DNAase I hypersensitive sites may be correlated with genomic regions of large structural variation

Helical-twist, roll and torsion-angle variations calculated by the Calladine (1982)-Dickerson (1983) rules were scanned along several nucleotide sequences for which DNAase I cleavage data are available. It has been shown that for short synthetic oligomers DNAase I cuts preferentially at positions of high helical twist (Dickerson & Drew, 1981; Lomonossoff et al., 1981). Our calculations indicate that DNAase I sensitive and hypersensitive sites in chromatin are correlated with regions of successive, large, helical-twist angle variations from regular B-DNA. In many cases these regions exhibit large variations in base-pair roll and backbone torsion angles as well. It has been suggested that DNAase I cuts in the vicinity of cruciforms. However, it was recently demonstrated by Courey & Wang (1983) and Gellert et al. (1983) that such cruciform formation in a negatively supercoiled DNA is kinetically forbidden under physiological conditions. We thus propose that clustering of large twist-angle (and/or roll and backbone torsion angle) variations may be among the conformational features recognized by the enzyme. Specific cuts can then preferentially occur at base-pair steps with high helical twists.     

Separation of the high affinity insulin-like growth factor I receptor from low affinity binding sites by affinity chromatography

We have identified high and low affinity insulin-like growth factor I (IGF I)-binding sites with mean dissociation constants of 0.37 and 6.25 nM, respectively, in solubilized placental membranes. We have separated these sites and purified the high affinity IGF I receptor 1,300-fold, with an overall yield of 9.9%, using wheat germ agglutinin-Sepharose chromatography, insulin affinity chromatography, and IGF I affinity chromatography. The Scatchard plot of IGF I binding to the high affinity receptor is linear, suggesting the purification of a single homogeneous class of binding sites. Insulin is two orders of magnitude less effective than IGF I in competitively inhibiting IGF I binding to this receptor. The high affinity IGF I receptor is composed of alpha and beta subunits with apparent molecular weights of 135,500 and 96,200, respectively. IGF I at concentrations of greater than or equal to 50 ng/ml stimulates autophosphorylation of the beta subunit of the purified high affinity receptor 4.6-fold. Low affinity IGF I-binding sites run through the IGF I affinity column or are eluted from the insulin affinity column. The separation of IGF I receptors with different binding affinities by sequential affinity chromatography will make it possible to examine directly the determinants of receptor affinity.     

Type I collagen contains at least 14 cryptic fibronectin binding sites of similar affinity

There is uncertainty in the literature regarding the number and location of fibronectin binding sites on denatured collagen. Although most attention has focused on a single site near the collagenase-sensitive region of each alpha chain, there is evidence for additional sites in other regions. We treated bovine type I collagen with cyanogen bromide, labeled the resulting mixture with fluorescein, and separated the peptides by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Fluorescent bands were excised from the gel and dialyzed exhaustively to remove detergent. Titration of eight distinct fluorescent-labeled fragments with the 42-kDa gelatin-binding fragment of fibronectin caused increases in anisotropy that were fully reversible with unlabeled gelatin. By fitting the dose responses it was possible to calculate apparent K(d)'s whose values ranged between 1 and 4 microM. The largest fragment, alpha(2)-CB3,5, composing about 2/3 of the alpha(2) chain, when further digested with endoproteinase Lys-C, yielded at least three additional subfragments that also bound with similar affinities. Thus, there appear to be at least 14 distinct fibronectin binding sites of similar affinity in bovine type I collagen, five on each of the alpha(1) chains and four on the alpha(2) chain. Experiments with several synthetic peptides failed to reveal the exact nature of the binding site.     

DNAase I,DNAase II and staphylococcal nuclease cut at different,yet symmetrically located,sites in the nucleosome core

We have determined the relative location of pancreatic DNAase (DNAase I), spleen acid DNAase (DNAase II) and staphylococcal nuclease cleavage sites in the nucleosome core. Each of these three enzymes cleaves the DNA of chromatin at 10. n nucleotide intervals (n integer); this specificity presumably reflects the internal structure of the nucleosome. We have already reported that DNAase I cleaves nucleosomal DNA so that nearest adjacent cuts on opposite strands are staggered by 2 nucleotides, 3′ end extending (Sollner-Webb and Felsenfeld, 1977). Here we show that the nearest cuts made by DNAase II in nucleosomal DNA are staggered by 4 nucleotides, 3′ end extending, while cuts made by staphylococcal nuclease have a stagger of 2 nucleotides, 5′ end extending. The cutting sites of the three enzymes thus do not coincide. Each pair of staggered cuts, however, is symmetrically located about a common axis-that is, the “dyad axes” that bisect nearest pairs of cutting sites coincide for all three enzymes. This result is consistent with the presence of a true dyad axis in the nucleosome core.Our results support the conclusion that a structural feature of the nucleosome, having a 10 nucleotide periodicity, is the common recognition site for all three nucleases. The position of the cut is determined, however, by the individual characteristics of each enzyme. Sites potentially available to nuclease cleavage span a region of 4 nucleotides out of this 10 nucleotide repeat, and a large fraction of these sites are actually cut. Thus much of the nucleosomal DNA must in some sense be accessible to the environment.     

DNA topoisomerase II selects DNA cleavage sites based on reactivity rather than binding affinity

DNA topoisomerase II modulates DNA topology by relieving supercoil stress and by unknotting or decatenating entangled DNA. During its reaction cycle, the enzyme creates a transient double-strand break in one DNA segment, the G-DNA. This break serves as a gate through which another DNA segment is transported. Defined topoisomerase II cleavage sites in genomic and plasmid DNA have been previously mapped. To dissect the G-DNA recognition mechanism, we studied the affinity and reactivity of a series of DNA duplexes of varied sequence under conditions that only allow G-DNA to bind. These DNA duplexes could be cleaved to varying extents ranging from undetectable (<0.5%) to 80%. The sequence that defines a cleavage site resides within the central 20bp of the duplex. The DNA affinity does not correlate with the ability of the enzyme to cleave DNA, suggesting that the binding step does not contribute significantly to the selection mechanism. Kinetic experiments show that the selectivity interactions are formed before rather than subsequent to cleavage. Presumably the binding energy of the cognate interactions is used to promote a conformational change that brings the enzyme into a cleavage competent state. The ability to modulate the extent of DNA cleavage by varying the DNA sequence may be valuable for future structural and mechanistic studies that aim to determine topoisomerase structures with DNA bound in pre- and post-cleavage states and to understand the conformational changes associated with DNA binding and cleavage.     

Interactions between eukaryotic DNA topoisomerase I and a specific binding sequence

The interaction between eukaryotic DNA topoisomerase I and a high affinity binding sequence was investigated. Quantitative footprint analysis demonstrated that the substrate preference results from strong specific binding of topoisomerase I to the sequence. The specificity was conferred by a tight noncovalent association between the enzyme and its target DNA, whereas the transient formation of a covalently bound enzyme.nicked DNA intermediate contributed insignificantly to the overall affinity. Topoisomerase I protected both strands over a 20-base pair region in which the cleavage site was centrally located. DNA modification interference analysis revealed a 16-base pair interference region on the scissile strand. Essential bases were confined to the 5' side of the cleavage site. The 6-base pair interference region observed on the complementary strand did not contain essential bases.     

Location of the ethidium binding sites of high affinity in chromatin

The influence of H1 and H5 histones proteins upon the accessibility of ethidium bromide into chromatin is studied by steady-state fluorescence anisotropy in the range of r-values ([Dye]/[Phosphate]) smaller than 0.01. This corresponds to the very strong binding process. When H1 and H5 are present, the DNA segment which contains the binding sites is 25–30 base pairs long, even if H1 and H5 are digested by trypsin or by natural proteolysis, but presumably still interacting with the DNA chromatin. On the contrary, when H1 or H5 are separated from chromatin by an increase of the ionic strength, ethidium binds to a segment of DNA about 55–60 base pairs long. We may explain the results by assuming that the ethidium sites are located on a continuous segment constituting about one half of the linker, the other half interacting with H1 and H5. When chromatin is depleted from these proteins, the high affinity sites are distributed all along the linker.     

Insulin-like growth factor II binding to the type I somatomedin receptor. Evidence for two high affinity binding sites

We have previously shown that the antireceptor antibody alpha IR-3 inhibits binding of 125I-somatomedin-C/insulin-like growth factor I (Sm-C/IGF-I) to the 130-kDa alpha subunit of the type I receptor in human placental membranes, but does not block 125I-insulin-like growth factor II (IGF-II) binding to a similar 130-kDa complex in these membranes. To determine whether the 130-kDa 125I-IGF-II binding complex represents a homologous receptor or whether 125I-IGF-II binds to the type I receptor at a site that is not blocked by alpha IR-3, type I receptors were purified by affinity chromatography on Sepharose linked alpha IR-3. The purified receptors bound both 125I-Sm-C/IGF-I and 125I-IGF-II avidly (KD = 2.0 X 10(-10) M and 3.0 X 10(-10) M, respectively). The maximal inhibition of 125I-Sm-C/IGF-I binding by the antibody, however, was 62% while only 15% of 125I-IGF-II binding was inhibited by alpha IR-3. In the presence of 500 nM alpha IR-3, Sm-C/IGF-I bound with lower affinity (KD = 6.5 X 10(-10) M) than IGF-II (KD = 4.5 X 10(-10) M) and IGF-II was the more potent inhibitor of 125I-Sm-C/IGF-I binding. These findings suggest that the type I receptor contains two different binding sites. The site designated IA has highest affinity for Sm-C/IGF-I and is blocked by alpha IR-3. Site IB has higher affinity for IGF-II than for Sm-C/IGF-I and is not blocked by alpha IR-3.     

Antiestrogen specific,high affinity saturable binding sites in rat uterine cytosol

Analysis of rat uterine cytosol for Tamoxifen binding reveals that the saturable binding sites are only partially inhibited by estradiol-17β. Partial thermal denaturation of the cytosol at 30° C for 2 h 30 allows the characterization of a high affinity (Kd = 3.3 × 10^?9M) saturable Tamoxifen class of binding sites insensitive to estradiol-17β while remaining sensitive to the antiestrogens CI628 and Nafoxidine. The uterine concentration of these binding sites is lower in the uterus of immature or castrated animals, increases from metestrus to proestrus and reaches a peak on the day of estrus.     

Inhibition of topoisomerase I prevents chromosome breakage at common fragile sites

Common fragile sites are loci that preferentially form gaps and breaks on metaphase chromosomes when DNA synthesis is perturbed, particularly after treatment with the DNA polymerase inhibitor, aphidicolin. We and others have identified several cell cycle checkpoint and DNA repair proteins that influence common fragile site stability. However, the initial events underlying fragile site breakage remain poorly understood. We demonstrate here that aphidicolin-induced gaps and breaks at fragile sites are prevented when cells are co-treated with low concentrations of the topoisomerase I inhibitor, camptothecin. This reduction in breakage is accompanied by a reduction in aphidicolin-induced RPA foci, CHK1 and RPA2 phosphorylation, and PCNA monoubiquitination, indicative of reduced levels of single stranded DNA. Furthermore, camptothecin reduces spontaneous fragile site breakage seen in cells lacking ATR, even in the absence of aphidicolin. These data from cultured human cells demonstrate that topoisomerase I activity is required for DNA common fragile site breaks and suggest that polymerase–helicase uncoupling is a key initial event in this process.     

A novel bipartite mode of binding of M. smegmatis topoisomerase I to its recognition sequence

We have investigated interaction of Mycobacterium smegmatis topoisomerase I at its specific recognition sequence. DNase I footprinting demonstrates a large region of protection on both the scissile and non-scissile strands of DNA. Methylation protection and interference analyses reveal base-specific contacts within the recognition sequence. Missing contact analyses reveal additional interactions with the residues in both single and double-stranded DNA, and hence underline the role for the functional groups associated with those bases. These interactions are supplemented by phosphate contacts in the scissile strand. Conformation specific probes reveal protein-induced structural distortion of the DNA helix at the T-A-T-A sequence 11 bp upstream to the recognition sequence. Based on these footprinting analyses that define parameters of topoisomerase I-DNA interactions, a model of topoisomerase I binding to its substrate is presented. Within the large protected region of 30 bp, the enzyme makes direct contact at two locations in the scissile strand, one around the cleavage site and the other 8-12 bases upstream. Thus the enzyme makes asymmetric recognition of DNA and could carry out DNA relaxation by either of the two proposed mechanisms: enzyme bridged and restricted rotation.     

Mutation of the high affinity calcium binding sites in cardiac troponin C.

Fast skeletal and cardiac troponin C (TnC) contain two high affinity Ca2+/Mg2+ binding sites within the C-terminal domain that are thought to be important for association of TnC with the troponin complex of the thin filament. To test directly the function of these high affinity sites in cardiac TnC they were systematically altered by mutagenesis to generate proteins with a single inactive site III or IV (CBM-III and CBM-IV, respectively), or with both sites III and IV inactive (CBM-III-IV). Equilibrium dialysis indicated that the mutated sites did not bind Ca2+ at pCa 4. Both CBM-III and CBM-IV were similar to the wild type protein in their ability to regulate Ca(2+)-dependent contraction in slow skeletal muscle fibers, and Ca(2+)-dependent ATPase activity in fast skeletal and cardiac muscle myofibrils. The mutant CBM-III-IV is capable of regulating contraction in permeabilized slow muscle fibers but only if the fibers are maintained in a contraction solution containing a high concentration of the mutant protein. CBM-III-IV also regulates myofibril ATPase activity in fast skeletal and cardiac myofibrils but only at concentrations 10-100-fold greater than the normal protein. The pCa50 and Hill coefficient values for Ca(2+)-dependent activation of fast skeletal muscle myofibril ATPase activity by the normal protein and all three mutants are essentially the same. Competition between active and inactive forms of cardiac and slow TnC in a functional assay demonstrates that mutation of both sites III and IV greatly reduces the affinity of cardiac and slow TnC for its functionally relevant binding site in the myofibrils. The data indicate that although neither high affinity site is absolutely essential for regulation of muscle contraction in vitro, at least one active C-terminal site is required for tight association of cardiac troponin C with myofibrils. This requirement can be satisfied by either site III or IV.     

Temperature-sensitive high affinity [3H]tryptamine binding sites in rat brain

The influence of prior incubation on [3H]tryptamine binding was investigated in rat brain synaptic plasma membranes. A 55 min preincubation of the membranes at 37 degrees C induced an approx. 2.4-fold increase in the specific binding of [3H]ligand to the subsequently washed preparations and this phenomenon was quite temperature-dependent. On the other hand, the proportion of nonspecific binding sites was significantly decreased by 70% of the original sites within 20 min of the start of preincubation. Pargyline, ascorbic acid, EGTA, metal ions (Ca2+, Mg2+, Na+) and guanine nucleotides, included in the preincubation buffer, were all inactive on the stimulation of [3H]tryptamine binding, while the pretreatment of membranes with glutaraldehyde antagonized the augmentation of this binding. Furthermore, it was revealed that the Scatchard plot of the [3H]tryptamine binding preincubated at 0 degree C conformed to a straight line (KD = 33.1 nM, Bmax = 543 fmoles/mg protein), whereas a curvilinear Scatchard plot was obtained at 37 degrees C preincubation. Nonlinear regression analysis of the latter resulted in apparent KD (nM) & Bmax (fmoles/mg protein) values of 0.45 & 102.7 and 33.7 & 603.4 for the high and low affinity sites, respectively. All these observations lead to the inference that the preincubation-induced increase in [3H]tryptamine binding (i.e., nearly high affinity proportion of sites) may occur as a result of temperature-sensitive interconvertible conformational changes.     

Cyclic GMP-specific, high affinity, noncatalytic binding sites on light-activated phosphodiesterase

Two classes of high affinity, cGMP-specific binding sites have been found in association with a peripheral membrane protein in rod outer segments. [3H]cGMP and a photoaffinity label, 8-N3-[32P]cIMP, have been used to study these cGMP binding sites. The cGMP binding sites co-migrated with rod outer segment phosphodiesterase (EC 3.1.4.17) upon Bio-Gel A-0.5m column chromatography, sucrose density gradient centrifugation, and isoelectric focusing (pI 5.35). Upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the 8-N3-[32P]cIMP-labeled protein also migrated in a position identical with that of purified phosphodiesterase. Scatchard analysis, using purified phosphodiesterase, revealed the presence of two classes of cGMP binding sites with apparent KD values of 0.16 and 0.83 microM. A number of observations indicated that these high affinity, cGMP-specific binding sites are distinct from the phosphodiesterase catalytic site. cAMP, which is a substrate for phosphodiesterase, did not bind to the high affinity cGMP specific sites. Limited tryptic proteolysis of phosphodiesterase resulted in a striking activation of the catalytic activity and a 96% loss of cGMP binding. 1-Methyl-3-isobutylxanthine inhibited phosphodiesterase activity and enhanced the specific binding of cGMP. Mg2+ was necessary for phosphodiesterase activity, but not for high affinity cGMP binding. Finally, phosphodiesterase activity and the cGMP-specific high affinity sites showed different stabilities on storage in phosphate buffer. These specific high affinity cGMP binding sites may be involved in the regulation of phosphodiesterase activity.     

Native genomic blotting: a novel approach to mapping DNase I hypersensitive sites and protein-DNA interactions at high resolution

We have developed a new high resolution method for screening 400-600 base pairs of DNA in chromatin for DNase I hypersensitive sites and protein-DNA interactions. By separating the DNA isolated from nuclease-digested nuclei in small, native polyacrylamide gels prior to electroblotting onto nylon membranes, we increased the resolution by greater than 3-fold as compared with the traditional approach whereby the nuclease-digested DNA is fractionated electrophoretically in agarose gels (11). In addition, our native genomic blotting method has the advantage of combining the ability of the traditional agarose approach to detect DNase I hypersensitive sites, with the genomic sequencing method (2), where individual protein-DNA contacts can be observed. Native genomic blotting therefore permits for the first time the display of DNase I hypersensitive sites and protein-DNA interactions at high resolution on the same autoradiograph. This method allows us to investigate a new level of chromatin structure and to therefore obtain better insight into levels of gene structure, organization and gene regulation.     

A novel protein domain induces high affinity selenocysteine insertion sequence binding and elongation factor recruitment

Selenocysteine (Sec) is incorporated at UGA codons in mRNAs possessing a Sec insertion sequence (SECIS) element in their 3'-untranslated region. At least three additional factors are necessary for Sec incorporation: SECIS-binding protein 2 (SBP2), Sec-tRNA(Sec), and a Sec-specific translation elongation factor (eEFSec). The C-terminal half of SBP2 is sufficient to promote Sec incorporation in vitro, which is carried out by the concerted action of a novel Sec incorporation domain and an L7Ae RNA-binding domain. Using alanine scanning mutagenesis, we show that two distinct regions of the Sec incorporation domain are required for Sec incorporation. Physical separation of the Sec incorporation and RNA-binding domains revealed that they are able to function in trans and established a novel role of the Sec incorporation domain in promoting SECIS and eEFSec binding to the SBP2 RNA-binding domain. We propose a model in which SECIS binding induces a conformational change in SBP2 that recruits eEFSec, which in concert with the Sec incorporation domain gains access to the ribosomal A site.     

Characterization of high affinity and low affinity dexamethasone binding sites on male rat liver nuclear envelopes

Steroids must traverse the nuclear envelope before exerting their action at the chromatin. However, few studies have been done to elucidate the mechanism by which steroids traverse this membrane barrier. As first steps towards investigating the mechanism, we have characterized the binding sites for dexamethasone on male rat liver nuclear envelopes. The nuclear envelopes, prepared in the presence of dithiothreitol, were isolated from purified nuclei after treatment with DNase 1 at high pH. Binding of dexamethasone to the nuclear envelopes was measured after 16 h of incubation at 0-4 degrees C. At pH 7.4, only a single high capacity, low affinity binding site for dexamethasone was identified. However, at pH 8.6, two sites were identified; a low capacity, high affinity site and a high capacity, low affinity site. Adrenalectomy of the animal before preparation of the membranes caused loss of the high affinity site and reduction in the number of the lower affinity sites. Acute dexamethasone treatment of adrenalectomized rats resulted in the reappearance of the high affinity site but long term treatment with dexamethasone was required for complete restoration of the high affinity sites and reappearance of any of the low affinity sites. The steroid specificity of these nuclear envelope binding sites was different from that of the cytosolic glucocorticoid receptor, generally showing broader specificity. However, triamcinolone acetonide, which is a potent competitor for binding to the glucocorticoid receptor, did not complete effectively. The binding sites were sensitive to protease treatment and salt extraction studies revealed that the dexamethasone binding sites do not represent proteins non-specifically bound to the nuclear envelope. The affinity and the hormone responsiveness of the high affinity site are similar to those of the nuclear glucocorticoid receptor. Therefore, the nuclear envelope may be a site of action of glucocorticoids.