Complex formed by complementary RNA stem-loops and its stabilization by a protein: function of CoIE1 Rom protein.

A small plasmid-specified RNA (RNA I) inhibits formation of the RNA primer for CoIE1 DNA replication by binding to its precursor (RNA II). Binding is modulated by the plasmid-specified Rom protein. Both in the presence and absence of Rom, binding starts with interaction between loops of RNAs. To understand the mechanism of binding, we examined the interactions of pairs of single stem-loops that are complementary fragments of RNA I and RNA II. We found that these complementary single stem-loops bind to each other at their loops, forming an RNAase V1-sensitive structure. Rom protects the complex from cleavage and from alkylation of phosphate groups by ethyinitrosourea. A single dimer of Rom binds to the complex by recognizing the structure rather than its exact nucleotide sequence. Rom enhances complex formation by decreasing the rate of dissociation of the complex. Structures of RNA complexes formed in the presence and absence of Rom are proposed.     

Control of ColE1 plasmid replication. Intermediates in the binding of RNA I and RNA II.

Replication of plasmid ColE1 is regulated by a plasmid-specified small RNA (RNA I). RNA I binds to the precursor (RNA II) of the primer for DNA synthesis and inhibits primer formation. The process of binding of RNA I to RNA II that results in formation of a stably bound complex consists of a series of reactions forming complexes differing in the stability. Formation of a very unstable early intermediate that was previously inferred from the inhibition of stable binding caused by a second RNA I species was firmly established by more extensive studies. This complex is converted to a more stable yet reversible complex that was identified by its RNase sensitivity, which was altered from that of the earlier complex or from that of free RNA I or RNA II. In these complexes, most loops of RNA II interact with their complementary loops of RNA I. The kinetic and structural analyses of the binding process predict formation of a complex interacting at a single pair of complementary loops that precedes formation of these complexes. Thus the process of binding of RNA I to RNA II is seen to consist of a sequence of reactions producing a series of progressively more stable intermediates leading to the final product.     

High copy number of the pUC plasmid results from a Rom/Rop-suppressible point mutation in RNA II

The plasmids pUC18 and pUC19 are pBR322 derivatives that replicate at a copy number several fold higher than the parent during growth of Escherichia coli at 37 degrees C. We show here that the high copy number of pUC plasmids results from a single point mutation in the replication primer, RNA II, and that the phenotypic effects of this mutation can be suppressed by the Rom (RNA one modulator)/Rop protein or by lowering the growth temperature to 30 degrees C. The mutation's effects are enhanced by cell growth at 42 degrees C, at which copy number is further increased. During normal cell growth, the pUC mutation does not affect the length or function of RNA I, the antisense repressor of plasmid DNA replication, but may, as computer analysis suggests, alter the secondary structure of pUC RNA II. We suggest that the pUC mutation impedes interactions between the repressor and the primer by producing a temperature-dependent alteration of the RNA II conformation. The Rom/Rop protein may either promote normal folding of the mutated RNA II or, alternatively, may enable the interaction of sub-optimally folded RNA II with the repressor.     

Functional properties of the herpes simplex virus type I origin-binding protein are controlled by precise interactions with the activated form of the origin of DNA replication

The herpes simplex virus, type I origin-binding protein, OBP, is a superfamily II DNA helicase encoded by the UL9 gene. OBP binds in a sequence-specific and cooperative way to the viral origin of replication oriS. OBP may unwind partially and introduce a hairpin into the double-stranded origin of replication. The formation of the novel conformation referred to as oriS* also requires the single-stranded DNA-binding protein, ICP8, and ATP hydrolysis. OBP forms a stable complex with oriS*. The hairpin in oriS* provides a site for sequence-specific attachment, and a single-stranded region triggers ATP hydrolysis. Here we use Escherichia coli exonuclease I to map the binding of the C-terminal domain of OBP to the hairpin and the helicase domains to the single-stranded tail. The helicase domains cover a stretch of 23 nucleotides of single-stranded DNA. Using streptavidin-coated magnetic beads, we show that OBP may bind two copies of double-stranded DNA (one biotin-labeled and the other one radioactively labeled) but only one copy of oriS*. It is the length of the single-stranded tail that determines the stoichiometry of OBP.DNA complexes. OBP interacts with the bases of the single-stranded tail, and ATP hydrolysis is triggered by position-specific interactions between OBP and bases in the single-stranded tail of oriS*.     

A novel conformation of the herpes simplex virus origin of DNA replication recognized by the origin binding protein

The Herpes simplex virus type I origin binding protein (OBP) is a sequence-specific DNA-binding protein and a dimeric DNA helicase encoded by the UL9 gene. It is required for the activation of the viral origin of DNA replication oriS. Here we demonstrate that the linear double-stranded form of oriS can be converted by heat treatment to a stable novel conformation referred to as oriS*. Studies using S1 nuclease suggest that oriS* consists of a central hairpin with an AT-rich sequence in the loop. Single-stranded oligonucleotides corresponding to the upper strand of oriS can adopt the same structure. OBP forms a stable complex with oriS*. We have identified structural features of oriS* recognized by OBP. The central oriS palindrome as well as sequences at the 5' side of the oriS palindrome were required for complex formation. Importantly, we found that mutations that have been shown to reduce oriS-dependent DNA replication also reduce the formation of the OBP-oriS* complex. We suggest that oriS* serves as an intermediate in the initiation of DNA replication providing the initiator protein with structural information for a selective and efficient assembly of the viral replication machinery.     

The interaction of RNA polymerase II with non-promoter DNA sites.

Various complexes formed between purified RNA polymerase II and simian virus 40 DNA have been characterized with respect to rates of formation, rates of dissociation, and initial velocity of RNA synthesis. Two different types of complexes can form on intact DNA templates. One of these is formed rapidly, but is quite labile; the other forms more slowly, but is moderately stable once formed. The introduction of a single strand break into DNA leads to rapid and stable complex formation, and thus is expected to create the favored binding site. The observed properties of these complexes provide a general framework for describing the interactions of RNA polymerase II at non-promoter DNA sites. This framework appears to be similar to that established for Escherichia coli RNA polymerase interactions, suggesting that the fundamental mode of non-promoter DNA binding is similar for the bacterial, plant, and mammalian enzymes.     

Mapping of a protein-RNA kissing hairpin interface: Rom and Tar-Tar*.

An RNA 'kissing' complex is formed by the association of two hairpins via base pairing of their complementary loops. This sense-antisense RNA motif is used in the regulation of many cellular processes, including Escherichia coli ColE1 plasmid copy number. The RNA one modulator protein (Rom) acts as a co-regulator of ColE1 plasmid copy number by binding to the kissing hairpins and stabilizing their interaction. We have used heteronuclear two-dimensional NMR spectroscopy to map the interface between Rom and a kissing complex formed by the loop of the trans -activation response (Tar) element of immunodeficiency virus 1 (HIV-1) and its complement. The protein binding interface was obtained from changes in amide proton signals of uniformly 15N-labeled Rom with increasing concentrations of unlabeled Tar-Tar*. Similarly, the RNA-binding interface was obtained from changes in imino proton signals of uniformly 15N-labeled Tar with increasing concentrations of unlabeled Rom. Our results are in agreement with previous mutagenesis studies and provide additional information on Rom residues involved in RNA binding. The kissing hairpin interface with Rom leads to a model in which the protein contacts the minor groove of the loop-loop helix and, to a lesser extent, the major groove of the stems.