Modification Interference Analysis Research Articles

Modification interference analysis of the ribosome.

RNAs are versatile molecules involved in myriad functions in the cell. To understand how a RNA molecule functions in the cell it is important to identify the nucleotides in the RNA molecule that are important for its structure and function. There are several biochemical methods such as footprinting, cross-linking, and modification interference analysis that can be used to study RNA-RNA and RNA-protein interactions. Ribosome is a classical example of a RNA-protein complex that has been extensively studied using these methods. Here, we describe a modification interference method that was used to identify bases in 16S rRNA that are important for the translocation of the mRNA-tRNA complex by the ribosome.

Protein–DNA interactions at theSulfolobusspindle-shaped virus-1 (SSV1) T5 and T6 gene promoters

Ultraviolet irradiation upregulates transcription from the Sulfolobus spindle-shaped virus 1 (SSV-1) T5, T(ind), and T6 genes promoters and also triggers viral DNA replication, but nothing is known about the proteins involved in this process. A notable feature of T5 and T6 promoters is that they contain 4 copies of a highly conserved DNA sequence 5'-ATAGATAGAGT-3'; 2 copies of this repeat are found in tandem upstream of the A-box, whereas 2 additional tandem copies span the initiator region from which transcription originates. By employing electrophoretic mobility gel-shift assays (EMSAs) and chemical modification interference analyses, I have identified a protein STRIP (SSV-1 T5/T6 region-interacting protein) in Sulfolobus shibatae extract that binds specifically to this sequence. Unique to S. shibatae, STRIP induces a 28 degrees bend in DNA. Surprisingly, despite the fact that STRIP binding masks the initiator region and can potentially interfere with preinitiation complex assembly, it does not appear to effect transcription driven from T5 and T6 promoters in vitro. Based on these results, I discuss the potential roles of STRIP in T5 and T6 transcription and in initiating SSV-1 DNA replication.

Structural and biochemical analyses of DNA and RNA binding by a bifunctional homing endonuclease and group I intron splicing factor.

We determined the crystal structure of a bifunctional group I intron splicing factor and homing endonuclease, termed the I-AniI maturase, in complex with its DNA target at 2.6 A resolution. The structure demonstrates the remarkable structural conservation of the beta-sheet DNA-binding motif between highly divergent enzyme subfamilies. DNA recognition by I-AniI was further studied using nucleoside deletion and DMS modification interference analyses. Correlation of these results with the crystal structure provides information on the relative importance of individual nucleotide contacts for DNA recognition. Alignment and modeling of two homologous maturases reveals conserved basic surface residues, distant from the DNA-binding surface, that might be involved in RNA binding. A point mutation that introduces a single negative charge in this region uncouples the maturase and endonuclease functions of the protein, inhibiting RNA binding and splicing while maintaining DNA binding and cleavage.

Analysis of interaction between RNA aptamer and protein using nucleotide analogs.

Non-structural protein 3 (NS3) derived from Hepatitis C virus (HCV) is essential for viral proliferation and has two functional domains; trypsin-like serine protease and helicase. Recently we obtained three types of RNA aptamers (G9-I, -II and -III) bound to NS3 protease domain (delta NS3) by in vitro selection and confirmed their strong inhibition for protease activity. These aptamers have a common sequence, 5'-GA(A/U)UGGGAC-3', forming a loop structure by Mulfold secondary structure modeling. G9-I shows a three-way junction and G9-II and -III have four-way junction structures. To characterize the active structure of these aptamers, we applied modification interference analysis using nucleotide analogs and identified common important nucleotides in these three aptamers.

RNA footprinting and modification interference analysis.

RNA footprinting and modification interference analysis.

RNA determinants of a specific RNA-Coat protein peptide interaction in alfalfa mosaic virus: conservation of homologous features in ilarvirus RNAs

Alfalfa mosaic virus (AMV) coat protein and tobacco streak virus (TSV) coat protein bind specifically to the 3′ untranslated regions of the viral RNAs and are required with the genomic RNAs to initiate virus replication. A combination of nucleotide substitutions, hydroxyl radical footprinting, and ethylation and chemical modification interference analysis has been used to define the RNA determinants important for the specific binding of the 3′-terminal 39 nucleotides of AMV RNA 3/4 (AMV 843–881) to an amino-terminal coat protein peptide (CP26). The results demonstrate that potential phosphate and base-specific contacts as well as ribose moieties protected upon peptide binding cluster in lower hairpin stems and flanking AUGC sequences of the viral RNA, without direct involvement of loop nucleotides. Nucleotides identified in the modification-interference analyses as important for RNA-protein interactions are highly conserved among AMV and the ilarvirus RNAs. This RNA sequence homology, coupled with the recent identification of an RNA binding consensus sequence for AMV and ilarvirus coat proteins, provides a framework for understanding the functional equivalence of AMV and TSV coat proteins in binding RNA and activating virus replication and may explain why heterologous AMV and ilarvirus coat protein-RNA mixtures are infectious.

Interaction of the Bacillus stearothermophilusRibosomal Protein S15 with 16 S rRNA: II. Specificity Determinants of RNA-Protein Recognition

S15 is a primary ribosomal protein that interacts specifically with a three-way junction in the central domain of 16 S rRNA, whose binding induces a conformational change in the RNA. In the accompanying paper, we demonstrated that S15 binds with high affinity to a 61 nucleotide RNA corresponding to the minimal rRNA binding site. Here, the sequence and structural determinants for the RNA in the Bacillus stearothermophilusS15-rRNA interaction have been probed using site-directed mutagenesis, chemical modification interference, and iodine footprinting of phospho rothioate RNA. Mutations and RNA modifications that interfere with protein binding cluster in two distinct regions, one containing an internal loop and the other containing a three-way junction. The internal loop, defined by two A·G base-pairs and a bulged guanosine, is not important for the specific interaction, however, BS15 interacts with a phylogenetically conserved G·U base-pair above this internal loop. Near the three-way junction in helix 22, a bulged adenosine and two base-pairs adjacent to the junction also provide important determinants for BS15 binding. Chemical modification interference also suggests that four highly phylogenetically conserved nucleotides in the three-way junction may form non-canonical G·G and U·A base-pairs that are required for the BS15-rRNA interaction. Ethylation modification interference suggests that BS15 binding is accompanied by a conformational change in the RNA involving orientation of helices 20 and 22 at an acute angle with respect to one another. Projection of the data provided by mutagenesis, chemical modification interference analysis, and iodine footprinting onto a three-dimensional model illustrates that BS15 is likely to interact with the minor groove along an extended face of helix 22.

E-Box Variants Direct Formation of Distinct Complexes with the Basic Helix-Loop-Helix Protein ALF1

The murine transcription factor ALF1 belongs to the class of basic helix-loop-helix proteins specific for the NCAGNTGN-version of the E-box. Binding of homodimeric ALF1 to variants of this motif was studied by a combination of binding site selection technology and DNA modification interference analysis. The results showed that substitutions at the non-conserved positions in the E-box sequence could cause profound alterations in the patterns of specific contacts at the protein-DNA interface. Thus, both the overall extent of the binding region and the backbone phosphate contact pattern differed markedly between closely related E-boxes with similar affinities for ALF1. The identity of the base at the inner N was an important determinant of contact pattern specification. The E-box variants differed in their ability to mediate ALF1 dependent transcriptional activationin vivo. We discuss the possibility that adaptability in basic helix-loop-helix protein-DNA interactions can result in complexes with different functional properties.

Sequence-specific binding of the influenza virus RNA polymerase to sequences located at the 5' ends of the viral RNAs.

The enzymatic activity of recombinant influenza virus RNA polymerase is strictly dependent on the addition of a template RNA containing 5' and 3' viral sequences. Here we report the analysis of the binding specificity and physical characterization of the complex by using gel shift, modification interference, and density gradient techniques. The 13S complex binds specifically to short synthetic RNAs that mimic the partially double stranded panhandle structures found at the termini of both viral RNA and cRNA. The polymerase will also bind independently to the single-stranded 5' or 3' ends of viral RNA. It binds most strongly to specific sequences within the 5' end but is unable to bind these sequences in the context of a completely double stranded structure. Modification interference analysis identified the short sequence motifs at the 5' ends of the viral RNA and cRNA templates that are critical for binding.

Purification and characterization of a mitochondrial DNA-binding protein that binds to double-stranded and single-stranded sequences of Paracentrotus lividus mitochondrial DNA.

A mitochondrial protein, able to specifically bind two double-stranded homologous sequences of sea-urchin mitochondrial DNA, has been partially purified from Paracentrotus lividus eggs. This protein, present at a low concentration, is a polypeptide of 40 kDa. One of the binding sequences, located in the main non-coding region, contains the replication origin of the mitochondrial DNA H-strand. By a combination of band-shift, DNase footprinting, and modification interference analyses with homologous and heterologous probes we identified YCYYATCAN(A/T)RC as the minimum sequence required for the binding. The protein also shows a single-stranded DNA-binding activity, as it is able to specifically interact with one of the strands of the binding sites. These features are consistent with a function of the protein in the modulation of sea-urchin mitochondrial DNA replication during the development stages.

Two distinct, sequence-specific DNA-binding proteins interact independently with the major replication pause region of sea urchin mtDNA.

We have identified a second DNA-binding protein in sea urchin embryo mitochondria, which interacts with a binding site in the major replication pause region, at the junction of the genes for ATP synthase subunit 6 and cytochrome c oxidase subunit III (COIII). We provisionally designate this protein mtPBP2, to distinguish it from the previously characterized mitochondrial pause-region binding protein mtPBP1, whose properties and binding site are quite distinct. The high-affinity binding site for mtPBP2 lies at the 5' end of the COIII gene, and exhibits partial dyad symmetry, although modification interference analysis indicates that recognition is complex. Binding of mtPBP2 to this site induces a bend of approximately 45 degrees in the DNA. Southwestern blots show that mtPBP1 and 2 are both single polypeptides, of apparent molecular weights 25 kD and 18 kD respectively. In vitro, mtPBP1 and mtPBP2 bind independently to their high-affinity sites, which are separated by about 50 bp.

Characterization of a high-affinity binding site for a DNA-binding protein from sea urchin embryo mitochondria.

Based on electrophoretic mobility shift assays, DNase I footprinting and modification interference analyses we have identified a sequence-specific DNA-binding protein in blastula stage mitochondria of the sea urchin Strongylocentrotus purpuratus, which interacts with a binding site around the major pause site for DNA replication. This region straddles the boundary of the genes for ATP synthase subunit 6 and cytochrome c oxidase subunit III, and contains also a prominent origin of lagging-strand synthesis. The protein is thermostable, and its natural high-affinity binding site comprises the sequence 5'-AGCCT(N7)AGCAT-3'. Binding studies have demonstrated that two copies of the imperfect repeat, as well as the 7 bp spacing between them, are essential for tight binding. Based on the location of its binding site, we tentatively designate the protein mitochondrial pause-region binding protein (mtPBP) 1.

Modification interference analysis of a self-cleaving RNA from hepatitis delta virus.

A chemical modification-interference assay was used to evaluate the sequence requirements for self-cleavage of a 73-nucleotide self-cleaving RNA from the genomic hepatitis delta virus (HDV). Twenty-two nucleotides were categorized as individually essential for self-cleavage, shown by loss of activity when modified. All of these required nucleotides fell within 38 nucleotides downstream of the cleavage site, suggesting an essential structural or functional role for this region. Lesser effects were seen for nucleotides further 3' of the cleavage site, and a small number of nucleotides had a negligible effect on the extent of self-cleavage when modified. Several modifications increased the extent of self-cleavage, suggesting these nucleotides may act to inhibit the reaction when unmodified. The functional requirements for certain nucleotides are discussed in the light of structural probing data and conventional mutational analysis available for other HDV RNAs.

Interaction of U6 snRNA with a sequence required for function of the nematode SL RNA in trans-splicing.

Nematode trans-spliced leader (SL) RNAs are composed of two domains, an exon [the 22-nucleotide spliced leader] and a small nuclear RNA (snRNA)-like sequence. Participation in vitro of the spliced leader RNA in trans-splicing reactions is independent of the exon sequence or size and instead depends on features contained in the snRNA-like domain of the molecule. Chemical modification interference analysis has revealed that two short sequence elements in the snRNA-like domain are necessary for SL RNA activity. These elements are sufficient for such activity because when added to a 72-nucleotide fragment of a nematode U1 snRNA, this hybrid RNA could participate in trans-splicing reactions in vitro. One of the critical sequence elements may function by base-pairing with U6 snRNA, an essential U snRNA for both cis- and trans-splicing.

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.

OBP100 binds remarkably degenerate octamer motifs through specific interactions with flanking sequences.

We have used the 100-kD HeLa cell octamer-binding protein OBP100 as a model to study flexible DNA sequence recognition by promoter-binding proteins. OBP100 binds to the conserved octamer motif ATGCAAAT found in numerous promoters and additionally to two degenerate octamer motifs (sites I and II) within the SV40 enhancer region. We show here that OBP100 binds the herpes simplex virus immediate early promoter TAATGARAT (R = purine) motif itself, extending the flexibility of OBP100 sequence recognition to sequences that bear very little resemblance (four matches over a 14-bp region). Nevertheless, a progression of OBP100-binding sites can be established that links the sequences of these two apparently unrelated binding sites by incremental steps. Mutational and chemical modification interference analyses of a degenerate octamer binding site (SV40 site II) show that specific sequences, which are not normally conserved but flank the degenerate octamer motif, can compensate for the degeneracy in the octamer core sequence. Thus, different regions of the binding site sequence (core or flanking) can diverge separately but not independently of one another. These results suggest that flexible DNA sequence recognition arises because there are few obligatory contact sites for OBP100 binding, but, rather, specific binding reflects the sum of many independent interactions.