DNA binding by single HMG box model proteins

The HMG1/2 family is a large group of proteins that share a conserved sequence of ~80 amino acids rich in basic, aromatic and proline side chains, referred to as an HMG box. Previous studies show that HMG boxes can bind to DNA in a structure-specific manner. To define the basis for DNA recognition by HMG boxes, we characterize the interaction of two model HMG boxes, one a structure-specific box, rHMGb from the rat HMG1 protein, the other a sequence-specific box, Rox1 from yeast, with oligodeoxynucleotide substrates. Both proteins interact with single-stranded oligonucleotides in this study to form 1:1 complexes. The stoichiometry of binding of rHMGb to duplex or branched DNAs differs: for a 16mer duplex we find a weak 2:1 complex, while a 4:1 protein:DNA complex is detected with a four-way DNA junction of 16mers in the presence of Mg²⁺. In the case of the sequence-specific Rox1 protein we find tight 1:1 and 2:1 complexes with its cognate duplex sequence and again a 4:1 complex with four-way branched DNA. If the DNA branching is reduced to three arms, both proteins form 3:1 complexes. We believe that these multimeric complexes are relevant for HMG1/2 proteins in vivo, since Mg²⁺ is present in the nucleus and these proteins are expressed at a very high level.     

Investigation of the structural stability of hUBF HMG box 5 by native-state hydrogen exchange

HMG box 5 of human upstream binding factor (hUBF) consists of three alpha-helices arranged in an L-shape with a hydrophobic core embraced by these helices and stabilized by extensive hydrophobic interactions between nonpolar residues around the core. The GdmCl-induced equilibrium unfolding transition of HMG box 5 of hUBF was monitored by both circular dichroism (CD) and fluorescence spectra. A cooperative two-state unfolding process was observed. The unfolding free energy, DeltaGU(D2O), and the cooperativity of the unfolding reaction, m, are 4.6 +/- 0.16 kcal x mol-1 and 1.62 +/- 0.06 kcal x mol-1 x M-1, respectively. Native-state hydrogen exchange (NHX) experiments under EX2 conditions were performed. NHX results clearly show that the hydrophobic core among the three helices is a slow-exchange core. The three helices would not contribute equally to the stability of the native protein. Helix 3 appears to contribute the least to the stability. The NHX data have also allowed the local, subglobal, and global unfolding structures of hUBF HMG box 5 to be dissected, and common global and subglobal unfolding units were successfully detected.     

亚洲玉米螟酚氧化酶原的原核表达和性质分析

【目的】昆虫体内酚氧化酶原（PPO）是一种重要的天然免疫蛋白,参与昆虫的体液免疫和细胞免疫过程。本研究采用原核表达体系,大量表达可溶且具有活性的重组PPO蛋白,可用于各种酚氧化酶（PO）抑制剂的筛选,从而为创制抑制昆虫免疫系统的新型杀虫剂提供条件。【方法】利用从亚洲玉米螟Ostrinia furnacalis 5龄幼虫体内克隆获得PPO基因,构建了pET-28b-PPO原核表达载体,在大肠杆菌Escherichia coli中重组表达了亚洲玉米螟PPO蛋白;采用Ni-NAT亲和层析柱快速纯化目的蛋白,进行了Western杂交鉴定;测定分析了重组PPO蛋白激活为PO后的酶学性质以及不同金属离子（Mg²⁺,Cu²⁺和Fe²⁺）对PPO二级结构的影响。【结果】融合蛋白PPO得到了表达和纯化。重组PPO蛋白激活为PO后最适反应温度为30℃,最适pH为7.2,以L-DOPA为底物时PO催化反应的V_max为140.8 U/mg·min,Km为2.96 mmol/L。Fe²⁺存在的情况下重组PPO蛋白中β-折叠结构成分显著增加至53.7%±4.6%,α-螺旋结构成分则显著下降至2.6%±1.2%（P<0.05）;有Mg2+存在的情况下,重组PPO蛋白中β-折叠结构成分显著下降,α-螺旋结构成分稍有上升。有Cu²⁺存在的情况下,重组PPO蛋白中β-折叠结构成分显著下降为10.0%±1.6%,而α-螺旋结构成分则上升至35.3%±6.9%。【结论】结果说明不同金属离子对重组PPO蛋白的二级结构有显著影响。     

Temperature‐induced partially unfolded state of hUBF HMG Box‐5: Conformational and dynamic investigations of the Box‐5 thermal intermediate ensemble

Human upstream binding factor (hUBF) HMG Box‐5 is a highly conserved protein domain, containing 84 amino acids and belonging to the family of the nonspecific DNA‐binding HMG boxes. Its native structure adopts a twisted L shape, which consists of three α‐helices and two hydrophobic cores: the major wing and the minor wing. In this article, we report a reversible three‐state thermal unfolding equilibrium of hUBF HMG Box‐5, which is investigated by differential scanning calorimetry (DSC), circular dichroism spectroscopy, fluorescence spectroscopy, and NMR spectroscopy. DSC data show that Box‐5 unfolds reversibly in two separate stages. Spectroscopic analyses suggest that different structural elements exhibit noncooperative transitions during the unfolding process and that the major form of the Box‐5 thermal intermediate ensemble at 55°C shows partially unfolded characteristics. Compared with previous thermal stability studies of other boxes, it appears that Box‐5 possesses a more stable major wing and two well separated subdomains. NMR chemical shift index and sequential ¹H^N_i‐¹H^N_i+1 NOE analyses indicate that helices 1 and 2 are native‐like in the thermal intermediate ensemble, while helix 3 is partially unfolded. Detailed NMR relaxation dynamics are compared between the native state and the intermediate ensemble. Our results implicate a fluid helix‐turn‐helix folding model of Box‐5, where helices 1 and 2 potentially form the helix 1‐turn‐helix 2 motif in the intermediate, while helix 3 is consolidated only as two hydrophobic cores form to stabilize the native structure. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Molecular insights into the mechanisms of cation-type specific stability and denaturation of poly-l-glutamate: a simulation study

Cation-induced conformational changes of peptide as a guide to developing insights into human diseases-related proteins have received a lot of attention. The interactions between poly-l-glutamate (PGA) and different cations, including Na⁺, K⁺ and Mg²⁺, respectively, are studied in solvent at a concentration of 1 M, and the behaviours of peptide with different cations are investigated. For Na⁺, an oscillatory stabilising process to α-helix PGA is found, in accordance with the uniform free-energy landscape, whereas for K⁺, an extended α-helix structure is formed by the terminal turns, suggesting a weaker attraction to charged head groups. For Mg²⁺, the bridged charged side chains are responsible for the maximum probability of helix state. These distinct structural changes can be attributed to the different interactions between charged head groups and cations. Both Na⁺ and K⁺ are mainly attracted around head groups by direct ion binding while Mg²⁺ is centrally trapped among adjacent charged head groups. In addition, a surprising shift of the backbone hydrogen bond, from intact state to intermediate state, is observed. This is opposite to the stabilising effect of Na⁺ around negatively charged head groups.     

Conformational transitions of calmodulin as studied by vacuum-uv CD

CD measurements were made for calmodulin and its calcium (Ca²⁺) complexes at different ionic strengths and Ca²⁺ concentrations. Calmodulin at an ionic strength of 0.00M and in the absence of Ca²⁺ exists as an α-helical protein with a negligible amount of β-sheet. An increase in ionic strength, whether or not Ca²⁺ is present, increases α-helix at the expense of “other” (coil) structure. The changes in β-sheet and β-turns are insignificant. Binding of Ca²⁺ at low ionic strength occurs in stages with at least one folding intermediate before attaining the final stable state. Binding of Ca²⁺ at an ionic strength of 0.165M causes only a slight increase in α-helix, so that the secondary structure of the protein depends on ionic strength and is insensitive to the nature of the cation (i.e., Ca²⁺). Thus, the activation of calmodulin by Ca²⁺ must be due to a structural reorientation rather than to a major secondary structural alteration. The CD estimation of secondary structure with 4 mol Ca²⁺/calmodulin (61% α-helix, 2% antiparallel β-sheet, 2% parallel β-sheet, 21% β-turns, and 14% other) is in excellent agreement with the x-ray results.     

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.     

The Effects of Metal Ions on the Cytotoxicity and Selectivity of a Histidine-Containing Lytic Peptide

The histidine-containing peptide L5C (PAWRHAFHWAWHMLHKAA) is a histidine-rich lytic peptide. Interactions of some divalent metal ions with peptide L5C and their effects on the cell lysis activity of the peptide were studied. The presence of Cu²⁺ caused a secondary structure change (from random coil to α-helix) which resulted in the loss of cell lysis activity in peptide L5C. Binding of Zn²⁺ to peptide L5C also reduced the lytic activity of the peptide but Zn²⁺ did not affect the secondary structure of the peptides. Instead, Zn²⁺ induced peptide L5C aggregation. Unlike Zn²⁺ and Cu²⁺, Mg²⁺ had no significant effect on the activity of peptide L5C. Further experiments revealed that formed ion-peptide L5C complexes were sensitive to pH and dissociated in acidic solutions. Peptide L5C demonstrated improved pH-selectivity in the presence of trace amount of Zn²⁺. This property of histidine-containing lytic peptides can be used to improve their therapeutic effectiveness in the treatment of cancers.     

Lipoxygenbase-derived products of arachidonic acid mediate stimulation of hexose uptake in human polymorphonuclear leukocytes

The titration of metal-freed bovine α-lactalbumin with Mg²⁺ ions causes a two-stepped decrease in the tryptophan fluorescence quantum yield and a pronounced spectral shift towards shorter wavelengths, which seems to be a result of the binding of two magnesium ions to the protein molecule. The magnesium binding constants evaluated from the fluorimetric Mg²⁺-titration are 2·10³ and 2·10² M^?1. Mg²⁺ ions in millimolar concentrations almost do not influence the binding of Ca²⁺ ions to the protein.     

Magnesium-dependent conformational changes of membrane proteins are related to the Mg2+ -dependent ATPase activity in cardiac sarcolemma

Magnesium-induced enzymatic and structural changes of membrane-bound proteins in rat heart sarcolemma have been investigated. In the absence of ATP, increasing concentrations of magnesium within the range 0.1–10.0 mM gradually lowered the α-helix content of sarcolemmal proteins. The same magnesium concentrations stepwise activated the Mg²⁺-dependent ATPase in the presence of ATP. Mathematical and graphical analysis of the data yielded a quantitative relationship between magnesium-induced stimulation of the Mg²⁺-dependent ATPase activity and diminution of the α-helix content of membrane proteins in cardiac sarcolemma.     

Interaction of HMG proteins and H1 with hybrid PNA–DNA junctions

The objective of this study was to evaluate the effects of inserting peptide nucleic acid (PNA) sequences into the protein‐binding surface of an immobilized four‐way junction (4WJ). Here we compare the classic immobile DNA junction, J1, with two PNA containing hybrid junctions (4WJ‐PNA₁ and 4WJ‐PNA₃). The protein interactions of each 4WJ were evaluated using recombinant high mobility group proteins from rat (HMGB1b and HMGB1b/R26A) and human histone H1. In vitro studies show that both HMG and H1 proteins display high binding affinity toward 4WJ's. A 4WJ can access different conformations depending on ionic environment, most simply interpreted by a two‐state equilibrium between: (i) an open‐x state favored by absence of Mg²⁺, low salt, and protein binding, and (ii) a compact stacked‐x state favored by Mg²⁺. 4WJ‐PNA₃, like J1, shifts readily from an open to stacked conformation in the presence of Mg⁺², while 4WJ‐PNA₁ does not. Circular dichroism spectra indicate that HMGB1b recognizes each of the hybrid junctions. H1, however, displays a strong preference for J1 relative to the hybrids. More extensive binding analysis revealed that HMGB1b binds J1 and 4WJ‐PNA₃ with nearly identical affinity (K_Ds) and 4WJ‐PNA₁ with two‐fold lower affinity. Thus both the sequence/location of the PNA sequence and the protein determine the structural and protein recognition properties of 4WJs.     

The in vitro synthesis of lysozyme,total proteins,and polyphenylalanine by ribosomes containing hydrolyzed ribonucleic acid

Ribosomes containing 23S rRNA with one scission per molecule were found to be inactive in the synthesis of lysozyme, total protein, and polyphenylalanine at 9.1 mm Mg²⁺. Increasing the Mg²⁺ concentration to 12.0 mm restored synthesis of lysozyme and total proteins. Ribosomes with two or more scissions in 23S rRNA were fully active in the synthesis of lysozyme, total protein, and polyphenylalanine at 9.1 mm Mg²⁺. It appears that one scission in the 23S rRNA molecule in a 70S ribosome allows the structure of the ribosome to change so as to disorient ribosomal proteins or rRNA. A second scission in 23S rRNA or an increase in Mg²⁺ concentration reverses the change which occurred with the first scission.