Characterization of a catalytically efficient acidic RNA-cleaving deoxyribozyme

A DNAzymes-in-droplets assay for Burkholderia gladioli pathovar cocovenenans with single-bacterium sensitivity

Foodborne pathogens pose a serious risk to human health, and the simple and rapid detection of such bacteria in complex food matrices remains challenging. Herein, we present the selection and characterization of a novel RNA-cleaving fluorogenic DNAzyme, named RFD-BC1, with exceptional specificity for Burkholderia gladioli pv. cocovenenans (B. cocovenenans), a pathogen strongly associated with fatal food poisoning cases. RFD-BC1 was activated by a protein secreted specifically by whole viable B. cocovenenans and displayed an optimum pH distinct from the selection pH, with a rate constant of approximately 0.01 min-1 at pH 5.0. Leveraging this newly discovered DNAzyme, we developed a novel system, termed DNAzymes-in-droplets (DID), that integrates droplet microfluidics to achieve the rapid and selective detection of live B. cocovenenans with single-cell sensitivity. We believe that the approach described herein holds promise for combating specific bacterial pathogens in food samples, offering significant potential for broader applications in food safety and public health.

An RNA-Cleaving DNAzyme That Requires an Organic Solvent to Function

Engineering functional nucleic acids that are active under unusual conditions will not only reveal their hidden abilities but also lay the groundwork for pursuing them for unique applications. Although many DNAzymes have been derived to catalyze diverse chemical reactions in aqueous solutions, no prior study has been set up to purposely derive DNAzymes that require an organic solvent to function. Herein, we utilized in vitro selection to isolate RNA-cleaving DNAzymes from a random-sequence DNA pool that were "compelled" to accept 35 % dimethyl sulfoxide (DMSO) as a cosolvent, via counter selection in a purely aqueous solution followed by positive selection in the same solution containing 35 % DMSO. This experiment led to the discovery of a new DNAzyme that requires 35 % DMSO for its catalytic activity and exhibits drastically reduced activity without DMSO. This DNAzyme also requires divalent metal ions for catalysis, and its activity is enhanced by monovalent ions. A minimized, more efficient DNAzyme was also derived. This work demonstrates that highly functional, organic solvent-dependent DNAzymes can be isolated from random-sequence DNA libraries via forced in vitro selection, thus expanding the capability and potential utility of catalytic DNA.

In Vitro Selection of M2+-Independent, Fast-Responding Acidic Deoxyribozymes for Bacterial Detection

We report on the first efforts to isolate acidic RNA-cleaving DNAzymes (aRCDs) from a random-sequence DNA pool by in vitro selection that are activated by a microbe Escherichia coli (E. coli), at pH 5.3. Importantly, these E. coli-responsive aRCDs only require monovalent metal ions as cofactors for cleaving a fluorogenic chimeric DNA/RNA substrate. Such characteristics can be used to efficiently protect RCDs from both intrinsic chemical instability and external enzymatic degradation. One remarkable DNAzyme, aRCD-EC1, is specific for E. coli, and its target is likely a protein. Furthermore, truncated aRCD-EC1 had significantly improved catalytic activity with an observed rate constant (kobs) of 1.18 min-1, making it the fastest bacteria-responding RCD reported to date. Clinical evaluation of this aRCD-based fluorescent assay using 40 patient urine samples demonstrated a diagnostic sensitivity of 100% and a specificity of 100% at a total analysis time of 50 min without a bacterial culture. This work can expand the repertoire of DNAzymes that are active under nonphysiological conditions, thus facilitating the development of diverse DNAzyme-based biosensors in clinical diagnosis.

Functional Nucleic Acids Under Unusual Conditions

Functional nucleic acids (FNAs), including naturally occurring ribozymes and riboswitches as well as artificially created DNAzymes and aptamers, have been popular molecular toolboxes for diverse applications. Given the high chemical stability of nucleic acids and their ability to fold into diverse sequence-dependent structures, FNAs are suggested to be highly functional under unusual reaction conditions. This review will examine the progress of research on FNAs under conditions of low pH, high temperature, freezing conditions, and the inclusion of organic solvents and denaturants that are known to disrupt nucleic acid structures. The FNA species to be discussed include ribozymes, riboswitches, G-quadruplex-based peroxidase mimicking DNAzymes, RNA-cleaving DNAzymes, and aptamers. Research within this space has not only revealed the hidden talents of FNAs but has also laid important groundwork for pursuing these intriguing functional macromolecules for unique applications.

Serendipitous Discovery of a Guanine-rich DNA Molecule with a Highly Stable Structure in Urea

We have made an accidental discovery of an unusual, single-stranded, guanine-rich DNA molecule that is capable of adopting a folded structure in 7 M urea (7MU) known to denature nucleic acid structures. The folding of this molecule requires Na⁺ and Mg²⁺ and the folded structure remains stable when subjected to denaturing (7MU) polyacrylamide gel electrophoresis. Results from sequence mutagenesis, DNA methylation, and circular dichroism spectroscopy studies suggest that this molecule adopts an intramolecular guanine-quadruplex structure with 5 layers of guanine tetrads. Our finding indicates that DNA has the ability to create extremely stable structural folds despite its limited chemical repertoire, making it possible to develop DNA-based systems for unconventional applications.

Discovery and Biosensing Applications of Diverse RNA-Cleaving DNAzymes

DNA-based enzymes, or DNAzymes, are not known to exist in Nature but can be isolated from random-sequence DNA pools using test tube selection techniques. Since the report of the first DNAzyme in 1994, many catalytic DNA molecules for catalyzing wide-ranging chemical transformations have been isolated and studied. Our laboratory has a keen interest in searching for diverse DNAzymes capable of cleaving RNA-containing substrates, determining their sequence requirements and structural properties, and examining their potential as biosensors. This Account begins with the description of an accidental discovery on the sequence adaptability of a small DNAzyme known as "8-17", when we performed 16 parallel selections to search for DNAzymes that targeted each and every possible dinucleotide junction of RNA for cleavage. DNAzyme 8-17 dominated all the selection pools targeting purine-containing junctions. In-depth sequence analysis revealed that 8-17 could manifest itself in many sequence options defined by the requirement of four absolutely conserved nucleotides. This study also exposed the fact that 8-17 had poor activity toward pyrimidine-pyrimidine junctions. With this information in hand, we proceeded to the discovery of diverse non-8-17 DNAzymes that exhibited robust catalytic activity under physiological conditions. These DNAzymes were found to universally interact with their substrates through two Watson-Crick binding arms and have a catalytic core of varying length and secondary-structure complexity. RNA-cleaving DNAzymes were also isolated to function at acidic conditions (pH 3-5), and these molecules exhibited intriguing pH profiles, with the highest activity precisely matching the pH used for their selection. Interestingly, these DNAzymes appear to use non-Watson-Crick interactions in defining their structures. More recently, we have embarked on the development of ligand-responsive RNA-cleaving fluorogenic DNAzymes that can recognize specific bacterial pathogens, such as Escherichia coli and Clostridium difficile, using a method that does not require a priori identification of a specific biomarker. Instead, the crude extracellular mixture as a whole is used as the target to drive the DNAzyme isolation. High recognition specificity can be achieved with a double-selection approach in which a DNA library is negatively selected against the cellular mixture prepared from unintended bacteria, followed by positive selection against the same mixture derived from a specific species or strain of bacterial pathogen. Finally, we have shown that DNAzymes' compatibility with DNA replication can benefit the design of amplification mechanisms that uniquely link the action of RNA-cleaving DNAzymes to rolling circle amplification, an isothermal DNA amplification technique. These methods are well suited for translating the target-binding and cleavage activity of an analyte-activated RNA-cleaving DNAzyme into the production of massive amounts of DNA amplicons to achieve ultrahigh detection sensitivity. Given the high chemical stability of DNA, our ability to discover catalytic DNA sequences by simultaneously evaluating as many as 10¹⁶ different DNA sequences, the accessibility to diverse RNA-cleaving DNAzymes in a single DNA pool, and the availability of methods for designing simple biosensors that incorporate RNA-cleaving DNAzymes, we believe we are moving closer to employing RNA-cleaving DNAzymes for exciting applications, such as point of care diagnostics or field detection of environmental toxins.

The Optimization and Characterization of an RNA-Cleaving Fluorogenic DNAzyme Probe for MDA-MB-231 Cell Detection

Breast cancer is one of the most frequently diagnosed cancers in females worldwide and lacks specific biomarkers for early detection. In a previous study, we obtained a selective RNA-cleaving Fluorogenic DNAzyme (RFD) probe against MDA-MB-231 cells, typical breast cancer cells, through the systematic evolution of ligands by exponential process (SELEX). To improve the performance of this probe for actual application, we carried out a series of optimization experiments on the pH value of a reaction buffer, the type and concentration of cofactor ions, and sequence minimization. The length of the active domain of the probe reduced to 25 nt from 40 nt after optimization, which was synthesized more easily and economically. The detection limit of the optimized assay system was 2000 MDA-MB-231 cells in 30 min, which is more sensitive than the previous one (almost 5000 cells). The DNAzyme probe was also capable of distinguishing MDA-MB-231 cell specifically from 3 normal cells and 10 other tumor cells. This probe with high sensitivity, selectivity, and economic efficiency enhances the feasibility for further clinical application in breast cancer diagnosis. Herein, we developed an optimization system to produce a general strategy to establish an easy-to-use DNAzyme-based assay for other targets.

Characterization of Highly Efficient RNA-Cleaving DNAzymes that Function at Acidic pH with No Divalent Metal-Ion Cofactors

Here, we describe the characterization of new RNA‐cleaving DNAzymes that showed the highest catalytic efficiency at pH 4.0 to 4.5, and were completely inactive at pH values higher than 5.0. Importantly, these DNAzymes did not require any divalent metal ion cofactors for catalysis. This clearly suggests that protonated nucleic bases are involved in the folding of the DNAzymes into catalytically active structures and/or in the cleavage mechanism. The trans‐acting DNAzyme variants were also catalytically active. Mutational analysis revealed a conservative character of the DNAzyme catalytic core that underpins the high structural requirements of the cleavage mechanism. A significant advantage of the described DNAzymes is that they are inactive at pH values close to physiological pH and under a wide range of conditions in the presence of monovalent and divalent metal ions. These pH‐dependent DNAzymes could be used as molecular cassettes in biotechnology or nanotechnology, in molecular processes that consist of several steps. The results expand the repertoire of DNAzymes that are active under nonphysiological conditions and shed new light on the possible mechanisms of catalysis.

Examination of bacterial inhibition using a catalytic DNA

Determination of accurate dosage of existing antibiotics and discovery of new antimicrobials or probiotics entail simple but effective methods that can conveniently track bacteria growth and inhibition. Here we explore the application of a previously reported fluorogenic E. coli-specific DNAzyme (catalytic DNA), RFD-EC1, as a molecular probe for monitoring bacterial inhibition exerted by antibiotics and for studying bacterial competition as a result of cohabitation. Because the DNAzyme method provides a convenient way to monitor the growth of E. coli, it is capable of determining the minimal inhibitory concentration (MIC) of antibiotics much faster than the conventional optical density (OD) method. In addition, since the target for RFD-EC1 is an extracellular protein molecule from E. coli, RFD-EC1 is able to identify pore-forming antibiotics or compounds that can cause membrane leakage. Finally, RFD-EC1 can be used to analyse the competition of cohabitating bacteria, specifically the inhibition of growth of E. coli by Bacillus subtilis. The current work represents the first exploration of a catalytic DNA for microbiological applications and showcases the utility of bacteria-sensing fluorogenic DNAzymes as simple molecular probes to facilitate antibiotic and probiotic research.

Highly specific recognition of breast tumors by an RNA-cleaving fluorogenic DNAzyme probe

Breast cancer is one of the most commonly diagnosed cancers among females worldwide. Early detection of breast cancer is of vital importance to the reduction of the mortality rate. However, the lack of specific biomarkers that can effectively identify breast cancer cells limits the ability for early diagnosis of breast cancer. RNA-cleaving fluorogenic DNAzymes (RFDs), which can be produced through the systematic evolution of ligands by exponential enrichment (SELEX) process, are catalytic DNA molecules capable of generating a fluorescent signal when the appropriate target is bound. In this study, we carried out a SELEX experiment to select for RFDs that are active in the cell lysate of MDA-MB-231, a model breast cancer cell line. We obtained a RFD probe, named AAI2-5, that can detect MDA-MB-231 at a concentration of cell lysate proteins as low as 0.5 μg/mL (which is equivalent to ∼5000 cell/mL). AAI2-5 is capable of distinguishing MDA-MB-231 cells from normal cells as well as other types of tumor cells, including other subtypes of breast cancer cells. Moreover, AAI2-5 responded positively to more than 90% of malignant breast tumors. This report is the first study to explore the RFD system for the detection of cancer cells. The results suggest that RFD can be potentially applied for the diagnosis and treatment of breast cancer in the future.

A sensitive DNA enzyme-based fluorescent assay for bacterial detection

Bacterial detection plays an important role in protecting public health and safety, and thus, substantial research efforts have been directed at developing bacterial sensing methods that are sensitive, specific, inexpensive, and easy to use. We have recently reported a novel “mix-and-read” assay where a fluorogenic DNAzyme probe was used to detect model bacterium E. coli. In this work, we carried out a series of optimization experiments in order to improve the performance of this assay. The optimized assay can achieve a detection limit of 1000 colony-forming units (CFU) without a culturing step and is able to detect 1 CFU following as short as 4 h of bacterial culturing in a growth medium. Overall, our effort has led to the development of a highly sensitive and easy-to-use fluorescent bacterial detection assay that employs a catalytic DNA.

Lighting Up RNA-Cleaving DNAzymes for Biosensing

The development of the in vitro selection technique has allowed the isolation of functional nucleic acids, including catalytic DNA molecules (DNAzymes), from random-sequence pools. The first-ever catalytic DNA obtained by this technique in 1994 is a DNAzyme that cleaves RNA. Since then, many other RNase-like DNAzymes have been reported from multiple in vitro selection studies. The discovery of various RNase DNAzymes has in turn stimulated the exploration of these enzymatic species for innovative applications in many different areas of research, including therapeutics, biosensing, and DNA nanotechnology. One particular research topic that has received considerable attention for the past decade is the development of RNase DNAzymes into fluorescent reporters for biosensing applications. This paper provides a concise survey of the most significant achievements within this research topic.

Detection of bacteria using fluorogenic DNAzymes

Outbreaks linked to food-borne and hospital-acquired pathogens account for millions of deaths and hospitalizations as well as colossal economic losses each and every year. Prevention of such outbreaks and minimization of the impact of an ongoing epidemic place an ever-increasing demand for analytical methods that can accurately identify culprit pathogens at the earliest stage. Although there is a large array of effective methods for pathogen detection, none of them can satisfy all the following five premier requirements embodied for an ideal detection method: high specificity (detecting only the bacterium of interest), high sensitivity (capable of detecting as low as a single live bacterial cell), short time-to-results (minutes to hours), great operational simplicity (no need for lengthy sampling procedures and the use of specialized equipment), and cost effectiveness. For example, classical microbiological methods are highly specific but require a long time (days to weeks) to acquire a definitive result.(1) PCR- and antibody-based techniques offer shorter waiting times (hours to days), but they require the use of expensive reagents and/or sophisticated equipment.(2-4) Consequently, there is still a great demand for scientific research towards developing innovative bacterial detection methods that offer improved characteristics in one or more of the aforementioned requirements. Our laboratory is interested in examining the potential of DNAzymes as a novel class of molecular probes for biosensing applications including bacterial detection.(5) DNAzymes (also known as deoxyribozymes or DNA enzymes) are man-made single-stranded DNA molecules with the capability of catalyzing chemical reactions.(6-8) These molecules can be isolated from a vast random-sequence DNA pool (which contains as many as 10(16) individual sequences) by a process known as "in vitro selection" or "SELEX" (systematic evolution of ligands by exponential enrichment).(9-16) These special DNA molecules have been widely examined in recent years as molecular tools for biosensing applications.(6-8) Our laboratory has established in vitro selection procedures for isolating RNA-cleaving fluorescent DNAzymes (RFDs; Fig. 1) and investigated the use of RFDs as analytical tools.(17-29) RFDs catalyze the cleavage of a DNA-RNA chimeric substrate at a single ribonucleotide junction (R) that is flanked by a fluorophore (F) and a quencher (Q). The close proximity of F and Q renders the uncleaved substrate minimal fluorescence. However, the cleavage event leads to the separation of F and Q, which is accompanied by significant increase of fluorescence intensity. More recently, we developed a method of isolating RFDs for bacterial detection.(5) These special RFDs were isolated to "light up" in the presence of the crude extracellular mixture (CEM) left behind by a specific type of bacteria in their environment or in the media they are cultured (Fig. 1). The use of crude mixture circumvents the tedious process of purifying and identifying a suitable target from the microbe of interest for biosensor development (which could take months or years to complete). The use of extracellular targets means the assaying procedure is simple because there is no need for steps to obtain intracellular targets. Using the above approach, we derived an RFD that cleaves its substrate (FS1; Fig. 2A) only in the presence of the CEM produced by E. coli (CEM-EC).(5) This E. coli-sensing RFD, named RFD-EC1 (Fig. 2A), was found to be strictly responsive to CEM-EC but nonresponsive to CEMs from a host of other bacteria (Fig. 3). Here we present the key experimental procedures for setting up E. coli detection assays using RFD-EC1 and representative results.

Developing fluorogenic RNA-cleaving DNAzymes for biosensing applications

Deoxyribozymes (or DNAzymes) are single-stranded DNA molecules that have the ability to catalyze a chemical reaction. Currently, DNAzymes have to be isolated from random-sequence DNA libraries by a process known as in vitro selection (IVS) because no naturally occurring DNAzyme has been discovered. Several IVS studies have led to the isolation of many RNA-cleaving DNAzymes (RNase DNAzymes), which catalyze the transesterification of a phosphodiester linkage in an RNA substrate, resulting in its cleavage. An RNase DNAzyme and its substrate can be modified with a pair of donor and acceptor fluorophores (or a fluorophore and quencher pair) to create a fluorescence-signaling system (a signaling DNAzyme) where the RNA-cleaving activity of the DNAzyme is reported through the generation of a fluorescent signal. A signaling DNAzyme can be further coupled with an aptamer (a target-binding nucleic acid sequence) to generate a fluorogenic aptazyme in which the aptamer-target interaction confers an allosteric control of the coupled RNA-cleaving and fluorescence-signaling activity of the DNAzyme. Fluorogenic aptazymes can be exploited as valuable molecular tools for biosensing applications. In this chapter, we provide both a detailed description of methods for isolation of signaling DNAzymes by IVS and general approaches for rational engineering of fluorogenic aptazymes for target detection.

The structural diversity of deoxyribozymes

When not constrained to long double-helical arrangements, DNA is capable of forming structural arrangements that enable specific sequences to perform functions such as binding and catalysis under defined conditions. Through a process called in vitro selection, numerous catalytic DNAs, known as deoxyribozymes or DNAzymes, have been isolated. Many of these molecules have the potential to act as therapeutic agents and diagnostic tools. As such, a better understanding of the structural arrangements present in these functional DNAs will aid further efforts in the development and optimization of these useful molecules. Structural characterization of several deoxyribozymes through mutagenesis, in vitro re-selection, chemical probing and circular dichroism has revealed many distinct and elaborate structural classes. Deoxyribozymes have been found to contain diverse structural elements including helical junctions, pseudoknots, triplexes, and guanine quadruplexes. Some of these studies have further shown the repeated isolation of similar structural motifs in independent selection experiments for the same type of chemical reaction, suggesting that some structural motifs are well suited for catalyzing a specific chemical reaction. To investigate the extent of structural diversity possible in deoxyribozymes, a group of kinase deoxyribozymes have been extensively characterized. Such studies have discovered some interesting structural features of these DNAzymes while revealing some novel DNA structures.

[New approaches to the real-time detection of nucleotide mismatches by means of chimeric hybridization probes]

New approaches to the detection of impaired nucleotides based on the allele specific ligation of a "C probe" followed by rolling circle amplification have been developed. The detection of amplification products was realized by using enzymatic and deoxyribozyme digestion of fluorescently-labeled DNA-RNA-DNA chimeric oligonucleotide structures in cycling probe technology (CPT) in real-time mode.

Characterization of an RNA-cleaving deoxyribozyme with optimal activity at pH 5

An in vitro selection endeavor previously executed by our laboratory led to the isolation of a set of RNA-cleaving deoxyribozymes that thrive under acidic conditions [Liu, Z., Mei, S. H., Brennan, J. D., and Li, Y. (2003) J. Am. Chem. Soc. 125, 7539-7545]. One of these sequences, coined pH5DZ1, is a 100-nucleotide (nt) cis-acting enzyme that was found to exhibit high cleavage activity near pH 5. Herein, we seek to deduce the properties and sequence requirements of this enzyme. This deoxyribozyme was found to cleave a 23-nt chimeric DNA-RNA substrate, which contains a single ribonucleotide flanked by fluorophore- and quencher-modified nucleotides on each side of the cleavage junction. Extensive nucleotide deletion experiments indicated that only 42 bases within the original enzyme sequence are required for catalysis. Results from a reselection experiment further revealed that 26 of these nucleotides are absolutely conserved. In addition to sequence analysis and minimization studies, we successfully designed a trans-acting variant of this enzyme. Characterization of the cleavage products produced upon pH5DZ1-mediated RNA cleavage and analyses of possible structures of pH5DZ1 provided us with insights into the catalytic mechanism of pH5DZ1 and characteristics of deoxyribozymes that retain their activity under acidic conditions.

Characterization of pH3DZ1 — An RNA-cleaving deoxyribozyme with optimal activity at pH 3

We previously described a cis-acting RNA-cleaving deoxyribozyme known as pH3DZ1 that exhibits optimal catalytic activity at pH 3.0 (Zhongjie Liu, Shirley H. Mei, John D. Brennan, and Yingfu Li. J. Am. Chem. Soc. 125, 7539 (2003)). This DNA catalyst was made of a 99-nucleotide (nt) catalytic domain covalently linked to a 23-nt DNA–RNA chimeric substrate containing a single ribonucleotide as the cleavage site. In the present work, we conducted an extensive sequence examination of this deoxyribozyme via nucleotide truncation and reselection experiments, with a goal to minimize its size and identify the nucleotides that are crucial to its catalytic function. A trans-acting deoxyribozyme that can process an external substrate was also successfully designed. Stretches of 30 and 17 nucleotides from the 5′ and 3′ ends of the trans catalyst, respectively, were found to be completely dispensable; in contrast, few nucleotides could be deleted internally without producing a detrimental effect. The reselection experiment led to the discovery of 7 and 5 absolutely conserved nucleotides located at the 5′ and 3′ ends of the minimized catalyst, respectively, separated by a 31-nt element in which 14 highly conserved nucleotides were scattered among 17 variable nucleotides. The shortened deoxyribozyme and the original catalyst showed a similar pH profile with the optimal activity at pH 3; however, the minimized deoxyribozyme still exhibited strong catalytic activity at pH 2.5, while the full-length catalyst was barely active at this pH. Finally, it was found that this deoxyribozyme generated two cleavage fragments, one with 2′,3′-cyclic phosphate and the other with 5′-OH.Key words: DNA, deoxyribozyme, RNA cleavage, in vitro selection, catalysis.

Characterization of long RNA-cleaving deoxyribozymes with short catalytic cores: the effect of excess sequence elements on the outcome of in vitro selection

We previously conducted an in vitro selection experiment for RNA-cleaving deoxyribozymes, using a combinatorial DNA library containing 80 random nucleotides. Ultimately, 110 different sequence classes were isolated, but the vast majority contained a short14-15 nt catalytic DNA motif commonly known as 8-17. Herein, we report extensive truncation experiments conducted on multiple sequence classes to confirm the suspected catalytic role played by 8-17 and to determine the effect of excess sequence elements on the activity of this motif and the outcome of selection. Although we observed beneficial, detrimental and neutral consequences for activity, the magnitude of the effect rarely exceeded 2-fold. These deoxyribozymes appear to have survived increasing selection pressure despite the presence of additional sequence elements, rather than because of them. A new deoxyribozyme with comparable activity, called G15-30, was approximately 2.5-fold larger and experienced a approximately 4-fold greater inhibitory effect from excess sequence elements than the average 8-17 motif. Our results suggest that 8-17 may be less susceptible to the potential inhibitory effects of excess arbitrary sequence than larger motifs, which represents a previously unappreciated selective advantage that may contribute to its widespread recurrence.

Phosphoester-transfer mechanism of an RNA-cleaving acidic deoxyribozyme revealed by radioactivity tracking and enzymatic digestion

A convenient method involving 32P-labeling of an RNA substrate at the cleavage site and subsequent enzymatic digestion of cleavage products via phosphatases reveals that pH4DZ1--an RNA-cleaving deoxyribozyme with optimal activity at pH 4--forms a 5'-cleavage fragment with 2',3'-cyclic phosphate group and a 3'-cleavage fragment with 5'-OH group.