Boundaries of the nutL antiterminator of coliphage lambda and effects of mutations in the spacer region between boxA and boxB

Expression plasmid with a very tight two-step control: Int/att-mediated gene inversion with respect to the stationary promoter

A very tightly controlled expression vector was constructed, which was originally designed as to be able to use any promoter, constitutive or regulated. Moreover, in vector pNH46T1, the repressible P(tac)/P(lac) promoters were used to transcribe genes cloned in the proximal multiple cloning site (MCS), which was flanked by convergent attB and attP sites. The gene of interest was cloned into MCS in the OFF orientation, i.e. facing the promoter(s). In such OFF orientation, the cloned gene could not be expressed, and only its anti-sense mRNA could be produced. Four strong rrnBT1 terminators, in a tandem arrangement and proximal to the N-terminal end of the cloned non-inverted gene, were protecting it from any inadvertent transcription originating in the vector. Moreover, the P(tac)/P(lac) promoters/operators are controlled by the LacI(q)ts and LacI(+) repressor(s) that further reduce the basal gene expression in the uninduced state. When induced, the total vector population is converted to the ON orientation by expression of the Int function that inverts the attB and attP-flanked MCS including the cloned gene. This places the gene under direct control of the P(tac)/P(lac) promoters, and thus results in very high expression. An additional feature is the anti-termination system that consists of the promoter-proximal nutL site and the inducible gene N, whose role in the ON state is to overcome the rrnBT1 terminators and any other adventitiously cloned terminators.

N-mediated transcription antitermination in lambdoid phage H-19B is characterized by alternative NUT RNA structures and a reduced requirement for host factors

Gene expression in lambdoid phages in part is controlled by transcription antitermination. For most lambdoid phages, maximal expression of delayed early genes requires an RNA polymerase modified by the phage N and host Nus proteins at RNA NUT sites. The NUT sites (NUTL and NUTR) are made up of three elements: BOXA, BOXB and an intervening spacer sequence. We report on N antitermination in H-19B, a lambdoid phage carrying shiga toxin 1 genes. H-19B N requires NusA, but not two other host factors required by lambda N, NusB and ribosomal protein S10. The H-19B NUT site BOXA is not required, whereas the BOXB is required for N action. H-19B nut sites have dyad symmetries in the spacer regions that are not in other nut sites. Changes in one arm of the dyad symmetry inactivate the NUT RNA. Compensating changes increasing the number of mutant nucleotides but restoring dyad symmetry restore activity. Deletion of the sequences encoding the dyad symmetry has little effect. Thus, the specific nucleotides composing the dyad symmetry seem relatively unimportant. We propose that the RNA stem-loop structure, called the 'reducer', by sequestering nucleotides from the linear RNA brings into proximity sites on either side of the dyad symmetry that contribute to forming an active NUT site.

Construction of lacIts and lacIqts expression plasmids and evaluation of the thermosensitive lac repressor

To characterize a thermosensitive lacIts mutant isolated by Bukrinsky et al. [Gene 70 (1989) 415-417] and to adapt it as a convenient control element, we have (i) mapped the mutation to the inducer-binding domain of the LacIts repressor, (ii) determined that the mutation resulted in the loss of a HaeIII site in lacIts due to a G-->A transition, leading to a Gly187-->Ser substitution, (iii) removed extraneous lacZop DNA downstream of lacI, and (iv) cloned lacIts (in plasmids based on ori of either ColE1 or P15A) under control of the wild-type or lacIq promoters. The LacIts repressor is insensitive to IPTG. The repression of lacZop by LacIts is very efficient at 30 degrees C and total induction was achieved at 42 degrees C, providing that the LacIts concentrations are not excessive and that repressor-to-operator ratios are not too high.

Escherichia coli genome targeting, I. Cre-lox-mediated in vitro generation of ori- plasmids and their in vivo chromosomal integration and retrieval

We have constructed a plasmid system designed for the insertion of cloned DNA (e.g., genes, gene fusions, regulatory elements, etc.) into the Escherichia coli genome. Its principal feature is the presence of two tandem lox sites on the plasmids, which upon Cre-mediated in vitro recombination resolve the plasmids into ori- and ori+ DNA circles. The non-replicating ori- circles contain the lambda attP site, several unique restriction sites for cloning, a NotI site and KmR, a kanamycin-resistance-encoding gene. The ori+ circles carry the origin of DNA replication (ori) together with several cleavage sites not present in the ori- circles, including the rare site for the very efficient I-SceI enzyme, that are used to inactivate the ori+ circles and any unresolved plasmid DNA. We have used this system to insert cloned DNA into the host genome at (i) the attB site, by Int-mediated integration and (ii) at any predetermined sequence, as mediated by the Rec system(s) of the host. The genomes of the resulting transformants were analyzed by NotI digestion of the chromosomal DNA, embedded in agarose microbeads, followed by pulsed-field gel electrophoresis. A system for the retrieval of DNA fragments inserted at the attB site was also developed.

Class-IIS restriction enzymes--a review

Class-IIS restriction enzymes (ENases-IIS) interact with two discrete sites on double-stranded DNA: the recognition site, which is 4-7 bp long, and the cleavage site, usually 1-20 bp away from the recognition site. The recognition sequences of ENases-IIS are totally (or partially) asymmetric and all of the characterized ENases-IIS are monomeric. A total of 35 ENases-IIS are described (80, if all isoschizomers are taken into consideration) together with ten related ENases (class IIT), and 15 cognate methyltransferases (MTases-IIS). The physical, chemical, and molecular properties of the ENases-IIS and MTases-IIS are reviewed and many unique applications of this class of enzymes are described, including: precise trimming of DNA; retrieval of cloned fragments; gene assembly; use as a universal restriction enzyme; cleavage of single-stranded DNA; detection of point mutations; tandem amplification; printing-amplification reaction; and localization of methylated bases.

Bacteriophage Mu sites and functions involved in the inhibition of lambda::mini-Mu growth

To better understand the nature of the mini-Mu-directed process which results in inhibition of lambda::mini-Mu growth we characterized spontaneous deletion mutants of the lambda::mini-Mu phage. On the basis of analysis of the deletion endpoints, mini-Mu replication functions, and integration and inhibition properties, the lambda::mini-Mu deletion mutants were divided into five classes which define the Mu sites and functions involved in lambda::mini-Mu growth inhibition. Class 1 mutants, which still exhibit lambda::mini-Mu growth inhibition, collectively delete all the Mu late functions encoded by the mini-Mu. Class 2 and 5 mutants, which show cis-dominant defects in inhibition and integration, delete the right and left mini-Mu attachment sites, respectively. Phages of Classes 3 and 4, which delete the Mu B or A and B genes, respectively, show recessive defects in growth inhibition. The properties of these mutants define the Mu replication functions, A and B, and the Mu attachment sites as essential for the inhibition of lambda::mini-Mu growth. The observation that the sites and functions essential for Mu replication also have requisite roles in the inhibition of lambda::mini-Mu growth suggests that inhibition results from mini-Mu-promoted replicative interference of lambda::mini-Mu development.

The role of the direct repeat in qut-controlled antitermination in phage lambda

For antitermination of transcription from the late p'R promoter of phage lambda, a cis-acting qut sequence, which overlaps with p'R, is required, together with the product of lambda gene Q. Using our BspMI-mediated multicycle technique for generation of precise deletions, we have confirmed that deletions removing DNA downstream of +18 bp (counted from the p'R-controlled transcriptional start point s'R = +1) do not affect the efficiency of qut antitermination; at the same time we found that deleting one more bp (shifting the right-hand boundary to bp +17) reduces antitermination by only 20%. Deleting another 5 or 6 bp (+11 or +12 bp right-hand qut boundary), decreases antitermination by about 80%. These deletions reduce the 9/10-bp-direct repeat (5'-TGGGT(A or T)AATT)2 in qut to only the five italicized bp. Similar strong reduction in antitermination (by about 68%) was obtained with +16 bp qut boundaries, in constructs which also contained 2- or 3-bp insertions between bp +11 and +12 or between +12 and +13. Since the latter deletions retain only 5/10 bp of the direct repeat, it appears that antitermination is dependent on the length and intactness of the direct repeat.

An MboII/FokI trimming plasmid allowing consecutive cycles of precise 1- to 12-base-pair deletions in cloned DNA

A novel trimming plasmid has been designed which allows, in a preprogrammed fashion, the precise deletion of up to 12 bp per cleavage cycle, from one end of a cloned fragment. The plasmid, which carries the dhfr gene, contains unique recognition sites for two class-IIS restriction enzymes, MboII and FokI, which are arranged in the form of a cassette, so that consecutive cleavages with these endonucleases, followed by blunting with mung bean nuclease (MB), will precisely delete 12 bp of adjacent cloned DNA. When either MboII or FokI is used alone (followed by MB), 1 or 4 bp are removed, respectively. The final step in the trimming cycle is religation of the plasmid with T4 ligase. After required number of cycles, plasmids were transformed into Escherichia coli C600, and transformants selected by resistance to trimethoprim. Since the MboII/FokI cassette remains intact during these operations, one can repeat the cycle, consisting of cleaving, MB blunting and religation, several times, each time removing up to 12 bp from the cloned target DNA. Examples are provided of one-, two- and three-cycle trimmings.

Ribosomal RNA operon anti-termination. Function of leader and spacer region box B-box A sequences and their conservation in diverse micro-organisms

All Escherichia coli rrn operons show a common motif in which anti-terminator box B-box A sequences occur twice, first in the leader and again in the 16 S-23 S spacer. In this study we have analyzed several aspects of rrn anti-termination by leader and spacer anti-terminator sequences. Using DNA synthesis and a plasmid test system, we incorporated random changes into the leader anti-terminator region and examined these mutations for their ability to read through a strong terminator. We also examined anti-termination by synthetic box A and by rrn spacer region sequences. Information derived from these experiments was used to search the rrn sequences of other micro-organisms for possible anti-termination features. Our principal conclusions were that: (1) box A was sufficient for terminator readthrough; (2) we could show no positive requirement for box B in our test system; (3) many of the negative anti-terminator mutations caused a promoter up-effect in the absence of a terminator; (4) the search of rrn operons from other micro-organisms revealed that anti-terminator-like box B-box A sequences exist in leader and spacer regions of both eubacteria and archaebacteria. The frequent occurrence of this pattern suggested that the E. coli rrn anti-termination motif is widespread in nature and has been conserved in microbial evolution.

An Escherichia coli cis-acting antiterminator sequence: the dnaG nut site

The Escherichia coli rpsU-dnaG-rpoD operon contains an internal transcription terminator T1 located in the intergenic region between the rpsU and dnaG genes (Smiley et al. 1982). By cloning T1 as a small 127 bp fragment into the terminator probe plasmid pDR720 between the trp operator promoter and the assayable galK gene, it was shown that T1 acts as a strong transcription terminator, comparable in strength to the 3' operon terminator T2. However, an operon sequence that occurs 5' to T1 within the coding region of the rpsU gene and which has homology with the lambda nut site, (Lupski et al. 1983) when placed 5' to T1 in the pDR720 plasmid construct, modifies transcription through T1 allowing expression of the galK gene. This sequence, called the dnaG nut site also modifies the termination activity of the external operon terminator T2. It is proposed that the dnaG nut site is a cis-acting element of an antitermination system in E. coli.

Repression of transcription from the b2-att region of coliphage lambda by integration host factor

The central b2-att region of coliphage lambda is known to be transcriptionally active in vitro, but silent in vivo in lambda lysogens. To explain such in vivo repression of transcription originating in the b2-att region, we explored the effect of the Escherichia coli integration host factor (IHF), the product of E. coli genes himA and himD, especially since the att region contains several IHF-binding sites. Using various lambda DNA templates, we mapped the transcripts which are initiated in vitro in the attP region by the RNA polymerase and found that there are three rightward (RI, RII, and RIII) and one leftward (LI) transcripts. All four of them are repressed by a factor of about 10 by 10 micrograms IHF/ml. Moreover, in in vivo experiments we found that plasmids carrying the attP fragment cannot be established and maintained in IHF-hosts. These results indicate that IHF may play a significant auxiliary role in repressing transcription in the prophage state.

Antisense RNA does not significantly affect expression of the galK gene of Escherichia coli or the N gene of coliphage lambda

The effect of antisense RNA on the expression of genes galK and N was studied in vivo. These two genes were either present in the Escherichia coli chromosome, as single copies, or were cloned on plasmid vectors. Antisense RNA was supplied from multicopy vectors where the entire galK or N gene, or only their N-proximal portions, were cloned in the antisense orientation downstream from the strong PL, PR or lacZp promoters. In all of the experiments there was no significant inhibition of the galK or N expression by up to a 50-fold excess of the specific antisense RNAs, for both the in cis and in trans experimental designs. The excess of the antisense RNA was calculated as based on respective copy numbers, but was not experimentally measured. The apparent five-fold regulatory effect observed in one of the experiments was found to be artifactually caused by unexpected creation of a terminator in one of our constructs. To avoid such artifacts, all our constructs were equipped with the nut-N antitermination system. We conclude that the reported antimessenger-mediated inhibition of gene expression is not a general phenomenon, but must require some special features which are not present in the galK and N systems.

Control of cloned gene expression by promoter inversion in vivo: construction of improved vectors with a multiple cloning site and the Ptac promoter

We have constructed three gene-expression plasmids which contain (an) invertible promoter(s) and a multiple cloning site. We used either the plac promoter or the ptac-plac tandem promoters, the latter directing a more than fourfold increase in expression of the galK reporter gene in Escherichia coli host. All these plasmids were derived from the pNH7a expression plasmid of Podhajska et al. [Gene 40 (1985) 163-168]. Like pNH7a, these vectors have three novel properties: (i) in the 'OFF phase', the promoter is facing away from the gene to be expressed, (ii) the 'ON phase' is attained by the rapid and efficient inversion of the promoter mediated by the phage lambda Int product and the flanking attP and attB sites, which have a divergent orientation, and (iii) only a short heat pulse is required for the efficient inversion of the promoter and switching from the OFF to the ON phase. As for the pNH7 a vector, the present plasmids contain the nut-N transcriptional antitermination system, which permits efficient gene expression even if terminator(s) happen to be present between the promoter(s) and the expressed gene. The promoter inversion is rapid and over 95% efficient, as assayed by restriction analysis and galactokinase assay. Many genes could be conveniently cloned in the multiple cloning site, and then either kept totally silent or expressed in a rigidly controlled manner. Moreover, the pNH8, pNH16 and pNH18 plasmids, with already inverted promoters, could be used for expression of cloned genes, either in an unregulated manner or regulated by the lac repressor. They would be particularly useful for genes associated with terminators affecting their expression.

Determination of the nucleotide sequence for the glutamate synthase structural genes of Escherichia coli K-12

We have determined the complete nucleotide sequence of a 6.3-kb chromosomal HpaI-EcoRI fragment, that contains the structural genes for both the large and small subunits of the Escherichia coli K-12 glutamate synthase (GOGAT) enzyme, as well as the 5'- and 3'-flanking and intercistronic DNA regions. The Mrs of the two subunits, as deduced from the nucleotide (nt) sequence, were estimated as 166,208 and 52,246. Partial amino acid sequence of the GOGAT enzyme revealed that the large subunit starts with a cysteine residue that is probably generated by a proteolytic cleavage. Northern blotting experiments revealed a transcript of approximately 7300 nt, that at least contains the cistrons for both subunits. A transcriptional start point and a functional promoter were identified in the 5' DNA flanking region of the large subunit gene. The messenger RNA nontranslated leader region has 120 nt and shares identity with the leader regions of E. coli ribosomal operons, in particular around the so-called boxA sequence implicated in antitermination. Other possible regulatory sequences are described.

Effect of the promoter structure on the nutL transcription antitermination function

Several boxA-less 74-bp nutL antiterminator fragments do not function as antiterminators of plac-promoted transcription, but are active with the pp and p'R promoters at 30 degrees C. At elevated temperatures (42 degrees C), these defective 74-bp nutL modules retain 50% of their activity when controlled by the p'R promoter; with the pp promoter the antitermination activity is 5-10 times less efficient. Similarly, deletions of 1-3 bp in the spacer region between the boxA and boxB subunits of nutL (which abolish antitermination promoted by plac), allow rather efficient but thermosensitive antitermination when controlled by the pp or p'R promoter. These results point to possible conditional interactions between the promoter and antiterminator elements and functions. Also noted were unexpectedly slow mobilities of the p'R-nutL-bearing fragments, suggesting some unusual secondary structures.

A novel multistep method for generating precise unidirectional deletions using BspMI, a class-IIS restriction enzyme

A novel approach is described that permits the introduction of unidirectional deletions into a cloned DNA fragment, in a precisely controlled manner. The method is based on the use of a special vector and a class-IIS restriction endonuclease, BspMI, which produces staggered cuts 4 and 8 nucleotides (nt) to the 3' from its recognition site 5'-ACCTGC-3'. The DNA fragment is inserted into the pUC19-based plasmid, which contains a unique BspMI recognition site, and the appropriate number of cleavage-and-deletion cycles is performed, each cycle removing 4 bp. Since the recognition site is not affected by the BspMI cleavage, no recloning of the DNA fragment is necessary. Each cycle consists of BspMI cleavage, removal of the 4-nt single-stranded cohesive ends with mung bean nuclease (MB), and blunt-end ligation to recircularize the plasmid. The shortened plasmid is reintroduced into the host, after one or after several such 4-bp deletion cycles. When DNA is inserted into the multiple cloning site in the lacZ alpha gene, the progress of 4-bp removal can be followed by determining the Lac phenotype, since removal of multiples of 3 bp retains the reading frame while other kinds of deletions distort (or restore) the reading frame. Loss of pre-existing restriction sites or creation of new ones also permits monitoring the progress of the deletion process.(ABSTRACT TRUNCATED AT 250 WORDS)