/T-rich enhancer element from the pea plastocyanin gene.

High-mobility-group proteins HMG-1 and HMG-I/Y bind at overlapping sites within the A/T-rich enhancer element of the pea plastocyanin gene. Competition binding experiments revealed that HMG-1 enhanced the binding of HMG-I/Y to a 31-bp region (P31) of the enhancer. Circularization assays showed that HMG-1, but not HMG-I/Y, was able to bend a linear 100-bp DNA containing P31 so that the ends could be ligated. HMG-1, but not HMG-I/Y, showed preferential binding to the circular 100-bp DNA compared with the equivalent linear DNA, indicating that alteration of the conformation of the DNA by HMG-1 was not responsible for enhanced binding of HMG-I/Y. Direct interaction of HMG-I/Y and HMG-1 in the absence of DNA was demonstrated by binding of 35S-labeled proteins to immobilized histidine-tagged proteins, and this was due to an interaction of the N-terminal HMG-box-containing region of HMG-1 and the C-terminal AT-hook region of HMG-I/Y. Kinetic analysis using the IAsys biosensor revealed that HMG-1 had an affinity for immobilized HMG-I/Y (Kd = 28 nM) similar to that for immobilized P31 DNA. HMG-1-enhanced binding of HMG-I/Y to the enhancer element appears to be mediated by the formation of an HMG-1-HMG-I/Y complex, which binds to DNA with the rapid loss of HMG-1.     

Structural changes induced by binding of the high-mobility group I protein to a mouse satellite DNA sequence

Using spectroscopic methods, we have studied the structural changes induced in both protein and DNA upon binding of the High-Mobility Group I (HMG-I) protein to a 21-bp sequence derived from mouse satellite DNA. We show that these structural changes depend on the stoichiometry of the protein/DNA complexes formed, as determined by Job plots derived from experiments using pyrene-labeled duplexes. Circular dichroism and melting temperature experiments extended in the far ultraviolet range show that while native HMG-I is mainly random coiled in solution, it adopts a beta-turn conformation upon forming a 1:1 complex in which the protein first binds to one of two dA.dT stretches present in the duplex. HMG-I structure in the 1:1 complex is dependent on the sequence of its DNA target. A 3:1 HMG-I/DNA complex can also form and is characterized by a small increase in the DNA natural bend and/or compaction coupled to a change in the protein conformation, as determined from fluorescence resonance energy transfer (FRET) experiments. In addition, a peptide corresponding to an extended DNA-binding domain of HMG-I induces an ordered condensation of DNA duplexes. Based on the constraints derived from pyrene excimer measurements, we present a model of these nucleated structures. Our results illustrate an extreme case of protein structure induced by DNA conformation that may bear on the evolutionary conservation of the DNA-binding motifs of HMG-I. We discuss the functional relevance of the structural flexibility of HMG-I associated with the nature of its DNA targets and the implications of the binding stoichiometry for several aspects of chromatin structure and gene regulation.     

High mobility group proteins HMG-1 and HMG-I/Y bind to a positive regulatory region of the pea plastocyanin gene promoter

A 268 bp region (P268) of the pea plastocyanin gene promoter responsible for high-level expression has been shown to interact with the high mobility group proteins HMG-1 and HMG-I/Y isolated from pea shoot chromatin. cDNAs encoding an HMG-1 protein of 154 amino acid residues containing a single HMG-box and a C-terminal acidic tail and an HMG-I/Y-like protein of 197 amino acid residues containing four AT-hooks have been isolated and expressed in Escherichia coli to provide large amounts of full-length proteins. DNase I footprinting identified eight binding sites for HMG-I/Y and six binding sites for HMG-1 in P268. Inhibition of binding by the antibiotic distamycin, which binds in the minor groove of A/T-rich DNA, revealed that HMG-I/Y binding was 400-fold more sensitive than HMG-1 binding. Binding-site selection from a pool of random oligonucleotides indicated that HMG-I/Y binds to oligonucleotides containing stretches of five or more A/T bp and HMG-1 binds preferentially to oligonucleotides enriched in dinucleotides such as TpT and TpG.     

The amino acid sequence of the chromosomal protein HMG-Y, its relation to HMG-I and possible domains for the preferential binding of the proteins to stretches of A-T base pairs

The primary structure of the human high mobility group (HMG) protein HMG-Y has been established except for a few amino acids in the N-terminal and the C-terminal part of the protein. It was found that the sequence was identical to that of HMG-I except for a run of eleven amino acids. Like HMG-I the protein was N-terminally blocked and the palindromic sequence Pro-Arg-Gly-Arg-Pro occurred twice as in HMG-I. The binding of peptides derived from HMG-I (after thermolysin cleavage) to poly (dA-dT).poly(dA-dT) suggested that there are at least two different binding domains in the protein and that binding is not dependent upon an intact protein.     

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).     

Kinetic analysis of high-mobility-group proteins HMG-1 and HMG-I/Y binding to cholesterol-tagged DNA on a supported lipid monolayer

High-mobility-group proteins HMG-1 and HMG-I/Y bind to multiple sites within a 268 bp A/T-rich enhancer element of the pea plastocyanin gene (PetE). Within a 31 bp region of the enhancer, the binding site for HMG-1 overlaps with the binding site for HMG-I/Y. The kinetics of binding and the affinities of HMG-1 and HMG-I/Y for the 31 bp DNA were determined using surface plasmon resonance. Due to very high non-specific interactions of the HMG proteins with a carboxymethyl–dextran matrix, a novel method using a cholesterol tag to anchor the DNA in a supported lipid monolayer on a thin gold film was devised. The phosphatidylcholine monolayer produced a surface that reduced background interactions to a minimum and permitted the measurement of highly reproducible protein–DNA interactions. The association rate constant (k_a) of HMG-I/Y with the 31 bp DNA was ~5-fold higher than the rate constant for HMG-1, whereas the dissociation constant (K_D) for HMG-I/Y (3.1 nM) was ~7-fold lower than that for HMG-1 (20.1 nM). This suggests that HMG-I/Y should bind preferentially at the overlapping binding site within this region of the PetE enhancer.