Octamerization of lambda CI repressor is needed for effective repression of P(RM) and efficient switching from lysogeny.

The CI repressor of bacteriophage lambda is a model for the role of cooperativity in the efficient functioning of genetic switches. Pairs of CI dimers interact to cooperatively occupy adjacent operator sites at O(R) and at O(L). These CI tetramers repress the lytic promoters and activate transcription of the cI gene from P(RM). CI is also able to octamerize, forming a large DNA loop between O(R) and O(L), but the physiological role of this is unclear. Another puzzle is that, although a dimer of CI is able to repress P(RM) by binding to the third operator at O(R), O(R)3, this binding seems too weak to affect CI production in the lysogenic state. Here we show that repression of P(RM) at lysogenic CI concentrations is absolutely dependent on O(L), in this case 3.8 kb away. A mutant defective in this CI negative autoregulation forms a lysogen with elevated CI levels that cannot efficiently switch from lysogeny to lytic development. Our results invalidate previous evidence that Cro binding to O(R)3 is important in prophage induction. We propose the octameric CI:O(R)-O(L) complex increases the affinity of CI for O(R)3 by allowing a CI tetramer to link O(R)3 and the third operator at O(L), O(L)3.

The late-expressed region of the temperate coliphage 186 genome.

The late-lytic region of the genome of bacteriophage 186 encodes the phage proteins that synthesize the complex viral particle and lyse the bacterial host. We report the completion of the DNA sequence of the late region and the assignment of 18 previously identified genes to open reading frames in the sequence. The 186 late region is similar to the late region of phage P2, sharing 26 genes of known function: the single gene for activation of late gene transcription, 6 genes for construction of DNA-containing heads, 16 for tail morphogenesis, and 3 for cell lysis. We identified two 186 late genes with unknown function; one is homologous to previously unrecognised genes in P2, HP1, and phiCTX, and the other may modulate DNA packaging. The 186 late region, like the rest of the genome, lacks the lysogenic conversion genes that are carried by P2, allowing the 186 late region to be transcribed from only three late promoters rather than four. The relative absence of lysogenic conversion genes in 186 suggests that the two phages have evolved to use the lytic and lysogenic reproductive modes to different extents.

DNA binding by the coliphage 186 repressor protein CI.

The cI gene of coliphage 186 maintains lysogeny and confers immunity to 186 infection by repressing the major early promoter, p(R), and the promoter for the late transcription activator gene, p(B). Gel mobility shirt and DNase I footprinting show that CI protein binds to the DNA at p(R) and p(B) and also to sites approximately 300 base pairs upstream and downstream of p(R), called FL and FR. Mutations which cause virulence reduce CI binding to p(R). The biochemical and genetic data identify three CI operators at p(R), two at p(B), and single operators at FL and FR. The operators at the p(B), FL, FR, and central p(R) sites are inverted repeat sequences, separated by 5 base pairs (Type A) or, in the case of p(R), by 4 base pairs (Type A'). A different inverted repeat operator sequence (Type B) is proposed for the binding sites on each side of the central site at p(R). Thus, CI appears to recognize two distinct DNA sequences. CI binds cooperatively to adjacent operators, and binding at p(R) is strongly dependent on these cooperative interactions. A high order CI multimer appears to be the active DNA binding species, even at single operators.

The Escherichia coli retrons Ec67 and Ec86 replace DNA between the cos site and a transcription terminator of a 186-related prophage.

Retrons are unusual, reverse transcriptase-encoding elements found in bacteria. Although there are a number of indications that retrons are mobile elements, their transposition has not been observed. The Escherichia coli retrons Ec67 and Ec86 are different retrons inserted at the same site and we have further characterized this site in search of clues to the mechanism of retron transposition. We confirm, by extending previous sequence analysis, that Ec67 and Ec86 are inserted into prophages related to coliphage 186. Comparison with the recently published sequence of the 186 96-2% region indicates that the retrons have replaced approximately 180 bp of DNA between the phage cohesive end site (cos) and the transcription terminator of a phage DNA-packaging gene. These features--DNA replacement at the insertion site and the location of retron junctions near transcription terminators or DNA cleavage sites--are shared with other retrons and suggest ways in which retron transposition might have occurred.

Defining the SOS operon of coliphage 186.

We have sequenced the LexA-controlled operon of coliphage 186 that carries the tum gene, whose product is necessary for UV induction of the 186 prophage. The operon consists of orf95 and orf97, and we have identified orf95 as the tum gene. The major translation products from orf95 result from internal initiations and modulate Tum activity. Tum is the product of the full-length Orf95 protein. The second gene of the operon, orf97, is of unknown function but, while it has little effect on prophage induction, its presence in the cell totally blocks infection of that cell by 186.

The Cro-like Apl repressor of coliphage 186 is required for prophage excision and binds near the phage attachment site.

The Apl protein of the temperature coliphage 186 represses transcription of the immunity repressor gene and down-regulates lytic transcription. It is shown here that an apl- mutant is competent for lytic development and establishes lysogeny normally but is defective in excision of the prophage. The Apl protein binds between the lytic and lysogenic promoters and also near the phage attachment site, suggesting that its role in excision is direct. Apl thus appears to act as an excisionase as well as a repressor. The pattern of Apl-induced DNase I enhancements indicates that the DNA is bent by Apl. Potential Apl recognition sequences are identified; these sequences are directly repeated several times across each binding region and are spaced 10 or 11 bases apart, suggesting that Apl binds to one face of the DNA helix.

Improved detection of helix-turn-helix DNA-binding motifs in protein sequences.

We present an update of our method for systematic detection and evaluation of potential helix-turn-helix DNA-binding motifs in protein sequences [Dodd, I. and Egan, J. B. (1987) J. Mol. Biol. 194, 557-564]. The new method is considerably more powerful, detecting approximately 50% more likely helix-turn-helix sequences without an increase in false predictions. This improvement is due almost entirely to the use of a much larger reference set of 91 presumed helix-turn-helix sequences. The scoring matrix derived from this reference set has been calibrated against a large protein sequence database so that the score obtained by a sequence can be used to give a practical estimation of the probability that the sequence is a helix-turn-helix motif.

Control of gene expression in the temperate coliphage 186. VIII. Control of lysis and lysogeny by a transcriptional switch involving face-to-face promoters.

The lysogenic and early lytic operons of the temperate coliphage 186 are transcribed divergently. Primer extension mapping of the 5' ends of these in vivo transcripts showed that the rightward lytic promoter, pR, and the leftward lysogenic promoter, pL, are arranged face-to-face, with their transcripts overlapping by 60 bases. We examined the control of transcription from pR and pL using galK as a reporter gene. The product of the lysogenic cI gene strongly repressed pR transcription while allowing pL transcription. The product of the lytic apl gene (formerly CP75) strongly repressed pL transcription while allowing pR transcription. Thus, the cI-pR-pL-apl region functioned as a transcriptional switch, determining whether transcription was lytic or lysogenic. Also, the cI gene product was able to stimulate pL, possibly by alleviating an inhibition of pL transcription caused by convergent transcription from pR. Other consequences of the face-to-face promoter arrangement are discussed.

Systematic method for the detection of potential lambda Cro-like DNA-binding regions in proteins.

We have developed and tested a systematic method for the location and statistical evaluation of potential DNA-binding regions of the lambda Cro type in protein sequences. Using this approach to examine proteins expected to contain such regions, we have been able to compile a statistically homogeneous master set of 37 lambda Cro-like DNA-binding domains. Examination of a protein database revealed other prokaryotic proteins that are similar to this lambda Cro-like group. There are also many DNA-binding proteins that are not found to be significantly similar to the lambda Cro group, consistent with previous suggestions that different types of protein sequence may be able to achieve a similar mode of binding and that there exist other modes of sequence-specific DNA-binding. A useful feature of the method is that it can be applied without a computer.

Control of gene expression in the P2-related template coliphages. III. DNA sequence of the major control region of phage 186.

The PstI fragment (65.5% to 77.4%) of coliphage 186, known genetically to encode the major control genes, has been sequenced, and an analysis performed to assess coding capacity, transcription-translation signals, and to identify any other significant features. Our analysis indicates that the region encodes: seven genes, including the int and cI genes, which overlap, the late control gene B, and two genes, named CP75 and CP76, encoding potential DNA-binding proteins; a promoter pB and terminator tB for the rightward transcription of the B gene, and we predict the existence of this transcript in a lysogen; a promoter pL and terminator tL for leftward transcription that encodes the int and cI genes, and represents the presumed lysogenic transcript; a promoter pR for rightward transcription to give the presumed (early) lytic transcript that is overlapping and convergent with the lysogenic transcript; and finally, a potential operator site for repressor binding in the region of the pR promoter. Preliminary evidence is presented to support this analysis.