Use of circular permutation to assess six bulges and four loops of DNA-packaging pRNA of bacteriophage phi29.

A 120-base phage phi29 encoded RNA (pRNA) has a novel role in DNA packaging. This pRNA possesses five single-base bulges, one three-base bulge, one bifurcation bulge, one bulge loop, and two stem loops. Circularly permuted pRNAs (cpRNA) were constructed to examine the function of these bulges and loops as well as their adjacent sequences. Each of the five single-base bulges was nonessential. The bifurcation bulge could be deleted and replaced with a new opening to provide flexibility for maintaining an overall correct folding in three-way junction. All of these nonessential bulges or their adjacent bases could be used as new termini for cpRNAs. The three-base (C18C19A20) bulge was dispensable for procapsid binding, but was indispensable for DNA packaging. The secondary structure around this CCA bulge and the phylogenetically conserved bases within or around it were investigated. Bases A14C15U16 were confirmed, by compensatory modification, to pair with U103G102A101. A99 was needed only to allow the proper folding of CCA bulge in the appropriate sequence order and distance constraints. Beyond these, the seemingly phylogenetic conservation of other bases has little role in pRNA activity. Each of the three stem loops was essential for procapsid binding, DNA packaging, and phage assembly. Disruption of the middle of any one of the loops resulted in dramatic reductions in procapsid binding, subsequent DNA packaging, and phage assembly activities. However, disruption of the loops at sequences that were close to double-stranded regions of the RNA did not interfere with pRNA activity significantly. Our results suggest that double-stranded helical regions near these loops were most likely not involved in interactions with components of the DNA-packaging machinery. Instead, these regions appear to be merely present to serve as a scaffolding to display the single-stranded loops that are important for pRNA tertiary structure or for interaction with the procapsid or other packaging components.     

Binding of pRNA to the N-terminal 14 amino acids of connector protein of bacteriophage phi29

During assembly, bacterial virus phi29 utilizes a motor to insert genomic DNA into a preformed protein shell called the procapsid. The motor contains one twelve-subunit connector with a 3.6 nm central channel for DNA transportation, six viral-encoded RNA (packaging RNA or pRNA) and a protein, gp16, with unknown stoichiometry. Recent DNA-packaging models proposed that the 5-fold procapsid vertexes and 12-fold connector (or the hexameric pRNA ring) represented a symmetry mismatch enabling production of a force to drive a rotation motor to translocate and compress DNA. There was a discrepancy regarding the location of the foothold for the pRNA. One model [C. Chen and P. Guo (1997) J. Virol., 71, 3864–3871] suggested that the foothold for pRNA was the connector and that the pRNA–connector complex was part of the rotor. However, one other model suggested that the foothold for pRNA was the 5-fold vertex of the capsid protein and that pRNA was the stator. To elucidate the mechanism of phi29 DNA packaging, it is critical to confirm whether pRNA binds to the 5-fold vertex of the capsid protein or to the 12-fold symmetrical connector. Here, we used both purified connector and purified procapsid for binding studies with in vitro transcribed pRNA. Specific binding of pRNA to the connector in the procapsid was found by photoaffinity crosslinking. Removal of the N-terminal 14 amino acids of the gp10 protein by proteolytic cleavage resulted in undetectable binding of pRNA to either the connector or the procapsid, as investigated by agarose gel electrophoresis, SDS–PAGE, sucrose gradient sedimentation and N-terminal peptide sequencing. It is therefore concluded that pRNA bound to the 12-fold symmetrical connector to form a pRNA–connector complex and that the foothold for pRNA is the connector but not the capsid protein.     

Confirmation of the helical structure of the 5'/3' termini of the essential DNA packaging pRNA of phage phi 29.

Bacteriophage phi 29 is typical of double-stranded DNA viruses in that its genome is packaged into a preformed procapsid during viral assembly. An intriguing feature of phi 29 is the presence of a 120-base virus-encoded RNA (pRNA) that is indispensable for DNA packaging. Phylogenetic comparison of similar RNAs in numerous phages has revealed that the secondary structure of the pRNA is well conserved. Computer analysis predicts the presence of an extensive segment of helix with three single-base bulges generated by the pairing of the 5' and 3' ends. The desire to understand the role played by the pRNA in DNA packaging has led to a mutational analysis of the 5'-/3'-terminal region, which is believed to be important in DNA translocation. Deletion of 3 bases from the 3' end of the RNA, shortening the pRNA from 120 to 117 bases, was tolerated without loss of activity, but additional deletion of the base 117 resulted in 100-fold less activity, and a 115-base pRNA was virtually nonfunctional. Additionally, the three unpaired one-base bulges within the helical stretches of the paired proximate ends were nonessential for pRNA activity, as demonstrated by deletion of the bulge individually. An extensive series of helix disruptions by single- and multiple-base substitution almost invariably led to the loss of DNA packaging activity. Additional mutations that restored predicted base pairings rescued pRNA activity. This second site suppression confirmed that the 5'- and 3'-end region was paired and was indeed a helical stretch. The secondary structure was of greater importance than the primary sequence, with the exception of the requirement of an adenine at either the third or fourth position. The specific requirement of an adenine in phi 29 pRNA at this position, as well as conservation of this position in other phage pRNAs, implicates that this base may play a special role in either the DNA-packaging reaction or the maintenance of the pRNA tertiary structure.     

DNA packaging motor assembly intermediate of bacteriophage phi29

Unraveling the structure and assembly of the DNA packaging ATPases of the tailed double-stranded DNA bacteriophages is integral to understanding the mechanism of DNA translocation. Here, the bacteriophage phi29 packaging ATPase gene product 16 (gp16) was overexpressed in soluble form in Bacillus subtilis (pSAC), purified to near homogeneity, and assembled to the phi29 precursor capsid (prohead) to produce a packaging motor intermediate that was fully active in in vitro DNA packaging. The formation of higher oligomers of the gp16 from monomers was concentration dependent and was characterized by analytical ultracentrifugation, gel filtration, and electron microscopy. The binding of multiple copies of gp16 to the prohead was dependent on the presence of an oligomer of 174- or 120-base prohead RNA (pRNA) fixed to the head-tail connector at the unique portal vertex of the prohead. The use of mutant pRNAs demonstrated that gp16 bound specifically to the A-helix of pRNA, and ribonuclease footprinting of gp16 on pRNA showed that gp16 protected the CC residues of the CCA bulge (residues 18-20) of the A-helix. The binding of gp16 to the prohead/pRNA to constitute the complete and active packaging motor was confirmed by cryo-electron microscopy three-dimensional reconstruction of the prohead/pRNA/gp16 complex. The complex was capable of supercoiling DNA-gp3 as observed previously for gp16 alone; therefore, the binding of gp16 to the prohead, rather than first to DNA-gp3, represents an alternative packaging motor assembly pathway.     

Complete inhibition of virion assembly in vivo with mutant procapsid RNA essential for phage phi 29 DNA packaging.

A highly efficient method for the inhibition of bacteriophage phi 29 assembly was developed with the use of mutant forms of the viral procapsid (or packaging) RNA (pRNA) indispensable for phi 29 DNA packaging. Phage phi 29 assembly was severely reduced in vitro in the presence of mutant pRNA and completely blocked in vivo when the host cell expressed mutant pRNA. Addition of 45% mutant pRNA resulted in a reduction of infectious virion production by 4 orders of magnitude, indicating that factors involved in viral assembly can be targets for efficient and specific antiviral treatment. The mechanism leading to the high efficiency of inhibition was attributed to two pivotal features. First, the pRNA contains two separate, essential functional domains, one for procapsid binding and the other for a DNA-packaging role other than procapsid binding. Mutation of the DNA-packaging domain resulted in a pRNA with no DNA-packaging activity but intact procapsid binding competence. Second, multiple copies of the pRNA were involved in the packaging of one genome. This higher-order dependence of pRNA in viral replication concomitantly resulted in its higher-order inhibitory effect. This finding suggested that the collective DNA-packaging activity of multiple copies of pRNA could be disrupted by the incorporation of perhaps an individual mutant pRNA into the group. Although this mutant pRNA could not be used for the inhibition of the replication of other viruses directly, the principle of using molecules with two functional domains and multiple-copy involvement as targets for antiviral agents could be applied to certain viral structural proteins, enzymes, and other factors or RNAs involved in the viral life cycle. This principle also implies a strategy for gene therapy, intracellular immunization, or construction of transgenic plants resistant to viral infection.     

Controlling bacteriophage phi29 DNA-packaging motor by addition or discharge of a peptide at N-terminus of connector protein that interacts with pRNA

Bacteriophage phi29 utilizes a motor to translocate genomic DNA into a preformed procapsid. The motor contains six pRNAs, an enzyme and one 12-subunit connector with a central channel for DNA transportation. A 20-residue peptide containing a His-tag was fused to the N-terminus of the connector protein gp10. This fusion neither interfered with procapsid assembly nor affected the morphology of the prolate-shaped procapsid. However, the pRNA binding and virion assembly activity were greatly reduced. Such decreased functions can be switched back on by the removal of the tag via protease cleavage, supporting the previous finding that the N-terminus of gp10 is essential for the pRNA binding. The DNA-packaging efficiency with dimeric pRNA was more seriously affected by the extension than with monomeric pRNA. It is speculated that the fusion of the tag generated physical hindrance to pRNA binding, with greater influence for the dimers than the monomers due to their size. These results reveal a potential to turn off and turn on the motor by attaching or removing, respectively, a component to outer part of the motor, and offers an approach for the inhibition of viral replication by using a drug or a small peptide targeted to motor components.     

Approaches to determine stoichiometry of viral assembly components.

Due to the rapidity of biological reactions, it is difficult to isolate intermediates or to determine the stoichiometry of participants in intermediate reactions. Instead of determining the absolute amount of each component, this study involved the use of relative parameters, such as dilution factors, percentages probabilities, and slopes of titration curves, that can be more accurately quantified to determine the stoichiometry of components involved in bacteriophage phi29 assembly. This work takes advantage of the sensitive in vitro phage phi29 assembly system, in which 10(8) infectious virions per ml without background can be assembled from eight purified components. It provides a convenient assay for quantification of the stoichiometry of packaging components, including the viral procapsid, genomic DNA, DNA-packaging pRNA, and other structural proteins and enzymes. The presence of a procapsid binding domain and another essential functional domain within the pRNA makes it an ideal component for constructing lethal mutants for competitive procapsid binding. Two methods were used for stoichiometry determination. Method 1 was to determine the combination probability of mutant and wild-type pRNAs bound to procapsids. The probability of procapsids that possess a certain amount of mutant and a certain amount of wild-type pRNA, both with an equal binding affinity, was predicted with the binomial equation [EQUATION IN TEXT] where Z is the total number of pRNAs per procapsid, M is the number of mutant pRNAs bound to one procapsid, and (ZM) is equal to [FORMULA IN TEXT]. With various ratios of mutant to wild-type pRNA in in vitro viral assembly, the percent mutant pRNA versus the yield of virions was plotted and compared to a series of predicted curves to find a best fit. It was determined that five or six copies of pRNA were required for one DNA-packaging event, while only one mutant pRNA per procapsid was sufficient to block packaging. Method 2 involved the comparison of slopes of curves of dilution factors versus the yield of virions. Components with known stoichiometries served as standard controls. The larger the stoichiometry of the component, the more dramatic the influence of the dilution factor on the reaction. A slope of 1 indicates that one copy of the component is involved in the assembly of one virion. A slope larger than 1 would indicate multiple-copy involvement. By this method, the stoichiometry of gp11 in phi29 particles was determined to be approximately 12. These approaches are useful for the determination of the stoichiometry of functional units involved in viral assembly, be they single molecules or oligomers. However, these approaches are not suitable for the determination of exact copy numbers of individual molecules involved if the functional unit is composed of multiple subunits prior to assembly.     

Boundary of pRNA functional domains and minimum pRNA sequence requirement for specific connector binding and DNA packaging of phage phi29.

Bacteriophage phi29 utilizes a viral-encoded 120-base RNA (pRNA) to accomplish dsDNA packaging into a preformed procapsid. Six pRNAs bind to the procapsid and work sequentially. The pRNA contains two functional domains, one for binding to the DNA translocating connector, and the other for interacting with another component of the DNA packaging machinery during DNA translocation. By UV crosslinking, the pRNA was found to bind to the connector specifically and not to the capsid or scaffolding proteins. When purified connectors were incubated with pRNA, rosette-like connector oligomers were observed. These oligomers were found to contain pRNA. A series of deletion mutants of the pRNA were constructed and their ability to perform various tasks involved in phi29 assembly were assayed. The minimum sizes of the pRNA needed for the following activities have been determined: (1) specific binding to procapsid or to connectors; (2) connector or procapsid binding with full efficiency compared with wild-type pRNA; and (3) genomic DNA packaging. In summary, bases 37-91 (55 nt) comprised the minimum sequence required for specific connector binding, although with lower efficiency; bases 6-113 (105 nt with the additional deletion of two nonessential bases, C109 and A106) comprised the minimum sequence required for full connector binding activity; and bases 1-117 comprised the minimum sequence needed for full DNA packaging activity. These data indicate clearly that the helical region composed of bases 1-6 and 113-117 plays a crucial role in DNA translocation, but is dispensable for connector binding. A model for the role of the pRNA in DNA packaging was also presented.     

Magnesium-induced conformational change of packaging RNA for procapsid recognition and binding during phage phi29 DNA encapsidation.

Bacteriophage phi29 is typical of double-stranded DNA viruses in that its genome is packaged into a preformed procapsid during maturation. An intriguing feature of phi29 assembly is that a virus-encoded RNA (pRNA) is required for the packaging of its genomic DNA. Psoralen cross-linking, primer extension, and T1 RNase partial digestion revealed that pRNA had at least two conformations; one was able to bind procapsids, and the other was not. In the presence of Mg2+, one stretch of pRNA, consisting of bases 31 to 35, was confirmed to be proximal to base 69, as revealed by its efficient cross-linking by psoralen. Two cross-linking sites in the helical region were identified. Mg2+ induced a conformational change of pRNA that exposes the portal protein binding site by promoting the refolding of two strands of the procapsid binding region, resulting in the formation of pRNA-procapsid complexes. The procapsid binding region in this binding-competent conformation could not be cross-linked with psoralen. When the two strands of the procapsid binding region were fastened by cross-linking, pRNA could neither bind procapsids nor package phi29 DNA. A pRNA conformational change was also discernible by comparison of migration rates in native EDTA and Mg2+ polyacrylamide gel electrophoresis and was revealed by T1 RNase probing. The Mg2+ concentration required for the detection of a change in pRNA cross-linking patterns was 1 mM, which was the same as that required for pRNA-procapsid complex formation and DNA packaging and was also close to that in normal host cells.     

Sequence requirement for hand-in-hand interaction in formation of RNA dimers and hexamers to gear phi29 DNA translocation motor.

Translocation of DNA or RNA is a ubiquitous phenomenon. One intricate translocation process is viral DNA packaging. During maturation, the lengthy genome of dsDNA viruses is translocated with remarkable velocity into a limited space within the procapsid. We have revealed that phi29 DNA packaging is accomplished by a mechanism similar to driving a bolt with a hex nut, which consists of six DNA-packaging pRNAs. Four bases in each of the two pRNA loops are involved in RNA/RNA interactions to form a hexagonal complex that gears the DNA translocating machine. Without considering the tertiary interaction, in some cases only two G/C pairs between the interacting loops could provide certain pRNAs with activity. When all four bases were paired, at least one G/C pair was required for DNA packaging. The maximum number of base pairings between the two loops to allow pRNA to retain wild-type activity was five, whereas the minimum number was five for one loop and three for the other. The findings were supported by phylogenetic analysis of seven pRNAs from different phages. A 75-base RNA segment, bases 23-97, was able to form dimer, to interlock into the hexamer, to compete with full-length pRNA for procapsid binding, and therefore to inhibit phi29 assembly in vitro. Our result suggests that segment 23-97 is a self-folded, independent domain involved in procapsid binding and RNA/RNA interaction in dimer and hexamer formation, whereas bases 1-22 and 98-120 are involved in DNA translocation but dispensable for RNA/RNA interaction. Therefore, this 75-base RNA could be a model for structural studies in RNA dimerization.     

Counting of six pRNAs of phi29 DNA-packaging motor with customized single-molecule dual-view system

Direct imaging or counting of RNA molecules has been difficult owing to its relatively low electron density for EM and insufficient resolution in AFM. Bacteriophage phi29 DNA-packaging motor is geared by a packaging RNA (pRNA) ring. Currently, whether the ring is a pentagon or hexagon is under fervent debate. We report here the assembly of a highly sensitive imaging system for direct counting of the copy number of pRNA within this 20-nm motor. Single fluorophore imaging clearly identified the quantized photobleaching steps from pRNA labeled with a single fluorophore and concluded its stoichiometry within the motor. Almost all of the motors contained six copies of pRNA before and during DNA translocation, identified by dual-color detection of the stalled intermediates of motors containing Cy3-pRNA and Cy5-DNA. The stalled motors were restarted to observe the motion of DNA packaging in real time. Heat-denaturation analysis confirmed that the stoichiometry of pRNA is the common multiple of 2 and 3. EM imaging of procapsid/pRNA complexes clearly revealed six ferritin particles that were conjugated to each pRNA ring.     

Role of the CCA bulge of prohead RNA of bacteriophage ø29 in DNA packaging

The oligomeric ring of prohead RNA (pRNA) is an essential component of the ATP-driven DNA packaging motor of bacteriophage ?29. The A-helix of pRNA binds the DNA translocating ATPase gp16 (gene product 16) and the CCA bulge in this helix is essential for DNA packaging in vitro. Mutation of the bulge by base substitution or deletion showed that the size of the bulge, rather than its sequence, is primary in DNA packaging activity. Proheads reconstituted with CCA bulge mutant pRNAs bound the packaging ATPase gp16 and the packaging substrate DNA-gp3, although DNA translocation was not detected with several mutants. Prohead/bulge-mutant pRNA complexes with low packaging activity had a higher rate of ATP hydrolysis per base pair of DNA packaged than proheads with wild-type pRNA. Cryoelectron microscopy three-dimensional reconstruction of proheads reconstituted with a CCA deletion pRNA showed that the protruding pRNA spokes of the motor occupy a different position relative to the head when compared to particles with wild-type pRNA. Therefore, the CCA bulge seems to dictate the orientation of the pRNA spokes. The conformational changes observed for this mutant pRNA may affect gp16 conformation and/or subsequent ATPase-DNA interaction and, consequently, explain the decreased packaging activity observed for CCA mutants.     

The procapsid binding domain of phi29 packaging RNA has a modular architecture and requires 2'-hydroxyl groups in packaging RNA interaction

The phi29 packaging RNA (pRNA) is an essential component in the phi29 bacteriophage DNA packaging motor, the strongest biomolecular motor known today. Utilizing Mg2+-dependent intermolecular base pairing interactions between two 4-nucleotide loops within the pRNA procapsid binding domain, multiple copies of pRNA form a ring-shaped complex that is indispensable for packaging motor function. To understand pRNA structural organization and pRNA/pRNA interaction, studies were carried out on pRNA closed dimers, the simplest functional pRNA complex believed to be the building blocks for assembling the oligomeric ring. Tertiary folding and interactions in various pRNA mutants were evaluated based on measured closed dimer affinity that is directly linked to the proper positioning of the interacting loops. The data revealed that the procapsid binding domain contains two autonomous modules that are capable of interacting noncovalently to form a fully active species in pRNA/pRNA interaction. Deleting the 2'-hydroxyl groups in one of the interacting loops weakens the dimer affinity by 125-fold, suggesting potential tertiary interactions involving these 2'-hydroxyl groups. The results provide evidence that nonbase functional groups are involved in pRNA folding and interaction and lead to a simple model that describes the pRNA monomer configuration in terms of three arms spanning a hinge. The functional constructs developed here will aid biophysical and biochemical investigations of pRNA structure and function, as well as developments of pRNA-based technology for nanoscience and gene therapy.     

Crystal structure of 3WJ core revealing divalent ion-promoted thermostability and assembly of the Phi29 hexameric motor pRNA

The bacteriophage phi29 DNA packaging motor, one of the strongest biological motors characterized to date, is geared by a packaging RNA (pRNA) ring. When assembled from three RNA fragments, its three-way junction (3WJ) motif is highly thermostable, is resistant to 8 M urea, and remains associated at extremely low concentrations in vitro and in vivo. To elucidate the structural basis for its unusual stability, we solved the crystal structure of this pRNA 3WJ motif at 3.05 Å. The structure revealed two divalent metal ions that coordinate 4 nt of the RNA fragments. Single-molecule fluorescence resonance energy transfer (smFRET) analysis confirmed a structural change of 3WJ upon addition of Mg²⁺. The reported pRNA 3WJ conformation is different from a previously published construct that lacks the metal coordination sites. The phi29 DNA packaging motor contains a dodecameric connector at the vertex of the procapsid, with a central pore for DNA translocation. This portal connector serves as the foothold for pRNA binding to procapsid. Subsequent modeling of a connector/pRNA complex suggests that the pRNA of the phi29 DNA packaging motor exists as a hexameric complex serving as a sheath over the connector. The model of hexameric pRNA on the connector agrees with AFM images of the phi29 pRNA hexamer acquired in air and matches all distance parameters obtained from cross-linking, complementary modification, and chemical modification interference.     

Sequential action of six virus-encoded DNA-packaging RNAs during phage phi29 genomic DNA translocation.

A 120-base pRNA encoded by bacteriophage b29 has a novel and essential role in genomic DNA packaging. Six DNA-packaging RNAs (pRNAs) were bound to the sixfold symmetrical portal vertex of procapsids during the DNA translocation process and left the procapsid after the DNA-packaging reaction was completed, suggesting that the pRNA participated in the translocation of genomic DNA into procapsids. To further investigate the mechanism of DNA packaging, it is crucial to determine whether these six pRNA molecules work as an integrated entity or each pRNA acts as a functional individual. If pRNAs work individually, then do they work in sequence with communication or in random order without interaction? Results from compensation and complementation analysis did not support the integrated model. Computation of the probability of combination between wild-type and mutant pRNAs and experimental data of competitive inhibition excluded the random model while favoring the proposal that the six pRNAs functioned sequentially. Sequential action of the pRNA also explains why the pRNA is so sensitive to mutation, since the effect of a pRNA mutation will be amplified by 6 orders of magnitude after six consecutive steps, resulting in the observed complete loss of DNA-packaging activity caused by small alterations. When any one of the six pRNAs was replaced with an inactive one, complete blockage of DNA packaging resulted, strongly supporting the speculation that individual pRNAs, presumably together with other components such as the packaging ATPase gp16, take turns mediating successive steps of packaging. Although the data provided here could not exclude the integrated model completely, there is no evidence so far to argue against the model of sequential action.     

The functional domains of bacteriophage t4 terminase

The packaging of double-stranded genomic DNA into some viral and all bacteriophage capsids is driven by powerful molecular motors. In bacteriophage T4, the motor consists of the portal protein assembly composed of twelve copies of gene product 20 (gp20, 61 kDa) and an oligomeric terminase complex composed of gp16 (18 kDa) and gp17 (70 kDa). The packaging motor drives the 171-kbp T4 DNA into the capsid utilizing the free energy of ATP hydrolysis. Evidence suggests that gp17 is the key component of the motor; it exhibits ATPase, nuclease, and in vitro DNA-packaging activities. The N- and C-terminal halves of gp17 were expressed and purified to homogeneity and found to have ATPase and nuclease activities, respectively. The N-terminal domain exhibited 2-3-fold higher Kcat values for gp16-stimulated ATPase than the full-length gp17. Neither of the domains, individually or together, exhibited in vitro DNA-packaging activity, suggesting that communication between the domains is essential for DNA packaging. The domains, in particular the C-terminal domain or a mixture of both the N- and C-terminal domains, inhibited in vitro DNA packaging that is catalyzed by full-length gp17. In conjunction with genetic evidence, these data suggest that the domains compete with the full-length gp17 for binding sites on the portal protein. A model for the assembly of the T4 DNA-packaging machine is presented.     

Mapping the inter-RNA interaction of bacterial virus phi29 packaging RNA by site-specific photoaffinity cross-linking

During replication, the lengthy genome of double-stranded DNA viruses is translocated with remarkable velocity into a limited space within the procapsid. The question of how this fascinating task is accomplished has long been a puzzle. Our recent investigation suggests that phi29 DNA packaging is accomplished by a mechanism similar to the driving of a bolt with a hex nut and that six packaging RNAs (pRNAs) form a hexagonal complex to gear the DNA-translocating machine (Chen, C., and Guo, P. (1997) J. Virol. 71, 3864-3871; Zhang, F., Lemieux, S., Wu, X., St.-Arnaud, S., McMurray, C. T., Major, F., and Anderson, D. (1998) Mol. Cell 2, 141-147; Guo, P., Zhang, C., Chen, C., Garver, K., and Trottier, M., (1998) Mol. Cell 2, 149-155). In the current study, circularly permuted pRNAs were used to position an azidophenacyl photoreactive cross-linking agent specifically at a strategic site that was predicted to be involved in pRNA-pRNA interaction. Cross-linked pRNA dimers were isolated, and the sites of cross-link were mapped by primer extension. The cross-linked pRNA dimer retained full activity in phi29 procapsid binding and genomic DNA translocation, indicating that the cross-link distance constraints identified in dimer formation reflect the native pRNA complex. Both cross-linked dimers either containing or not containing the interlocking loops for programmed hexamer formation bound procapsid equally well; however, only the one containing the interlocking loops programmed for hexamer formation was active in phi29 DNA packaging. The cross-linked pRNA dimers were also identified as the minimum binding unit necessary for procapsid binding. Primer extension of the purified cross-linked pRNA dimers revealed that base G(82) was cross-linked to bases G(39), G(40), A(41), C(49), G(62), C(63), and C(64), which contribute to the formation of the three-way junction, suggesting that these bases are proximate in the formation of pRNA tertiary structure. Interestingly, the photoaffinity agent in the left interacting loop did not cross-link directly to the right loop as expected but cross-linked to bases adjacent to the right loop. These data provide a background for future modeling of pRNA tertiary structure.     

A viral RNA that binds ATP and contains a motif similar to an ATP-binding aptamer from SELEX

The intriguing process of free energy conversion, ubiquitous in all living organisms, is manifested in ATP binding and hydrolysis. ATPase activity has long been recognized to be a capability limited to proteins. However, the presence of an astonishing variety of unknown RNA species in cells and the finding that RNA has catalytic activity have bred the notion that RNA might not be excluded from the group of ATPases. All DNA-packaging motors of double-stranded DNA phages involve two nonstructural components with certain characteristics typical of ATPases. In bacterial virus phi29, one of these two components is an RNA (pRNA). Here we report that this pRNA is able to bind ATP. A comparison between the chemically selected ATP-binding RNA aptamer and the central region of pRNA reveals similarity in sequence and structure. The replacement of the central region of pRNA with the sequence from ATP-binding RNA aptamer produced chimeric aptRNA that is able to both bind ATP and assemble infectious viruses in the presence of ATP. RNA mutation studies revealed that changing only one base essential for ATP binding caused both ATP binding and viral assembly to cease, suggesting that the ATP binding motif is the vital part of the pRNA that forms a hexamer to drive the phi29 DNA-packaging motor. This is the first demonstration of a natural RNA molecule that binds ATP and the first case to report the presence of a SELEX-derived RNA aptamer in living organisms.     

Sequential action of ATPase, ATP, ADP, Pi and dsDNA in procapsid-free system to enlighten mechanism in viral dsDNA packaging

Many cells and double-stranded DNA (dsDNA) viruses contain an AAA⁺ ATPase that assembles into oligomers, often hexamers, with a central channel. The dsDNA packaging motor of bacteriophage phi29 also contains an ATPase to translocate dsDNA through a dodecameric channel. The motor ATPase has been investigated substantially in the context of the entire procapsid. Here, we report the sequential action between the ATPase and additional motor components. It is suggested that the contact of ATPase to ATP resulted in its conformational change to a higher binding affinity toward dsDNA. It was found that ATP hydrolysis led to the departure of dsDNA from the ATPase/dsDNA complex, an action that is speculated to push dsDNA to pass the connector channel. Our results suggest that dsDNA packaging goes through a combined effort of both the gp16 ATPase for pushing and the channel as a one-way valve to control the dsDNA translocation direction. Many packaging models have previously been proposed, and the packaging mechanism has been contingent upon the number of nucleotides packaged per ATP relative to the 10.5 bp per helical turn for B-type dsDNA. Both 2 and 2.5 bp per ATP have been used to argue for four, five or six discrete steps of dsDNA translocation. Combination of the two distinct roles of gp16 and connector renews the perception of previous dsDNA packaging energy calculations and provides insight into the discrepancy between 2 and 2.5 bp per ATP.     

Probing the structure of monomers and dimers of the bacterial virus phi29 hexamer RNA complex by chemical modification

All dsDNA viruses multiply their genome and assemble a procapsid, a protein shell devoid of DNA. The genome is subsequently inserted into the procapsid. The bacterial virus phi29 DNA translocating motor contains a hexameric RNA complex composed of six pRNAs. Recently, we found that pRNA dimers are building blocks of pRNA hexamers. Here, we report the structural probing of pRNA monomers and dimers by chemical modification under native conditions and in the presence or absence of Mg2+. The chemical-modification pattern of the monomer is compared to that of the dimer. The data strongly support the previous secondary-structure prediction of the pRNA concerning the single-stranded areas, including three loops and seven bulges. However, discrepancies between the modification patterns of two predicted helical regions suggest the presence of more complicated, higher-order structure in these areas. It was found that dimers were formed via hand-in-hand and head-to-head contact, as the interacting sequence of the right and left loops and all bases in the head loop were protected from chemical modification. Cryoatomic force microscopy revealed that the monomer displayed a check-mark shape and the dimer exhibited an elongated shape. The dimer was twice as long as the monomer. Direct observation of the shape and measurement of size and thickness of the images strongly support the conclusion from chemical modification concerning the head-to-head contact in dimer formation. Our results also suggest that the role for Mg2+ in pRNA folding is to generate a proper configuration for the right and head loops, which play key roles in this symmetrical head-to-head organization. This explains why Mg2+ plays a critical role in pRNA dimer formation, procapsid binding, and phi29 DNA packaging.