The investigation of nucleic acid secondary structure by means of chemical modification with a carbodiimide reagent. I. The reaction between N-cyclohexyl-N'-beta-(4-methylmorpholinium)ethylcarbodiimide and model nucleotides

RNA Chemical Labeling with Site-Specific, Relative Quantification by Mass Spectrometry for the Structural Study of a Neomycin-Sensing Riboswitch Aptamer Domain

High-resolution mass spectrometry was used for the label-free, direct localization and relative quantification of CMC+ -modifications of a neomycin-sensing riboswitch aptamer domain in the absence and presence of the aminoglycoside ligands neomycin B, ribostamycin, and paromomycin. The chemical probing and MS data for the free riboswitch show high exposure to solvent of the uridine nucleobases U7, U8, U13, U14, U18 as part of the proposed internal and apical loops, but those of U10 and U21 as part of the proposed internal loop were found to be far less exposed than expected. Thus, our data are in better agreement with the proposed secondary structure of the riboswitch in complexes with aminoglycosides than with that of free RNA. For the riboswitch in complexes with neomycin B, ribostamycin, and paromomycin, we found highly similar CMC+ -modification patterns and excellent agreement with previous NMR studies. Differences between the chemical probing and MS data in the absence and presence of the aminoglycoside ligands were quantitative rather than qualitative (i. e., the same nucleobases were labeled, but to different extents) and can be rationalized by stabilization of both the proposed bulge and the apical loop by aminoglycoside binding. Our study shows that chemical probing and mass spectrometry can provide important structural information and complement other techniques such as NMR spectroscopy.

Structural characterization of a new subclass of panicum mosaic virus-like 3' cap-independent translation enhancer

Canonical eukaryotic mRNA translation requires 5'cap recognition by initiation factor 4E (eIF4E). In contrast, many positive-strand RNA virus genomes lack a 5'cap and promote translation by non-canonical mechanisms. Among plant viruses, PTEs are a major class of cap-independent translation enhancers located in/near the 3'UTR that recruit eIF4E to greatly enhance viral translation. Previous work proposed a single form of PTE characterized by a Y-shaped secondary structure with two terminal stem-loops (SL1 and SL2) atop a supporting stem containing a large, G-rich asymmetric loop that forms an essential pseudoknot (PK) involving C/U residues located between SL1 and SL2. We found that PTEs with less than three consecutive cytidylates available for PK formation have an upstream stem-loop that forms a kissing loop interaction with the apical loop of SL2, important for formation/stabilization of PK. PKs found in both subclasses of PTE assume a specific conformation with a hyperreactive guanylate (G*) in SHAPE structure probing, previously found critical for binding eIF4E. While PTE PKs were proposed to be formed by Watson-Crick base-pairing, alternative chemical probing and 3D modeling indicate that the Watson-Crick faces of G* and an adjacent guanylate have high solvent accessibilities. Thus, PTE PKs are likely composed primarily of non-canonical interactions.

RNA Regulations and Functions Decoded by Transcriptome-wide RNA Structure Probing

RNA folds into intricate structures that are crucial for its functions and regulations. To date, a multitude of approaches for probing structures of the whole transcriptome, i.e., RNA structuromes, have been developed. Applications of these approaches to different cell lines and tissues have generated a rich resource for the study of RNA structure–function relationships at a systems biology level. In this review, we first introduce the designs of these methods and their applications to study different RNA structuromes. We emphasize their technological differences especially their unique advantages and caveats. We then summarize the structural insights in RNA functions and regulations obtained from the studies of RNA structuromes. And finally, we propose potential directions for future improvements and studies.

Predicting RNA secondary structures from sequence and probing data

RNA secondary structures have proven essential for understanding the regulatory functions performed by RNA such as microRNAs, bacterial small RNAs, or riboswitches. This success is in part due to the availability of efficient computational methods for predicting RNA secondary structures. Recent advances focus on dealing with the inherent uncertainty of prediction by considering the ensemble of possible structures rather than the single most stable one. Moreover, the advent of high-throughput structural probing has spurred the development of computational methods that incorporate such experimental data as auxiliary information.

Emerging roles of RNA modifications in bacteria

RNA modifications are known to abound in stable tRNA and rRNA, where they cluster around functionally important regions. However, RNA-seq based techniques profiling entire transcriptomes are now uncovering an abundance of modified ribonucleotides in mRNAs and noncoding RNAs, too. While most of the recent progress in understanding the regulatory influence of these new RNA modifications stems from eukaryotes, there is growing evidence in bacteria for modified nucleotides beyond the stable RNA species, including modifications of small regulatory RNAs. Given their small genome size, good genetic tractability, and ample knowledge of modification enzymes, bacteria offer excellent model systems to decipher cellular functions of RNA modifications in many diverse physiological contexts. This review highlights how new global approaches combining classic analysis with new sequencing techniques may usher in an era of bacterial epitranscriptomics.

Genome-Wide Approaches for RNA Structure Probing

RNA molecules of all types fold into complex secondary and tertiary structures that are important for their function and regulation. Structural and catalytic RNAs such as ribosomal RNA (rRNA) and transfer RNA (tRNA) are central players in protein synthesis, and only function through their proper folding into intricate three-dimensional structures. Studies of messenger RNA (mRNA) regulation have also revealed that structural elements embedded within these RNA species are important for the proper regulation of their total level in the transcriptome. More recently, the discovery of microRNAs (miRNAs) and long non-coding RNAs (lncRNAs) has shed light on the importance of RNA structure to genome, transcriptome, and proteome regulation. Due to the relatively small number, high conservation, and importance of structural and catalytic RNAs to all life, much early work in RNA structure analysis mapped out a detailed view of these molecules. Computational and physical methods were used in concert with enzymatic and chemical structure probing to create high-resolution models of these fundamental biological molecules. However, the recent expansion in our knowledge of the importance of RNA structure to coding and regulatory RNAs has left the field in need of faster and scalable methods for high-throughput structural analysis. To address this, nuclease and chemical RNA structure probing methodologies have been adapted for genome-wide analysis. These methods have been deployed to globally characterize thousands of RNA structures in a single experiment. Here, we review these experimental methodologies for high-throughput RNA structure determination and discuss the insights gained from each approach.

Genome-wide profiling of mouse RNA secondary structures reveals key features of the mammalian transcriptome

Background

The understanding of RNA structure is a key feature toward the comprehension of RNA functions and mechanisms of action. In particular, non-coding RNAs are thought to exert their functions by specific secondary structures, but an efficient annotation on a large scale of these structures is still missing.

Results

By using a novel high-throughput method, named chemical inference of RNA structures, CIRS-seq, that uses dimethyl sulfate, and N-cyclohexyl- N'-(2-morpholinoethyl)carbodiimide metho-p-toluenesulfonate to modify RNA residues in single-stranded conformation within native deproteinized RNA secondary structures, we investigate the structural features of mouse embryonic stem cell transcripts. Our analysis reveals an unexpected higher structuring of the 5′ and 3′ untranslated regions compared to the coding regions, a reduced structuring at the Kozak sequence and stop codon, and a three-nucleotide periodicity across the coding region of messenger RNAs. We also observe that ncRNAs exhibit a higher degree of structuring with respect to protein coding transcripts. Moreover, we find that the Lin28a binding protein binds selectively to RNA motifs with a strong preference toward a single stranded conformation.

Conclusions

This work defines for the first time the complete RNA structurome of mouse embryonic stem cells, revealing an extremely distinct RNA structural landscape. These results demonstrate that CIRS-seq constitutes an important tool for the identification of native deproteinized RNA structures.

Electronic supplementary material

The online version of this article (doi:10.1186/s13059-014-0491-2) contains supplementary material, which is available to authorized users.

Transcriptome-wide mapping reveals widespread dynamic-regulated pseudouridylation of ncRNA and mRNA

Pseudouridine is the most abundant RNA modification, yet except for a few well-studied cases, little is known about the modified positions and their function(s). Here, we develop Ψ-seq for transcriptome-wide quantitative mapping of pseudouridine. We validate Ψ-seq with spike-ins and de novo identification of previously reported positions and discover hundreds of unique sites in human and yeast mRNAs and snoRNAs. Perturbing pseudouridine synthases (PUS) uncovers which pseudouridine synthase modifies each site and their target sequence features. mRNA pseudouridinylation depends on both site-specific and snoRNA-guided pseudouridine synthases. Upon heat shock in yeast, Pus7p-mediated pseudouridylation is induced at >200 sites, and PUS7 deletion decreases the levels of otherwise pseudouridylated mRNA, suggesting a role in enhancing transcript stability. rRNA pseudouridine stoichiometries are conserved but reduced in cells from dyskeratosis congenita patients, where the PUS DKC1 is mutated. Our work identifies an enhanced, transcriptome-wide scope for pseudouridine and methods to dissect its underlying mechanisms and function.

Gas-phase reactivity of carboxylic acid functional groups with carbodiimides

Gas-phase modification of carboxylic acid functionalities is performed via ion/ion reactions with carbodiimide reagents [N-cyclohexyl-N'-(2-morpholinoethyl)carbodiimide (CMC) and [3-(3-Ethylcarbodiimide-1-yl)propyl]trimethylaminium (ECPT)]. Gas-phase ion/ion covalent chemistry requires the formation of a long-lived complex. In this instance, the complex is stabilized by an electrostatic interaction between the fixed charge quaternary ammonium group of the carbodiimide reagent cation and the analyte dianion. Subsequent activation results in characteristic loss of an isocyanate derivative from one side of the carbodiimide functionality, a signature for this covalent chemistry. The resulting amide bond is formed on the analyte at the site of the original carboxylic acid. Reactions involving analytes that do not contain available carboxylic acid groups (e.g., they have been converted to sodium salts) or reagents that do not have the carbodiimide functionality do not undergo a covalent reaction. This chemistry is demonstrated using PAMAM generation 0.5 dendrimer, ethylenediaminetetraacetic acid (EDTA), and the model peptide DGAILDGAILD. This work demonstrates the selective gas-phase covalent modification of carboxylic acid functionalities.

Preparation of carbodiimide-terminated dithiolane self-assembly monolayers as a new DNA-immobilization method

A carbodiimide derivative having a dithiolane part at its terminus was designed and synthesized for use to construct carbodiimide-coated self-assembly monolayers (SAMs) on a gold surface with 6-mercaptohexanol (6MH). When treated with poly(dT), poly(dA), or poly(dA)poly(dT), only poly(dT) was immobilized on the surface of the SAMs through a specific reaction of the free imino moiety of thymine (T) with the carbodiimide moiety. The carbodiimide-covered SAM treated with probe DNA was tested in hybridization with sample DNA. Its hybridization efficiency was estimated by ferrocenylnaphthalene diimide (FND), described previously and the result revealed that the carbodiimide-covered SAM electrode can immobilize a DNA probe through the thymine moiety not involved in base pairing. The resulting electrode was capable of hybridizing with the target DNA, as proven by an increased current response of FND.

Identification of modified residues in RNAs by reverse transcription-based methods

Naturally occurring modified residues derived from canonical RNA nucleotides are present in most cellular RNAs. Their detection in RNA represents a difficult task because of their great diversity and their irregular distribution within RNA molecules. Over the decades, multiple experimental techniques were developed for the identification and localization of RNA modifications. Most of them are quite laborious and require purification of individual RNA to a homogeneous state. An alternative to these techniques is the use of reverse transcription (RT)-based approaches. In these approaches, purification of RNA to homogeneity is not necessary, because the selection of the analyzed RNA species is done by specific annealing of oligonucleotide DNA primers. However, results from primer extension analysis are difficult to interpret because of the unpredictable nature of RT pauses. They depend not only on the properties of nucleotides but also on the RNA primary and secondary structure. In addition, the degradation of cellular RNA during extraction, even at a very low level, may complicate the analysis of the data. RT-based techniques for the identification of modified residues were considerably improved by the development of selected chemical reagents specifically reacting with a given modified nucleotide. The RT profile obtained after such chemical modifications generally allows unambiguous identification of the chemical nature of the modified residues and their exact location in the RNA sequence. Here, we provide experimental protocols for selective chemical modification and identification of several modified residues: pseudouridine, inosine, 5-methylcytosine, 2'-O-methylations, 7-methylguanosine, and dihydrouridine. Advice for an optimized use of these methods and for correct interpretation of the data is also given. We also provide some helpful information on the ability of other naturally occurring modified nucleotides to generate RT pauses.

Evaluation of the performance of two carbodiimide-based cyanine dyes for detecting changes in mRNA expression with DNA microarrays

Microarrays have been extensively used to investigate genome-wide expression patterns. Although this technology has been tremendously successful, several practical issues would benefit from improvements in design. Here we describe a novel, efficient labeling methodology that uses carbodiimide-linked cyanine dyes to directly chemically label cDNA derived from mouse total RNA. Using this protocol, it takes only 10 min at 70 degrees C to complete the cDNA labeling reaction. The directly labeled cDNAs can then be hybridized to 70-mer mouse oligonucleotide arrays for expression profiling studies. Microarray analyses indicate that these cDNAs are uniformly labeled and produce higher signal intensities than conventional enzymatic direct labeling methods and comparable signal intensities to those obtained by conventional indirect labeling methods. Furthermore, verification of our microarray data using a reverse transcription PCR (RT-PCR) method indicates good agreement between the two methods. Thus, we conclude that our simplified cyanine-carbodiimide labeling method, which does not rely on the incorporation of modified nucleotides, will provide a reliable, quicker, and potentially cheaper alternative to established labeling techniques for gene expression analyses.

Attachment of oligonucleotide probes to poly carbodiimide-coated glass for microarray applications

Oligonucleotide-based DNA microarrays are becoming increasingly useful tools for the analysis of gene expression and single nucleotide polymorphisms (SNPs). Here, we present a method that permits the manufacture of microarrays from non-modified oligonucleotides on a poly carbodiimide-coated glass surface by UV-irradiation. The use of UV-irradiation facilitates an increase in the level of signal intensity, but it does not affect signal discrimination by the oligonucleotides immobilized on the surface. The signal intensity obtained for an array fabricated using non-modified oligonucleotides with UV-irradiation is approximately 7-fold greater than that without UV-irradiation. The detection of SNPs was tested to ascertain whether this technique could discriminate specific hybridization signals without causing significant UV-irradiation-induced damage to the immobilized oligonucleotides. We found that this immobilization method provides greater hybridization signals and a better match/mismatch ratio of SNPs than do the established aminosilane techniques. Application of this technology to manufacturing DNA microarrays for sequence analysis is discussed.

Site-selective reactions of imperfectly matched DNA with small chemical molecules: applications in mutation detection

The last decade has witnessed many exciting scientific publications associated with site-selective reactions of small chemical molecules with imperfectly matched DNA. Typical examples are carbodiimide, hydroxylamine, potassium permanganate, osmium tetroxide, chemical tagging probes, biotinylated, chemiluminescent and fluorescent probes, and all of them selectively react with imperfectly matched DNA. More recently, some therapeutic agents including DNA intercalating drugs and groove binders have been found to promote the in vivo repair system to recognize and repair the mismatch more effectively. The results have established a novel method for detection of mismatches. Development of new chemical reactions for detection of imperfectly matched DNA and mutations is a rapidly growing field and has attracted significant interest of scientists from both chemical and biological fields and it is the main focus of this review.

The use of chemical reagents in the detection of DNA mutations

As the analysis of the human genome proceeds at an ever-increasing pace, many genes have been identified which are the site for mutations responsible for inherited diseases. The identification of the mutations within these genes has become a major application of molecular biology technologies, and to this end a number of mutation detection systems have been developed for use in diagnostic and research laboratories. The uses of these mutation detection systems are in the diagnosis of inherited disease (both prenatal and neonatal) and in an understanding of the function of the affected protein by cataloguing the range of mutations. Two of these mutation detection systems are reviewed here. Both rely on chemical modification of mismatched nucleotides, by either carbodiimide or hydroxylamine and osmium tetroxide. The methods are termed the carbodiimide (CDI) and the Chemical Cleavage of Mismatch (CCM) methods. The history and evolution of the methods is tracked, illustrating the way in which they developed, both as suitable technology became available (for example, the polymerase chain reaction) and as a result of a specific need. The current methodologies are briefly discussed, followed by a discussion of their applications, especially in the realm of disease mutation detection.

Quantitative analysis of carbodiimide modified DNA and immunoprobing by adduct specific antibodies

Antibodies have been raised against N-cyclohexyl-N-(4-methylmorpholinium)ethyl carbodiimide (CMC) modified single-stranded DNA and characterized by competitive and non-competitive immunoassays to be highly specific for CMC base adduct in homopolymers poly(dG), poly(dT) and DNA. The antibodies recognize picogram concentrations of CMC treated DNA with no cross reactivity to at least 1000-fold excess of unmodified DNA or CMC treated poly(dA). The detection limit of antibodies at 1.4 fmol CMC adduct allows quantitation at a CMC/base ratio of 4.6.10(-7). Based upon single modified base-containing synthetic oligomers, a 7-fold higher binding preference is observed for CMC modified thymine than guanine bases. CMC binding to supercoiled DNA is found to depend upon reaction temperature and ionic strength. CMC-modified supercoiled SV40 and ColE1 DNA, exhibit specific antibody binding proportional to the DNA concentration and extent of CMC modification. However, antibody binding observed is independent of the conformation or strandedness of CMC-modified DNA. DNA extensively modified with CMC retains its inherent capacity to specifically and quantitatively hybridize with complementary DNA immobilized to membranes upon direct blotting or Southern transfers from gels. Hybridized CMC-DNA, through antibody binding, provides for the sensitive and non-isotopic detection of the target DNA sequences.

Detection of single-base mutations by reaction of DNA heteroduplexes with a water-soluble carbodiimide followed by primer extension: application to products from the polymerase chain reaction

A new method was developed for the detection of single-base mutations in DNA. The polymerase chain reaction was used to prepare DNA fragments of up to 1 kb. Fragments that differed by a single-base were combined, denatured and renatured to generate heteroduplexes. The heteroduplexes were reacted with a water-soluble carbodiimide under conditions in which the carbodiimide modified Gs and Ts that were not base paired. The DNA was then used as a template for primer extension with Taq DNA polymerase under conditions in which extension terminated at the site of the carbodiimide-modified base and generated a 32P-labeled fragment that was identified by polyacrylamide gel electrophoresis as a fragment smaller than the full length product. The procedure detected all four general classes of single-base mutations in several different sequence contexts. The site of the mutation was located to within about 15 bp. Extension with both a 5'- and a 3'-primer made it possible to confirm the site of the mutation in most DNA samples or detect a mutation in heteroduplexes even if a G or T in one strand was unreactive because of its sequence context. The procedure appears to have several advantages over previously published techniques.

Immunoassays for carbodiimide modified DNA-detection of unpairing transitions in supercoiled ColE1 DNA

The water soluble reagent N-cyclohexyl-N'-beta-(4-methylmorpholinium) ethyl carbodiimide-p-toluene sulphonate (CMC) can be used to probe for unpaired and mismatched sites in DNA. Polyclonal antibodies for CMC modified DNA were produced in order to develop immunological assays for the localization and quantitation of CMC adducts. Immunoslot blot analysis of modified DNA exhibited antibody binding proportional to the extent of CMC modification with adduct detection in the femtamole range. Unmodified DNA did not cross react under the conditions of the assay. The distribution of CMC reactivity for supercoiled ColE1 DNA modified at 100, 200 and 300 mM NaCl was determined by immunoanalysis of EcoRI-Hae2-NruI restriction fragments Southern transferred to nylon membranes. Reactivity above random expectation occurred in the A2-II fragment which can be accounted for by its high A-T content of 71.3%. Reactivity below random expectation occurred in the C fragment which can be accounted for by its low AT content of 43%. CMC modification for the other restriction fragments appeared random.

Detection and location of single-base mutations in large DNA fragments by immunomicroscopy

A technique whereby single-base mutations can be detected by immunomicroscopy of DNA heteroduplexes is described. Four constructs of the filamentous phage M13 were prepared so as to differ by a single base at the same site. Heteroduplexes were prepared and reacted with a water-soluble carbodiimide, with polyclonal antibodies specific for the carbodiimide, and then with a second antibody linked to an electrondense marker. Electron microscopy of the heteroduplexes indicated that the label was located at 4.9 to 5.1 kb in the 7.2-kb phage. The known site of the mismatch was 4.96 kb. Also, plasmids containing inserts of a fragment from the 5' end of hemoglobin A or hemoglobin S were prepared. The median location of the label in heteroduplex molecules was 2.9 kb. The known site of the mismatch was 2.65 kb in the 4.9-kb plasmid. The procedure requires about 10 days to analyze two samples of plasmid or phage DNA.

Sulfite oxidase from chicken liver. Further characterization of the role of carboxyl groups in the reaction with cytochrome c

The mitochondrial enzyme sulfite oxidase catalyzes the oxidation of cytochrome c by sulfite. The reaction is inhibited when the enzyme is treated with N-cyclohexyl-N'-[2-(N-methylmorpholino)-ethyl]carbodiimide p-toluenesulfonate (CMC). Inhibition follows the conversion of two carboxyl groups to N-acylurea derivatives. The two groups are about equally reactive toward this inhibitor and blocking of either group abolishes electron transfer to cytochrome c. The rate of inactivation is almost the same in the presence of cytochrome c and under conditions where, on average, 89% of the enzyme is bound to cytochrome c. Therefore, the functional groups are not likely to be at the cytochrome c binding site. There are two equal and non-interacting cytochrome c binding sites per sulfite oxidase monomer. The Kd is 7.5 microM at pH 6.0 and low ionic strength. The data are difficult to reconcile with binding of cytochrome c to a cluster of acidic residues in the area of the heme b prosthetic group, as was envisaged for the cytochrome-b5--cytochrome c complex [Salemme, F.R. (1976) J. Mol. Biol. 102, 563-568]. An improved method for the purification of sulfite oxidase from chicken liver, using affinity chromatography on cytochrome c--Sepharose, is described.

Glutamic acid-149 is important for enzymatic activity of yeast inorganic pyrophosphatase

Modification of Saccharomyces cerevisiae inorganic pyrophosphatase (PPase) with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide is known to lead to a loss of enzymatic activity, the rate of which is decreased in the presence of ligands binding to the active site [Cooperman, B. S., & Chiu, N. Y. (1973) Biochemistry 12, 1676-1682; Heitman, P., & Uhlig, H. J. (1974) Acta Biol. Med. Ger. 32, 565-594]. In this work we show that, when such inactivation is carried out in the presence of [14C]glycine ethyl ester (GEE), GEE is covalently incorporated into PPase, incorporation into the most highly labeled tryptic peptide is site-specific, as evidenced by the reduction of such incorporation in the presence of the active site ligands Zn2+ and Pi, the extent of formation of this specifically labeled peptide correlates with the fractional loss of PPase activity, and the specifically labeled peptide corresponds to residues 145-153 and the position of incorporation within this peptide is Glu-149. The significance of our findings for the location of the active site and for the catalytic mechanism of PPase is briefly considered in the light of the 3-A X-ray crystallographic structure of Arutyunyun and his colleagues [Arutyunyun, E. G., et al. (1981) Dokl. Akad. Nauk SSSR 258, 1481-1485; Kuranova, I. P., et al. (1983) Bioorg. Khim. 9, 1611-1919; Terzyan, S. S., et al. (1984) Bioorg. Khim. 10, 1469-1482].

Design and preparation of affinity columns for the purification of eukaryotic messenger ribonucleic acid cap binding protein

2',3'-O-[1-(2-Carboxyethyl) ethylidene]-7-methylguanosine 5'-diphosphate (5) and 7-(5-carboxypentyl) guanosine 5'-diphosphate (13) have been synthesized and immobilized on AH-Sepharose 4B to the extent of 17.4 and 36.6 mumol of ligand/g of gel, respectively. The affinity resins thus derives were employed in columns for the purificaton of 24K cap binding protein (CBP) from rabbit reticulocytes. Each resin was found to retain the protein of interest; elution of 24K CBP could then be effected by washing with 70 microM m7GDP. The 24K CBPs released from both columns were found to be active, both as judged by a cross-linking assay that utilized 10(4)-oxidized methyl-3H-labeled reovirus mRNA as a substrate for the protein and also by the ability of the isolated 24K CBP to stimulate the translocation of capped Sindbis virus mRNA in HeLa cell extracts.

The essential carboxyl group in restriction endonuclease EcoRI

We have carried out studies on type II restriction endonuclease EcoRI, which cleaves the DNA sequence 5'd(-G-A-A-T-T-C-)3', as indicated. The active form of the enzyme consists of two subunits, each 31063 molecular weight. A water-soluble reagent, 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-sulphonate, which reacts with carboxyl groups and also with tyrosine and cysteine residues, has been found to inactivate this enzyme. Results are presented which show the following. (1) This specific inactivation is not due to modification of tyrosine or cysteine residues. (2) There is one carboxyl group per subunit which, when modified with carbodiimide, inactivates the enzyme. (3) phi X174 DNA (which does not contain EcoRI sites) partially protects the enzyme from the carbodiimide; protection is unaffected by the additional presence of Mg2+, but significantly greater with Co2+ and phi X174 DNA.

Molecular electrostatic potential of the nucleic acids

It is generally acknowledged that geometrical and conformational properties of biopolymers have an important effect on their biochemical behaviour. It is less easily recognized that these properties depend also on their macromolecular electronic characteristics.

The aim of this review is to demonstrate the significance of such macromolecular electronic effects. Particularly useful for this sake is the recently much developed concept of ‘molecular electrostatic potential’ (MEP) (Scrocco & Tomasi, 1973, 1978) by which is defined the electrostatic (Coulomb) potential created in the neighbouring space by the nuclear charges and the eletronic distribution of a molecule.

Chemical modification studies and the secondary structure of HeLa cell 5.8S rRNA

Various secondary structure models have been proposed for 5.8 S rRNA. In this paper HeLa cell 5.8 S rRNA is shown to possess several sites that are reactive to carbodiimide at 25 degrees, and other regions that are unreactive. Previous work has established the distribution of reactive and unreactive cytidine residues along the primary structure (11). The secondary structure model of Nazar et al. (7) is fully compatible with the chemical reactivity data whereas other models are partly incompatible. We conclude that the model of Nazar et al. provides the best approximation so far available to the conformation of isolated 5.8 S rRNA. Findings on the effect temperature on the chemical reactivity of different parts of the structure are summarized. The findings described in this paper should provide a basis for examining the specific interaction of 5.8 S rRNA with 28 s rRNA.

Methods for limiting the action of SP3 DNAase and for the determination of the direction of hydrolysis of processive exonucleases

The action of the exonuclease SP3 DNAase is inhibited by chemical modification of DNA with the cation N-cyclohexyl-N'-beta-(4-methylmorpholinium)-ethylcarbodiimide (CME). The limited activity of the enzyme on CMA-modified DNA makes it possible to demonstrate that the enzyme also initiates its attack on polydeoxyribonucleotides at the 5'-termini. This was determined by the analysis of the products from the digestion of CME-modified DNA containing labeled 5'-terminal phosphate groups. Such procedure can be adopted as a general approach for the determination of the direction of hydrolysis of other processive exonucleases. SP3 DNAase has been shown able to degrade oligo- and polydeoxyribonucleotides with or without 5'-terminal phosphate groups with equal efficiency (Aposhian, H.V., Friedman, N., Nichihara M., Heimer, E.P., and Nussbaum, A.L. (1970) J. Mol. Biol. 49, 367-379). The present work also shows that the enzyme can even hydrolyze oligo- and polynucleotides containing derivatized phosphate groups.

Substrate- and product-affinity resins for adenosine deaminase obtained by immobilisation of adenosine and inosine via 2',3'-cyclic acetal derivatives

Immobilised inosine (6a) and adenosine (6c) and their 5'-phosphates have been synthesized. Reaction of the nucleosides with ethyl levulinate, followed by saponification or phosphorylation and then saponification, gave the 2',3'-O-[1-(2-carboxyethyl)ethylidene] derivatives 3 and 4 and the corresponding 5'-phosphates 2b and 2d. 6-Aminohexylagarose (5) was severally coupled to 2b, 2d, 3, and 4 through the carboxyl groups to give the polymers 6a-d. Adenosine deaminase converts 3 into 4, and 6c into 6a. The polymers can be used as affinity resins for adenosine deaminase, which is bound more strongly to 6c than to 6a. The operational capacity of 6a for adenosine deaminase is constant at 15--25 degrees, but decreases by approximately 16% from 25 degrees to 35 degrees. The resin 6a has been used to separate adenosine deaminase from mixtures containing other enzymes, for example, guanase or alcohol dehydrogenase.

Carbodiimide modification of superhelical PM2 DNA: considerations regarding reaction at unpaired bases and the unwinding of superhelical DNA with chemical probes

Superhelical PM2 DNA I can be modified with N-cyclohexyl-N'-beta-(4-methylmorpholinium)ethyl carbodiimide (CMC). The transition of the sedimentation coefficient uncorrected for buoyant density change (S20,*) vs. % reactivity in terms of base pairs shows the following characteristics. The S20,* increases by 4.5 S units upon 1% modification. There is a plateau in S20,* between 1 and 4% reactivity. The extent of reactivity was determined by buoyant density and 14C radioactive CMC binding measurements. Further reactivity was not explored since Pulleyblank and Morgan's (22) data of S20,* vs. % reactivity from 6 to 34% was previously published. The initial results obtained in this study are complementary to the cited results of the above authors. Consequently, both sets of data taken together represent a complete description of S20,* vs. % reactivity with CMC. It is shown that the model in which superhelical DNA is proposed to contain small intrastrand hairpin regions can be extended to account for the observed transitions in S20,* vs. reactivity.

Iodination as a probe for small regions of disrupted secondary structure in double-stranded DNAs

Conditions were established where the thallium-catalyzed iodination of random coil DNA proceeded 100-200 times faster than for native DNA. This reaction was explored as a probe for localized regions of disrupted base pairs in duplex DNA. A heteroduplex was constructed between DNA fragments produced by Hind II + III cleavage of phi80 plac DNA and phi80 plac DNA containing the Ll deletion (73 nucleotides in length). This heteroduplex incorporated twelve times as much iodine as the parent homoduplex fragments. Hence the technique could reveal the presence of a few (two or more) nonpaired cytosines, if they existed within an otherwise helical DNA fragment 789 base pairs long. Iodination studies were performed on superhelical SV40 DNA and on linear lambdaplac DNA. Analysis of the relative amount of iodine in restriction endonuclease fragments of these DNA's revealed the absence of localized single-stranded regions.