4S oop RNA is a leader sequence for the immunity-establishment transcription in coliphage lambda

Coliphage lambda to terminator lowers the stability of messenger RNA in Escherichia coli hosts

The effects of the transcription terminators to and tfd on the overall high-level expression of a human interferon-beta gene (IFN-beta) in Escherichia coli hosts were compared. Deletion mapping shows that mRNA lability is caused by sequences at or near the lambda terminator to stem-loop structure. Extensive RNA secondary structure in this region indicates a potential RNase III cleavage/binding site. In RNase III- E. coli hosts, IFN-beta synthesis is indeed considerably enhanced. The bacteriophage tfd terminator does not confer this mRNA labilization phenomenon. In all cases, RNA level and stability correlate with the level of IFN-beta synthesized in the cell. In the system described, ongoing translation stabilizes mRNA only moderately.

Transcription termination: sequence and function of the rho-independent tL3 terminator in the major leftward operon of bacteriophage lambda

For cloning, assaying the function and sequencing terminators, we have constructed the pD12 plasmid, in which the late promotor p'R of phage lambda controls the expression of the galK gene of the pK03 plasmid of McKenney et al. (1981). The lambda tL3 terminator region was cloned in this plasmid between the promoter and the galK gene, and found to be 90-94% effective in preventing galactokinase expression in both rho+ and rho- hosts. Is is also active in vitro, both in the presence or absence of the rho factor. The termination point is located at 4320 bp to the left of the SL startpoint of the PL-RNA, just downstream of gene exo. We have sequenced 356 bp of the hitherto uncharted lambda DNA to the right of the TaqI cut, which in turn is 110 bp to the right of the b522 deletion at 63.9% lambda. The tL3 terminator has several features common to other rho-independent termination sequences, including an 81% G+C-rich region of 2X8-bp symmetry ("stem") with a 5-bp intervening "loop", partially overlapping and followed by a sequence transcribed into the pyrimidine-rich CCUUUCU-OH 3' terminus of the RNA. The termination point that follows the last U was determined by the S1 mapping technique.

Overlap between ampC and frd operons on the Escherichia coli chromosome

The promoter for the Escherichia coli ampC beta-lactamase gene is shown to be located within the last gene of the fumarate reductase (frd) operon. Evidence is presented that the ampC attenuator serves as the terminator for transcription of this preceding operon. The nucleotide sequence was determined for two proteins that were shown to be encoded by a DNA segment preceding the ampC gene. The two proteins consisted of 131 and 119 triplets and had molecular weights of 15,000 and 13,100, respectively. The twelve COOH-terminal amino acids of the 13,100 molecular weight protein were found to overlap the ampC promoter. Accordingly, a G.C insertion in the promoter gave both increased transcription of ampC and a frameshift in this overlapping gene, resulting in readthrough proteins. Thus, we describe a type of very compact genetic organization of operons in prokaryotes.

Promoter for the establishment of repressor synthesis in bacteriophage lambda

Transcription of the lambda repressor gene (cI) is positively regulated by the phage-encoded proteins cII and cIII. We have isolated and characterized the 5'-terminal region of this RNA and shown that it originates at a promoter (pE) located between genes cro and cII. The DNA sequence of this promoter shows little homology to other known promoters. Initiation of transcription from PE is abolished by the cis-dominant mutations cY; these mutations alter the "-10" and "-35" regions of the promoter. We propose that the "-35" region is the site of activation of PE, possibly via the direct interaction of protein cII.

A comprehensive molecular map of bacteriophage lambda

Physical and genetic mapping of deletion mutations has been correlated with the available molecular sizes of the lambda gene products and the DNA base sequence to construct a comprehensive molecular map of the phage lambda genome. The physical length of the DNA making up the left arm from the cos site through gene J is not sufficient to account in a nonoverlapping manner for all the proteins of the sizes reported to be coded, especially in the Nu1--C region. In the right arm all the coding capacity has not been accounted for, and it appears to be oversaturated only in the gam-ral region. The positions of several IS and Tn elements, and of restriction endonuclease cleavage sites are specified.

Primary structure of an EcoRI fragment of lambda imm434 DNA containing regions cI-cro of phage 434 and cII-o of phage lambda

Digestion of phage lambda imm434 DNA with restriction endonuclease EcoRI yields 7 fragments. The shortest among them (1287 bp) contains the right part of the phage 434 immunity region and the phage DNA portion proximal to it. The complete primary structure of this fragment has been determined using the chemical method of DNA sequencing. Hypothetical amino-acid sequences of proteins coded by the cro gene of phage 434 and the cII gene of phage lambda, as well as NH2-terminal amino-acid sequences of the cI protein of phage 434 and the O protein of phage lambda, have been deduced solely on the basis of the DNA sequence. The fragment studied contains also the pR and probably prm promoters and the oR operator of phage 434. The sequence coding for them differs from the respective DNA sequence of phage lambda.

Inceptor and origin of DNA replication in lambdoid coliphages. I. The lambda DNA minimal replication system

In a pBR313-lambda dv hybrid plasmid system, stepwise deletion and serial cloning procedures have led to a functional dissection of the DNA replication region of lambdoid bacteriophages lambda, 434 and 21. A simple system for initiation of DNA replication has been detected within lambdoid replicator DNAs, which is active in the absence of several normal replication elements, including the origin of replication (ori) and product of gene O. This "minimal" (or "mini") initiation system depends on the p0 or substitute leftward promoter in conjunction with the newly discovered "inceptor" (ice) element, which is located within the cII gene. Even the fragments containing ori are unable to initiate replication in these hybrid plasmids as long as fragments containing ice are missing. The base sequence of ice resembles transcriptional terminators and it appears to control both termination of primer RNA and inception of daughter strand DNA synthesis. Initiation in the p0-ice mini system of lambda or 21 phages requires the gene P product. Hwever, mini replication of 434 DNA hybrid plasmids required neither O nor P proteins, although there are only two single-base changes in the 434 inceptor sequence. The mini system is repressed by the elements of the maximal lambda replication system, as described in the accompanying publication.

Bacteriophage lambda mutants (lambdatp) that overproduce repressor

Lambda tp mutants, selected for their ability to form turbid plaques on lon hosts, overproduce repressor. The tp1 and tp2 mutations have been located within (or adjacent to) the cIII gene. The tp1 mutation reduced late gene expression, as measured by endolysin synthesis (in the absence of functional cI repressor) and progeny phage yield. The tp4 mutation was mapped in the cY-cII region, and complementation tests indicated that tp4 affects the diffusible product of the cII gene. The tp4 mutation also reduced progeny production, but did not markedly affect endolysin synthesis.

Regulation of the int gene of bacteriophage lambda: activation by the cII and cIII gene products and the role of the Pi and Pl promoters

The activation of the int gene by the cII and cIII gene products was studied by analysing int expression following infection of UV-irradiated cells by various phage mutants. Residual expression of int, probably from Pl, takes place in the absence of cII/cIII activation. Activation of the int gene, like that of the cI repressor gene, is poor at low multiplicities of infection. The mutation intC, which allows constitutive int expression in the lysogenic state, partially relieves the requirement for cII and cIII activation. The kinetics of Int synthesis after addition of the inhibitor rifampicin suggest that the activation occurs at the transcriptional level.

Control of lambda repressor prophage and establishment transcription by the product of gene tof

Control of expression of the bacteriophage lambda (lambda) repressor was studied by measuring repressor transcription in noninduced and derepressed lambda lysogens. Three distinct modes of leftward transcription were observed from cI and the adjacent genes associated with the control of repressor synthesis: The prophage or maintenance mode Prm-cI-rex-ti repressor transcript occurs from repressed lysogens; the oop (Po-oop-to) transcript, and the lit (lit-ti) RNA, from the distal half of gene rex, both occur from induced tof+ prophage; the repressor establishment mode of transcription is observed throughout the rex-cI-tof-y-cII-oop interval between Po and ti from induced tof- prophage. The overall level of establishment mRNA synthesis is partially template dependent. However, the actual initiation step for repressor establishment transcription requires the participation of the lambda cIII, cII products, and also either requires the activity of Escherichia coli replication proteins, or is triggered by a replication initiation event. The cII cIII products do not positively stimulate de novo initiation of establishment transcription, but rather act after an initial replication-dependent step. Initiation of the establishment mode of repressor transcription is totally inhibited by more than 125-fold, in an all or none fashion, by the lambda antirepressor (Tof), the product of gene tof (cro). Since Tof only reduces the in vivo rightward transcription of cII from Pr by about 2-fold, we suggest that Tof inhibits repressor establishment transcription by either uncoupling the replication and cII-cIII dependent events, or by inhibiting the activity rather than the expression of the cIII, cII products. Our results do not fully support either of the present hypotheses that establishment transcription is initiated from the hypothetical Pre promoter in the y-interval, or arises through antitermination of the oop RNA. Since the initiation and control of the establishment mode of repressor transcription parallels the control of lit RNA synthesis, we propose a common mechanism underlies the initiation of these transcripts.

Nucleotide sequence of cro, cII and part of the O gene in phage lambda DNA

A nucleotide sequence comprising 960 base pairs of bacteriophage lambda DNA has been determined. The sequence includes the entire genes of the regulatory proteins cro and cII, and part of the O gene, together with control elements for their transcription and translation. The right-hand boundaries of the lambdaimm434 and lambdaimm21 substitutions and the cy42 mutation have been located.

The relationship between function and DNA sequence in an intercistronic regulatory region in phage lambda

rho factor-mediated transcription termination at the tr1 terminator site of bacteriophage lambda is examined. Mutations affecting the termination event are characterised. These mutations define features of the site which seem to be important to terminator function. In addition, other related transcriptional and translational regulatory elements are defined within the region surrounding the termination site. The potential molecular interactions and structural overlaps of these control signals apparently couple the regulation of the decision between lytic and lysogenic growth patterns by phage lambda.

DNA base sequence of the po promoter region of phage lamdba

The sequence of a 123 base pair HpaII restriction fragment of bacteriophage lamdba DNA has been determined by the dimethylsulphate-hydrazine technique. Of this fragment 65 nucleotide pairs are transcribed into the 5' proximal part of the oop RNA. The remaining 58 nucleotide pairs preceding the start point of transcription show homologies to the lamdbaL and lamdbapR promoter regions, and are concluded to contain the lamdbapo promoter sequence.