A stationary-phase-dependent viability block governed by two different polypeptides from the RhsA genetic element of Escherichia coli K-12.

Multicopy plasmids bearing a small internal portion of the RhsA genetic element of Escherichia coli K-12 imparted a viability block on cultures grown to stationary phase in broth. Inclusion of the last 25 codons of the RhsA core open reading frame (called core-ORF) in the plasmid insert was crucial for eliciting this toxic effect. The toxic effect could be suppressed by including the adjacent Rhs component, dsORF-a1, on the multicopy plasmid. The toxic effect was enhanced in RpoS- strains.

Rhs elements of Escherichia coli: a family of genetic composites each encoding a large mosaic protein.

The Rhs family comprises a set of composite elements found in the chromosomes of many natural Escherichia coli strains. Five Rhs elements occur in strain K-12. The most prominent Rhs component is a giant core open reading frame (core ORF) whose features are suggestive of a cell surface ligand-binding protein. This hypothetical protein contains a peptide motif, xxGxxxRYxYDxxGRL(I or T)xxxx, that is repeated 28 times. A similar repeated motif is found in a Bacillus subtilis wall-associated protein. The Rhs core ORFs consist of two distinct parts: a large N-terminal core that is conserved in all Rhs elements, and a smaller C-terminus that is highly variable. Distinctive G+C contents of Rhs components indicate that the elements have a recent origin outside the E. coli species, and that they are composites assembled from segments with very different evolutionary histories. The Rhs cores fall into three sub-families that are mutually more than 20% divergent. Downstream of the core ORF is a second, much shorter ORF. Like the adjacent core extension, these are highly variable. In most examples, the hypothetical product of this ORF has a candidate signal sequence for transport across the cytoplasmic membrane. Another Rhs component, the 1.3 kb H-rpt, has features typical of insertion sequences. Structures homologous to H-rpt have been detected in other bacterial genera, such as Vibrio and Salmonella, where they are associated with loci that determine O-antigen variation.

Rhs elements of Escherichia coli K-12: complex composites of shared and unique components that have different evolutionary histories.

The complete sequences of the RhsB and RhsC elements of Escherichia coli K-12 have been determined. These sequence data reveal a new repeated sequence, called H-rpt (Hinc repeat), which is distinct from the Rhs core repetition that is found in all five Rhs elements. H-rpt is found in RhsB, RhsC, and RhsE. Characterization of H-rpt supports the view that the Rhs elements are composite structures assembled from components with very different evolutionary histories and that their incorporation into the E. coli genome is relatively recent. In each case, H-rpt is found downstream from the Rhs core and is separated from the core by a segment of DNA that is unique to the individual element. The H-rpt's of RhsB and RhsE are very similar, diverging by only 2.1%. They are 1,291 bp in length, and each contains an 1,134-bp open reading frame (ORF). RhsC has three tandem copies of H-rpt, all of which appear defective in that they are large deletions and/or have the reading frame interrupted. Features of H-rpt are analogous to features typical of insertion sequences; however, no associated transposition activity has been detected. A 291-bp fragment of H-rpt is found near min 5 of the E. coli K-12 map and is not associated with any Rhs core homology. The complete core sequences of RhsB and RhsC have been compared with that of RhsA. As anticipated, the three core sequences are closely related, all having identical lengths of 3,714 bp each. Like RhsA, the RhsB and RhsC cores constitute single ORFs that begin with the first core base. In each case, the core ORF extends beyond the core into the unique sequence. Of the three cores, RhsB and RhsA are the most similar, showing only 0.9% sequence divergence, while RhsB and RhsC are the least similar, diverging by 2.9%. All three cores conserve the 28 repetitions of a peptide motif noted originally for RhsA. A secondary structure is proposed for this motif, and the possibility of its having an extracellular binding function is discussed. RhsB contains one additional unique ORF, and RhsC contains two additional unique ORFs. One of these ORFs includes a signal peptide that is functional when fused to TnphoA.

Structure of the rhsA locus from Escherichia coli K-12 and comparison of rhsA with other members of the rhs multigene family.

The complete nucleotide sequence of the rhsA locus and selected portions of other members of the rhs multigene family of Escherichia coli K-12 have been determined. A definition of the limits of the rhsA and rhsC loci was established by comparing sequences from E. coli K-12 with sequences from an independent E. coli isolate whose DNA contains no homology to the rhs core. This comparison showed that rhsA comprises 8,249 base pairs (bp) in strain K-12 and that the Rhs0 strain, instead, contains an unrelated 32-bp sequence. Similarly, the K-12 rhsC locus is 9.6 kilobases in length and a 10-bp sequence resides at its location in the Rhs0 strain. The rhsA core, the highly conserved portion shared by all rhs loci, comprises a single open reading frame (ORF) 3,714 bp in length. The nucleotide sequence of the core ORF predicts an extremely hydrophilic 141-kilodalton peptide containing 28 repeats of a motif whose consensus is GxxxRYxYDxxGRL(I or T). One of the most novel aspects of the rhs family is the extension of the core ORF into the divergent adjacent region. Core extensions of rhsA, rhsB, rhsC, and rhsD add 139, 173, 159, and 177 codons to the carboxy termini of the respective core ORFs. For rhsA, the extended core protein would have a molecular mass of 156 kilodaltons. Core extensions of rhsB and rhsD are related, exhibiting 50.3% conservation of the predicted amino acid sequence. However, comparison of the core extensions of rhsA and rhsC at both the nucleotide and the predicted amino acid level reveals that each is highly divergent from the other three rhs loci. The highly divergent portion of the core extension is joined to the highly conserved core by a nine-codon segment of intermediate conservation. The rhsA and rhsC loci both contain partial repetitions of the core downstream from their primary cores. The question of whether the rhs loci should be considered accessory genetic elements is discussed but not resolved.

Errant processing and structural alterations of genomes present in a varicella-zoster virus vaccine.

Five minority populations of aberrant, varicella-zoster virus (VZV)-derived genomes were identified among the encapsidated DNAs obtained from the nuclear and cytoplasmic fractions of an in vitro infection initiated with a lyophilized sample of the BIKEN VZV vaccine (strain Oka). These were (i) VZV genomes, present within nuclear but not cytoplasmic viral capsids, which had been cleaved at a specific site within the short segment and which were, therefore, 3.15 megadaltons (approximately 4% of the VZV genome length) short of full length; (ii) highly deleted, repetitive VZV genomes which contained the errant cleavage site but not the usual VZV genome terminal sequences; (iii) VZV genomes into which multiples of 1 through 5 defective genome repeat units had been inserted into a homologous site; (iv) VZV genomes with additions of 0.1 or 0.18 megadaltons of DNA at both the terminal and internal ends of the short segment; and (v) VZV DNA which had lost the HindIII restriction site at map position 0.11.

Site-specific cleavage/packaging of herpes simplex virus DNA and the selective maturation of nucleocapsids containing full-length viral DNA.

Defective genomes present in serially passaged herpes simplex virus (HSV) stocks have been shown to consist of tandemly arranged repeat units containing limited sets of the standard virus DNA sequences. Invariably, the HSV defective genomes terminate with the right (S component) terminus of HSV DNA. Because the oligomeric forms can arise from a single repeat unit, it has been concluded that the defective genomes arise by a rolling circle mechanism of replication. We now report on our studies of defective genomes packaged in viral capsids accumulating in the nuclei and in mature virions (enveloped capsids) translocated into the cytoplasm of cells infected with serially passaged virus. These studies have revealed that, upon electrophoresis in agarose gels, the defective genomes prepared from cytoplasmic virions comigrated with nondefective standard virus DNA (M(r) 100 x 10(6)). In contrast, DNA prepared from capsids accumulating in nuclei consisted of both full-length defective virus DNA molecules and smaller DNA molecules of discrete sizes, ranging in M(r) from 5.5 to 100 x 10(6). These smaller DNA species were shown to consist of different integral numbers (from 1 to approximately 18) of defective genome repeat units and to terminate with sequences corresponding to the right terminal sequences of HSV DNA. We conclude on the basis of these studies that (i) sequences from the right end of standard virus DNA contain a recognition signal for the cleavage and packaging of concatemeric viral DNA, (ii) the sequence-specific cleavage is either a prerequisite for or occurs during the entry of viral DNA into capsid structures, and (iii) DNA molecules significantly shorter than full-length standard viral DNA can become encapsidated within nuclear capsids provided they contain the cleavage/packaging signal. However, capsids containing DNA molecules significantly shorter than standard virus DNA are not translocated into the cytoplasm.

Replication of herpes simplex virus DNA: localization of replication recognition signals within defective virus genomes.

Serially passaged herpes simplex virus type 1 (HSV-1) strain Justin was previously shown to contain defective virus genomes consisting of head-to-tail reiterations of sequences derived from the end of the S component of the standard virus DNA. Cotransfection of purified monomeric defective genome repeat units with foster helper virus DNAs onto rabbit skin cells resulted in regeneration and replication of concatemeric defective DNA molecules which were successfully encapsidated. Thus, defective HSV-1 (Justin) genomes contain, within their limited DNA sequences, a sufficient set of recognition sites required for HSV DNA replication and packaging. The arrangement of repeat units within the regenerated defective virus genomes was consistent with their replication by a rolling circle mechanism in which a single repeat unit served as the circularized template. This replication occurred most actively late after infection and could be shown to be inhibited by low concentrations of phosphonoacetate known to inhibit the HSV-specified viral DNA polymerase selectively. The resultant concatemers were shown to be cleaved to Mr 100 X 10(6) DNA molecules which were terminated at one end with the proper ac end sequence of the parental standard virus DNA.