Photochemical Cross-linking Experiments Research Articles

Identification of PDGF-BB binding to thymosin β4 by chemical cross-linking

Introduction: The purpose of our work was to identify unknown interaction partners of thymosin β4 (Tβ4). It was suggested that Tβ4 could be an antifibrotic drug for treatment of liver fibrogenesis, because Tβ4 prevents the platelet-derived growth factor-BB (PDGF-BB)-induced activation of hepatic stellate cells (HSCs). Very little information is available how Tβ4 counteracts the PDGF-BB-induced activation of HSCs. We propose the hypothesis that Tβ4 could bind directly to PDGF-BB and thereby reduce the concentration of free PDGF-BB available for binding to the PDGF-β receptor.Methods: To prove our suggestion of a direct interaction between Tβ4 and PDGF-BB, we carried out chemical as well as photochemical cross-linking experiments between the two pure proteins in vitro.Results: We identified an interaction between Tβ4 and PDGF-BB by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) cross-linking as well as through biotin label transfer using a bifunctional photoactivatable derivative of Tβ4. In an in vitro system, PDGF-BB was identified as the first extracellular partner interacting with Tβ4. This interaction could influence PDGF-BB binding to its receptor and abolish PDGF-BB-related effects.Conclusion: Direct interaction of Tβ4 with extracellular factors should be considered as a potential mechanism to explain the pleiotropic effects of β-thymosins.

Molecular basis of TRAP–5′SL RNA interaction in the Bacillus subtilis trp operon transcription attenuation mechanism

Expression of the Bacillus subtilis trpEDCFBA operon is regulated by the interaction of tryptophan-activated TRAP with 11 (G/U)AG trinucleotide repeats that lie in the leader region of the nascent trp transcript. Bound TRAP prevents folding of an antiterminator structure and favors formation of an overlapping intrinsic terminator hairpin upstream of the trp operon structural genes. A 5'-stem-loop (5'SL) structure that forms just upstream of the triplet repeat region increases the affinity of TRAP-trp RNA interaction, thereby increasing the efficiency of transcription termination. Single-stranded nucleotides in the internal loop and in the hairpin loop of the 5'SL are important for TRAP binding. We show here that altering the distance between these two loops suggests that G7, A8, and A9 from the internal loop and A19 and G20 from the hairpin loop constitute two structurally discrete TRAP-binding regions. Photochemical cross-linking experiments also show that the hairpin loop of the 5'SL is in close proximity to the flexible loop region of TRAP during TRAP-5'SL interaction. The dimensions of B. subtilis TRAP and of a three-dimensional model of the 5'SL generated using the MC-Sym and MC-Fold pipeline imply that the 5'SL binds the protein in an orientation where the helical axis of the 5'SL is perpendicular to the plane of TRAP. This interaction not only increases the affinity of TRAP-trp leader RNA interaction, but also orients the downstream triplet repeats for interaction with the 11 KKR motifs that lie on TRAP's perimeter, increasing the likelihood that TRAP will bind in time to promote termination.

Archaeal Transcription: Function of an Alternative Transcription Factor B from Pyrococcus furiosus

The genome of the hyperthermophile archaeon Pyrococcus furiosus encodes two transcription factor B (TFB) paralogs, one of which (TFB1) was previously characterized in transcription initiation. The second TFB (TFB2) is unusual in that it lacks recognizable homology to the archaeal TFB/eukaryotic TFIIB B-finger motif. TFB2 functions poorly in promoter-dependent transcription initiation, but photochemical cross-linking experiments indicated that the orientation and occupancy of transcription complexes formed with TFB2 at the strong gdh promoter are similar to the orientation and occupancy of transcription complexes formed with TFB1. Initiation complexes formed by TFB2 display a promoter opening defect that can be bypassed with a preformed transcription bubble, suggesting a mechanism to explain the low TFB2 transcription activity. Domain swaps between TFB1 and TFB2 showed that the low activity of TFB2 is determined mainly by its N terminus. The low activity of TFB2 in promoter opening and transcription can be partially relieved by transcription factor E (TFE). The results indicate that the TFB N-terminal region, containing conserved Zn ribbon and B-finger motifs, is important in promoter opening and that TFE can compensate for defects in the N terminus through enhancement of promoter opening.

Model for General Acid−Base Catalysis by the Hammerhead Ribozyme: pH−Activity Relationships of G8 and G12 Variants at the Putative Active Site

We have used nucleobase substitution and kinetic analysis to test the hypothesis that hammerhead catalysis occurs by a general acid-base mechanism, in which nucleobases are directly involved in deprotonation of the attacking 2'-hydroxyl group and protonation of the 5'-oxygen that serves as the leaving group in the cleavage reaction. We demonstrate that simultaneous substitution of two important nucleobases, G8 and G12, with 2,6-diaminopurine shifts the pH optimum of the cleavage reaction from greater than 9.5 to approximately 6.8 in two different hammerhead constructs. Controls involving substitution with other nucleobases and combinations of nucleobases at G5, G8, and/or G12 do not show this behavior. The observed changes in the pH-rate behavior are consistent with a mechanism in which N1 protonation-deprotonation events of guanine or 2,6-diaminopurine at positions 8 and 12 are essential for catalysis. Further support for the participation of G8 and G12 comes from photochemical cross-linking experiments, which show that G8 and G12 can stack upon the two substrate nucleobases at the reactive linkage, G(or U)1.1 and C17 (Heckman, J. E., Lambert, D., and Burke, J. M. (2005) Photocrosslinking detects a compact active structure of the hammerhead ribozyme, Biochemistry 44, 4148-4156). Together, these results support a model in which the hammerhead undergoes a transient conformational change into a catalytically active structure, in which stacking of G8 and G12 upon the nucleobases spanning the cleavage site provides an appropriate architecture for general acid-base catalysis. The hammerhead and hairpin ribozymes may share similarities in the organization of their active sites and their catalytic mechanism.

Characterization of the biologically important interaction between troponin C and the N-terminal region of troponin I.

The N-terminal regulatory region of Troponin I, residues 1-40 (TnI 1-40, regulatory peptide) has been shown to have a biologically important function in the interactions of troponin I and troponin C. Truncated analogs corresponding to shorter versions of the N-terminal region (1-30, 1-28, 1-26) were synthesized by solid-phase methodology. Our results indicate that residues 1-30 of TnI comprises the minimum sequence to retain full biological activity as measured in the acto-S1-TM ATPase assay. Binding of the TnI N-terminal regulatory peptides (TnI 1-30 and the N-terminal regulatory peptide (residues 1-40) labeled with the photoprobe benzoylbenzoyl group, BBRp) were studied by gel electrophoresis and photochemical cross-linking experiments under various conditions. Fluorescence titrations of TnI 1-30 were carried out with TnC mutants that carry a single tryptophan fluorescence probe in either the N- or C-domain (F105W, F105W/C domain (88-162), F29W and F29W/N domain (1-90)) (Fig. 1). Low Kd values (Kd < 10(-7) M) were obtained for the interaction of F105W and F105W/C domain (88-162) with TnI 1-30. However, there was no observable change in fluorescence when the fluorescence probe was located at the N-domain of the TnC mutant (F29W and F29W/N domain (1-90)). These results show that the regulatory peptide binds strongly to the C-terminal domain of TnC.

Effects of bicyclomycin on RNA- and ATP-binding activities of transcription termination factor Rho.

Bicyclomycin is a commercially important antibiotic that has been shown to be effective against many gram-negative bacteria. Genetic and biochemical evidence indicates that the antibiotic interferes with RNA metabolism in Escherichia coli by inhibiting the activity of transcription termination factor Rho. However, the precise mechanism of inhibition is not completely known. In this study we have used in vitro transcription assays to analyze the effects of bicyclomycin on the termination step of transcription. The Rho-dependent transcription termination region located within the hisG cistron of Salmonella typhimurium has been used as an experimental system. The possible interference of the antibiotic with the various functions of factor Rho, such as RNA binding at the primary site, ATP binding, and hexamer formation, has been investigated by RNA gel mobility shift, photochemical cross-linking, and gel filtration experiments. The results of these studies demonstrate that bicyclomycin does not interfere with the binding of Rho to the loading site on nascent RNA. Binding of the factor to ATP is not impeded, on the contrary, the antibiotic appears to decrease the apparent equilibrium dissociation constant for ATP in photochemical cross-linking experiments. The available evidence suggests that this decrease might be due to an interference with the correct positioning of ATP within the nucleotide-binding pocket leading b an inherent block of ATP hydrolysis. Possibly, as a consequence of this interference, the antibiotic also prevents ATP-dependent stabilization of Rho hexamers.

Isolation and characterization of replication protein A (RP-A) from tobacco cells

Replication protein A (RP-A) was isolated from tobacco suspension cells and purified to near homogeneity by a procedure involving isolation of protoplasts, preparation of nuclei, nuclear lysis, binding to a column of single-stranded (ss) DNA cellulose and elution at different salt concentrations. The purified protein contained three subunits with molecular masses of 70, 34 and 14 kDa, and was free from nuclease activity. Tobacco RP-A had a high affinity for ssDNA. Binding competition experiments indicated only a weak affinity for double-stranded DNA and no detectable affinity for ssRNA. Photochemical cross-linking experiments indicated that the 70 kDa subunit has the ssDNA-binding activity. Tobacco RP-A was able to stimulate the activity of a tobacco α-like DNA polymerase about 4-fold. This is the first isolation of RP-A from a plant and the procedure may be generally applicable to other plant species.

Translational termination efficiency in both bacteria and mammals is regulated by the base following the stop codon.

The translational stop signal and polypeptide release factor (RF) complexed with Escherichia coli ribosomes have been shown to be in close physical contact by site-directed photochemical cross-linking experiments. The RF has a protease-sensitive site in a highly conserved exposed loop that is proposed to interact with the peptidyltransferase center of the ribosome. Loss of peptidyl-tRNA hydrolysis activity and enhanced codon-ribosome binding by the cleaved RF is consistent with a model whereby the RF spans the decoding and peptidyltransferase centers of the ribosome with domains of the RF linked by conformational coupling. The cross-link between the stop signal and RF at the ribosomal decoding site is influenced by the base following the termination codon. This base determines the efficiency with which the stop signal is decoded by the RF in both mammalian and bacterial systems in vivo. The wide range of efficiencies correlates with the frequency with which the signals occur at natural termination sites, with rarely used weak signals often found at recoding sites and strong signals found in highly expressed genes. Stop signals are found at some recoding sites in viruses where -1 frame-shifting occurs, but the generally accepted mechanism of simultaneous slippage from the A and P sites does not explain their presence here. The HIV-1 gag-pol-1 frame shifting site has been used to show that stop signals significantly influence frame-shifting efficiency on prokaryotic ribosomes by a RF-mediated mechanism. These data can be explained by an E/P site simultaneous slippage mechanism whereby the stop codon actually enters the ribosomal A site and can influence the event.

A silencer element for the lipoprotein lipase gene promoter and cognate double- and single-stranded DNA-binding proteins.

Transfection experiments with constructs containing various 5'-deleted fragments of the human lipoprotein lipase (LPL) promoter and the chloramphenicol acetyltransferase reporter gene revealed an LPL silencer element (LSE) in the region of nucleotides -225 to -81 of the LPL gene that functioned in Chinese hamster ovary (CHO) and HeLa cells. Gel retardation competition analysis showed the presence of a nuclear factor(s) capable of binding to the sequence of nucleotides -169 to -152 of LSE (LSE-6) in a single-stranded (opposite-strand) and double-stranded specific fashion, the binding affinity being almost the same in the two binding forms. Site-directed mutagenesis indicated that almost the entire sequence of LSE-6 was necessary to form the complexes and also critical for silencing activity in CHO cells. The amounts of this binding factor(s) in CHO and HeLa cells were closely associated with transcriptional silencing activity. Photochemical cross-linking experiments indicated that the single- and double-stranded elements recognized the same binding factor(s) with molecular masses of 54 to 63 kDa and 109 to 124 kDa. The 109- to 124-kDa DNA binding factor(s) was found to be a doublet of that of the 54- to 63-kDa factor by isoelectric focusing or by increasing the time of exposure to UV irradiation. When inserted upstream of another gene such as that of the simian virus 40 enhancer/promoter of pSV2CAT, the sequence of nucleotides -190 to -143 (LSE-1) also suppressed transcription of the reporter gene in CHO cells. These results strongly suggest that the LSE plays a role in regulation of LPL gene expression by suppressing its transcription.

Direct recognition of mRNA stop signals by Escherichia coli polypeptide chain release factor two

The interaction between the translational stop signal and the polypeptide chain release factor protein (RF) within complexes of Escherichia coli ribosomes has been investigated by site-directed photochemical cross-linking experiments. Twelve mRNA analogues containing 4-thiouridine residues as part of stop signals were synthesized. Highly efficient cross-linking to RF-2 from 4-thiouridine (sU) residues of sUGAN-containing mRNAs was observed, and cross-linking from those of sUAAN was observed at a lower efficiency. This indicates that RF-2 is in close physical contact with the stop signal on the ribosome. The yield of the RF-2-mRNA cross-link depended on the identity of the fourth base for the sUGAN set of signals, suggesting that the fourth base of the stop signal affects the interaction between RF-2 and the stop codon. A region previously implicated as part of the decoding site of the small ribosomal subunit, 1385-1420 of the 16 S rRNA, was also cross-linked with these mRNAs. No new cross-links were obtained in the presence of the release factor. The data are consistent with models in which the RF has an anticodon-like domain that contacts the stop signal directly at or near the ribosomal site in which sense codons are decoded.

Crosslinking of mRNA Analogs Containing 4-Thiouridine Residues on the 3'- or 5'-Side of the Coding Triplet to the mRNA Binding Center of the Human Ribosome

The interaction between mRNA and 18S rRNA within complexes of human placenta 80S ribosomes has been investigated by photochemical cross-linking experiments using mRNA analogues substituted with 4-thiouridine at specific locations. mRNA analogues 51 or 54 nucleotides long were prepared from synthetic DNA templates. These mRNA analogues contained either the sequence GGGACC (coding for glycine and threonine, respectively) or the single triplet GGG together with 2-4 4-thiouridine residues located at various positions with respect to the coding triplets. The products of cross-linking of the mRNA analogues to 18S rRNA within different model complexes without tRNA or in the presence of cognate tRNAs were analyzed by reverse transcription. Two cross-linking sites in the 18S rRNA were detected. The first site, U630, was cross-linked by mRNA 8' (s4U at +20, +22, +24, and +26), mRNA 9e' (s4U at -16, -18, and -20), and mRNA 10 (s4U at +4, +6, -1, and -3) but, unexpectedly, not with either mRNA 10b (s4U at +4 and +6) or mRNA 10c (s4U at -1 and -3). The second site, U1111/A1112, was cross-linked by mRNA 10 and mRNA 10c but not by any of the other mRNA analogues. There is significant tRNA dependence on cross-linking only for mRNA analogue 9e'. Both of the sites detected correspond to sites of mRNA cross-linking in Escherichia coli 16S rRNA.

Arrangement of messenger RNA on Escherichia coli ribosomes with respect to 10 16S rRNA cross-linking sites.

The arrangement of the mRNA on the Escherichia coli ribosome with respect to ribosomal RNA sites has been investigated by photochemical cross-linking experiments. mRNA analogues 51-54 nucleotides in length contained a Shine-Dalgarno sequence, a single codon for tRNA(Gly), and 4-thiouridine (s4U) in the 5' third of the mRNA (-20 to -12), in the middle third of the mRNA (-3 to +6), or in the 3' third of the mRNA (+20 to +26), where the position numbers are counted from the first nucleotide of the codon. Complexes were formed with these mRNAs and 70S ribosomes in the absence or presence of tRNA(Gly) and were irradiated. The extent of cross-linking and the identity of cross-linked rRNA sites were determined on agarose gels and by primer extension. 16S rRNA nucleotides A412, A532, G693 (weakly), U723, and U1381 (weakly) cross-linked with s4U in the 3' third; A532, G693, U723, A1167 (weakly), U1381, G818 (weakly), and A845 cross-linked with s4U in the middle; A532, G693, U723, A1167, G818 (weakly), and A845 cross-linked with s4U in the 5' third. All of these cross-links occur with tRNA independence. Cross-links at C1395 and A1196 occur for all three mRNAs with tRNA dependence. The pattern of these sites provides information about the order of the rRNA sites along the mRNA track, and they also point out the apparent overlapping neighborhoods for the mRNA track. Models for the track of the mRNA on the 30S subunit are considered to explain this pattern of interactions.

Regulation of rat glutathione S-transferase Ya subunit gene expression. DNA-protein interaction at the antioxidant responsive element.

We have characterized the interaction of the antioxidant responsive element (ARE) in the 5'-flanking region of the rat glutathione S-transferase Ya subunit gene with its trans-acting factor. The ARE core sequence, 5'-ggTGACaaaGC-3', previously identified as the cis-acting element required for activation of the Ya subunit gene by planar aromatic compounds and phenolic antioxidants, is shown to be the high affinity recognition motif for a trans-acting factor(s) as determined by gel mobility shift assays as well as methylation interference and protection studies. The DNA-protein interaction appears to occur in the major groove and involves the GpG dinucleotide preceding and the G residue within the TGAC tetramer on the coding strand of the core sequence. In addition, DNase I protection analysis maps an extended region 5' from the core recognition motif, which was shown previously to be essential for basal activity of the ARE. The trans-acting factor is present in nuclear extracts from untreated and tert-butylhydroquinone-treated cells as determined by photochemical cross-linking experiments. The cross-linked protein appears to be a heterodimer with subunit molecular weights of approximately 28,000 and approximately 45,000.

The mRNA binding track in the Escherichia coli ribosome for mRNAs of different sequences.

Interactions between mRNA and rRNA on the 30S ribosomal subunit or 70S ribosome have been determined by photochemical cross-linking experiments using synthetic mRNA analogs substituted with 4-thiouridine. A set of RNA molecules containing different sequences has been used to determine the extent to which binding contacts are sequence dependent. The 16S rRNA and 23S rRNA nucleotides that form a part of the binding site have been identified by reverse transcription. The nucleotides are U1381, G1338, G1300, G1156, A845, U723, G693, A532, G497, U420, G413/A412, and G436 of 16S rRNA and U887 of 23S rRNA. Several additional nucleotides (U1065 of 23S rRNA and A1227, G818, G524, and G423 of 16S rRNA) are seen for some, but not all, of the mRNAs. Results obtained with two mRNAs containing the Shine-Dalgarno sequence were similar to those obtained with mRNAs lacking the Shine-Dalgarno sequence. Eight of these cross-linking sites were also seen when a mixture of RNA was used in which there are 12 random nucleotides preceding and seven random nucleotides succeeding an AUG codon. These results indicate that to a large extent placement of the mRNA in the ribosome does not depend upon its primary sequence.

Common double- and single-stranded DNA binding factor for a sterol regulatory element.

A cis-acting element necessary for sterol regulation, SRE-1, has previously been identified in the promoters of the low density lipoprotein receptor, hydroxymethylglutaryl (HMG)-CoA reductase, and HMG-CoA synthase genes. In this report we describe a nuclear factor, SRE-BF, isolated from Chinese hamster ovary nuclear extracts, that binds to the SRE-1 octanucleotide sequence. In addition to sequence-specific binding to SRE-1, as indicated by competition analysis with double-stranded DNA fragments, single-stranded oligomer DNA sequences also compete for binding in a sequence-specific fashion. Photochemical cross-linking experiments suggest that a common protein factor, with apparent molecular mass of 45-49 kDa, recognizes both single-stranded and double-stranded SRE-1. The binding specificity of SRE-BF to single-stranded SRE-1 closely correlates with the reported in vivo ability of SRE-1 to direct sterol responsiveness of transcription.

Sites of contact of mRNA with 16S rRNA and 23S rRNA in the Escherichia coli ribosome

The locations of close encounter between ribosomal RNA (rRNA) and messenger RNA (mRNA) were determined by photochemical cross-linking experiments that employ an artificial mRNA, 51 nucleotides long, containing 14 U residues that were randomly substituted by 1-4 4-thiouridine (s4U) residues. The mRNA was bound to 70S ribosomes or 30S subunits and then was irradiated at 366 nm to activate cross-linking between the s4U residues and rRNA. Cross-linking occurred to both 16S rRNA and 23S RNA. The rRNA was then analyzed by a series of reverse transcriptase experiments to determine the locations of cross-linking. Twelve sites in the 16S rRNA and two sites in the 23S rRNA have been detected. In the 16S rRNA, two of the sites (U1381, C1395) are in the middle part of the secondary structure close to position C1400, and the remaining sites (G413, U421, G424; A532; G693; U723; A845; G1131/C1132; G1300; G1338) are distributed between six regions that are peripheral in the secondary structure. In the 23S rRNA, one site (U1065) is located in the GTPase center close to A1067, the site of thiostrepton-resistance methylation in domain II, and the other site (U887) is located a short distance away also in domain II. The distribution of these rRNA sites in the ribosome specifies an mRNA track that is consistent with other information. In addition, some of the contact points represent new constraints for the three-dimensional folding of the rRNA.

Constitutive transcription of yeast ribosomal protein gene TCM1 is promoted by uncommon cis- and trans-acting elements.

The DNA sequence UAST (TCGTTTTGTACGTTTTTCA) was found to mediate transcription of yeast ribosomal protein gene TCM1. UAST was defined as a transcriptional activator on the basis of loss of transcription accompanying deletions of all or part of UAST, orientation-independent restoration of transcription promoted by a synthetic UAST oligomer inserted either into TCM1 or into the yeast CYC1 gene lacking its transcriptional activation region, and diminished transcription following nucleotide alterations in UAST. UAST bound in vitro to a protein denoted TAF (TCM1 activation factor); TAF was concluded to be a transcriptional activator protein because nucleotide alterations in UAST that diminished transcription in vivo also diminished TAF binding in vitro. The sequence of UAST bore no obvious resemblance to UASrpg, the principal cis-acting element common to most yeast ribosomal protein genes. Likewise, TAF was distinguished from the UASrpg-binding protein TUF, since (i) TAF and TUF were chromatographically separable, (ii) binding of either TAF or TUF to its corresponding UAS was unaffected by an excess of UASrpg or UAST DNA, respectively, and (iii) photochemical cross-linking experiments showed that TAF was a protein of 147 kilodaltons (kDa), while TUF was detected as an approximately 120-kDa polypeptide, consistent with its known size. Cross-linking experiments also revealed that both UAST and UASrpg bound a second heretofore unobserved 82-kDa protein; binding of this additional protein appeared to require binding of TAF or TUF. On the basis of the biochemical characterization of TAF and a lack of sequence similarity between UAST and UASrpg, we suggest that transcription of TCM1 is mediated by a cis-acting sequence and at least one trans-acting factor different from the elements which promote transcription of most other ribosomal protein genes. A second trans-acting factor may be shared by TCM1 and other ribosomal protein genes; this factor could mediate coordinate regulation of these genes.

Constitutive transcription of yeast ribosomal protein gene TCM1 is promoted by uncommon cis- and trans-acting elements.

The DNA sequence UAST (TCGTTTTGTACGTTTTTCA) was found to mediate transcription of yeast ribosomal protein gene TCM1. UAST was defined as a transcriptional activator on the basis of loss of transcription accompanying deletions of all or part of UAST, orientation-independent restoration of transcription promoted by a synthetic UAST oligomer inserted either into TCM1 or into the yeast CYC1 gene lacking its transcriptional activation region, and diminished transcription following nucleotide alterations in UAST. UAST bound in vitro to a protein denoted TAF (TCM1 activation factor); TAF was concluded to be a transcriptional activator protein because nucleotide alterations in UAST that diminished transcription in vivo also diminished TAF binding in vitro. The sequence of UAST bore no obvious resemblance to UASrpg, the principal cis-acting element common to most yeast ribosomal protein genes. Likewise, TAF was distinguished from the UASrpg-binding protein TUF, since (i) TAF and TUF were chromatographically separable, (ii) binding of either TAF or TUF to its corresponding UAS was unaffected by an excess of UASrpg or UAST DNA, respectively, and (iii) photochemical cross-linking experiments showed that TAF was a protein of 147 kilodaltons (kDa), while TUF was detected as an approximately 120-kDa polypeptide, consistent with its known size. Cross-linking experiments also revealed that both UAST and UASrpg bound a second heretofore unobserved 82-kDa protein; binding of this additional protein appeared to require binding of TAF or TUF. On the basis of the biochemical characterization of TAF and a lack of sequence similarity between UAST and UASrpg, we suggest that transcription of TCM1 is mediated by a cis-acting sequence and at least one trans-acting factor different from the elements which promote transcription of most other ribosomal protein genes. A second trans-acting factor may be shared by TCM1 and other ribosomal protein genes; this factor could mediate coordinate regulation of these genes.