Antitermination and absence of processing of the leftward transcript of coliphage lambda in the RNAase III-deficient host

The antitermination activity of bacteriophage lambda N protein is controlled by the kinetics of an RNA-looping-facilitated interaction with the transcription complex

Protein N of bacteriophage lambda activates the lytic phase of phage development in infected Escherichia coli cells by suppressing the activity of transcriptional terminators that prevent the synthesis of essential phage proteins. N binds tightly to the boxB RNA hairpin located near the 5' end of the nascent pL and pR transcripts and induces an antitermination response in the RNA polymerase (RNAP) of elongation complexes located at terminators far downstream. Here we test an RNA looping model for this N-dependent "action at a distance" by cleaving the nascent transcript between boxB and RNAP during transcript elongation. Cleavage decreases antitermination, showing that an intact RNA transcript is required to stabilize the interaction of boxB-bound N with RNAP during transcription. In contrast, an antitermination complex that also contains Nus factors retains N-dependent activity after transcript cleavage, suggesting that these host factors further stabilize the N-RNAP interaction. Thus, the binding of N alone to RNAP is controlled by an RNA looping equilibrium, but after formation of the initial RNA loop and in the presence of Nus factors the system no longer equilibrates on the transcription time scale, meaning that the "range" of antitermination activity along the template in the full antitermination system is kinetically controlled by the dissociation rate of the stabilized N-RNAP complex. Theoretical calculations of nucleic acid end-to-end contact probabilities are used to estimate the local concentrations of boxB-bound N at elongation complexes poised at terminators, and are combined with N activity measurements at various boxB-to-terminator distances to obtain an intrinsic affinity (K(d)) of approximately 2 x 10(-5) M for the N-RNAP interaction. This RNA looping approach is extended to include the effects of N binding at nonspecific RNA sites on the transcript and the implications for transcription control in other regulatory systems are discussed.

Protection of antiterminator RNA by the transcript elongation complex

Nascent transcripts encoded by the putL and putR sites of phage HK022 bind the transcript elongation complex and suppress termination at downstream transcription terminators. We report here that the chemical stability of putL RNA is considerably greater than that of the typical Escherichia coli message because the elongation complex protects this RNA from degradation. When binding to the elongation complex was prevented by mutation of either putL or RNA polymerase, RNA stability decreased more than 50-fold. The functional modification conferred by putL RNA on the elongation complex is also long-lived: the efficiency of terminator suppression remained high for at least 10 kb from the putL site. We find that RNase III rapidly and efficiently cleaved the transcript just downstream of the putL sequences, but such cleavage changed neither the stability of putL RNA nor the efficiency of antitermination. These results argue that the continuity of the RNA that connects put sequences to the growing point is not required for persistence of the antiterminating modification in vivo.

Conservation and diversity in the immunity regions of wild phages with the immunity specificity of phage lambda

The gene regulatory circuitry of phage lambda is among the best-understood circuits. Much of the circuitry centres around the immunity region, which includes genes for two repressors, CI and Cro, and their cis-acting sites. Related phages, termed lambdoid phages, have different immunity regions, but similar regulatory circuitry and genome organization to that of lambda, and show a mosaic organization, arising by recombination between lambdoid phages. We sequenced the immunity regions of several wild phages with the immunity specificity of lambda, both to determine whether natural variation exists in regulation, and to analyse conservation and variability in a region rich in well-studied regulatory elements. CI, Cro and their cis-acting sites are almost identical to those in lambda, implying that regulatory mechanisms controlled by the immunity region are conserved. A segment adjacent to one of the operator regions is also conserved, and may be a novel regulatory element. In most isolates, different alleles of two regulatory proteins (N and CII) flank the immunity region; possibly the lysis-lysogeny decision is more variable among isolates. Extensive mosaicism was observed for several elements flanking the immunity region. Very short sequence elements or microhomologies were also identified. Our findings suggest mechanisms by which fine-scale mosaicism arises.

The global regulator RNase III modulates translation repression by the transcription elongation factor N

Efficient expression of most bacteriophage lambda early genes depends upon the formation of an antiterminating transcription complex to overcome transcription terminators in the early operons, p(L) and p(R). Formation of this complex requires the phage-encoded protein N, the first gene product expressed from the p(L) operon. The N leader RNA contains, in this order: the NUTL site, an RNase III-sensitive hairpin and the N ribosome-binding site. N bound to NUTL RNA is part of both the antitermination complex and an autoregulatory complex that represses the translation of the N gene. In this study, we show that cleavage of the N leader by RNase III does not inhibit antitermination but prevents N-mediated translation repression of N gene expression. In fact, by preventing N autoregulation, RNase III activates N gene translation at least 200-fold. N-mediated translation repression is extremely sensitive to growth rate, reflecting the growth rate regulation of RNase III expression itself. Given N protein's critical role in lambda development, the level of RNase III activity therefore serves as an important sensor of physiological conditions for the bacteriophage.

Bacillus subtilis RNase III cleaves both 5'- and 3'-sites of the small cytoplasmic RNA precursor

Bacillus subtilis small cytoplasmic RNA (scRNA) is a member of the signal recognition particle RNA family. It is transcribed as a 354-nucleotide primary transcript and processed to a 271-nucleotide mature scRNA. In the precursor, the 5'- and 3'-flanking regions form a stable double-stranded structure based on their complementary sequence. This structure is similar to those of substrates for the double-stranded RNA processing enzyme, RNase III. The B. subtilis enzyme that has similar activity to Escherichia coli RNase III has been purified and is designated Bs-RNase III. Recently, B. subtilis rncS has been shown to encode Bs-RNase III (Wang, W., and Bechhofer, D. H. (1997) J. Bacteriol. 179, 7379-7385). We show here that Bs-RNase III and the purified His-tagged product of rncS cleave pre-scRNA at both 5'- and 3'-sites to produce an intermediate scRNA (scRNA-275), although processing at the 3'-site is less efficient. The 5'-end of scRNA-275 was identical to that of the mature scRNA, whereas it contains four excess nucleotides at the 3'-end. Bs-RNase III cleavage yields a two-base 3'-overhang, which is consistent with the manner in which E. coli RNase III cleaves. We also show that truncation of the rncS gene affected processing, and significant amounts of an intermediate scRNA (scRNA-275) were found to accumulate in the rncS-truncated mutant. It is concluded that Bs-RNase III is an enzyme that processes pre-scRNA.

Genetic uncoupling of the dsRNA-binding and RNA cleavage activities of the Escherichia coli endoribonuclease RNase III--the effect of dsRNA binding on gene expression

RNase III, a double-stranded RNA-specific endonuclease, is proposed to be one of Escherichia coli's global regulators because of its ability to affect the expression of a large number of unrelated genes by influencing post-transcriptional control of mRNA stability or mRNA translational efficiency. Here, we describe the phenotypes of bacteria carrying point mutations in rnc, the gene encoding RNase III. The substrate recognition and RNA-processing properties of mutant proteins were analysed in vivo by measuring expression from known RNase III-modulated genes and in vitro from the proteins' binding and cleavage activities on known double-stranded RNA substrates. Our results show that although the point mutation rnc70 exhibited all the usual rnc null-like phenotypes, unlike other mutations, it was dominant over the wild-type allele. Multicopy expression of rnc70 could suppress a lethal phenotype of the wild-type rnc allele in a certain genetic background; it could also inhibit the RNase III-mediated activation of lambdaN gene translation by competing for the RNA-binding site of the wild-type endonuclease. The mutant protein failed to cleave the standard RNase III substrates in vitro but exhibited an affinity for double-stranded RNA when passed through poly(rI):poly(rC) columns. Filter binding and gel-shift assays with purified Rnc70 showed that the mutant protein binds to known RNase III mRNA substrates in a site-specific manner. In vitro processing reactions with purified enzyme and labelled RNA showed that the in vivo dominant effect of the mutant enzyme over the wild-type was not necessarily caused by formation of mixed dimers. Thus, the rnc70 mutation generates a mutant RNase III with impaired endonucleolytic activity but without blocking its ability to recognize and bind double-stranded RNA substrates.

Translational repression by a transcriptional elongation factor

One of the classical positive regulators of gene expression is bacteriophage lambda N protein. N regulates the transcription of early phage genes by participating in the formation of a highly processive, terminator-resistant transcription complex and thereby stimulates the expression of genes lying downstream of transcriptional terminators. Also included in this antiterminating transcription complex are an RNA site (NUT) and host proteins (Nus). Here we demonstrate that N has an additional, hitherto unknown regulatory role, as a repressor of the translation of its own gene. N-dependent repression does not occur when NUT is deleted, demonstrating that N-mediated antitermination and translational repression both require the same cis-acting site in the RNA. In addition, we have identified one nut and several host mutations that eliminate antitermination and not translational repression, suggesting the independence of these two N-mediated mechanisms. Finally, the position of nutL with respect to the gene whose expression is repressed is important.

Use of a gene encoding a suppressor tRNA as a reporter of transcription: analyzing the action of the Nun protein of bacteriophage HK022

The Nun protein of phage HK022 blocks the expression of genes that lie downstream of the nut sites of phage lambda. Nun is believed to act by promoting premature termination of transcription at or near these sites. To test this hypothesis and to facilitate mapping the sites of termination, we inserted a gene encoding a suppressor tRNA immediately downstream of the lambda nutL site and determined the effect of Nun on tRNA level. We found that Nun severely reduced the accumulation of mature, biologically active tRNA and promoted the accumulation of short, promoter-proximal transcripts whose 3' ends were dispersed over a 100-nucleotide region downstream of nutL. These results are consistent with the hypothesis that Nun terminates transcription within the region immediately downstream of nutL and are inconsistent with the hypothesis that the only action of Nun is to prevent translation of genes located downstream of the nut site. The stability, small size, and easily assayable biological function of suppressor tRNA recommend it as a reporter of transcription in other systems.

Transcriptional antitermination

Antiterminator proteins control gene expression by recognizing control signals near the promoter and preventing transcriptional termination which would otherwise occur at sites that may be a long way downstream. The N protein of bacteriophage lambda recognizes a sequence in the nascent RNA, and modifies RNA polymerase by catalysing the formation of a stable ribonucleoprotein complex on its surface, whereas the lambda Q protein recognizes a sequence in the DNA. These mechanisms of antitermination in lambda provide models for analysing antitermination in viruses such as HIV-1 and in eukaryotic genes.

Elongation factor NusG interacts with termination factor rho to regulate termination and antitermination of transcription

NusG is a transcriptional elongation factor in Escherichia coli that aids transcriptional antitermination by the phage lambda N protein. By using NusG affinity chromatography, we found that NusG binds directly and selectively to termination factor rho. NusG was shown previously to be needed for termination by rho in vivo, and we show here that NusG increases the efficiency of termination by rho at promoter-proximal sites in vitro. The rho026 mutation makes termination by rho less dependent on NusG. It also makes antitermination by N at rho-dependent terminators and the binding of rho to NusG temperature sensitive. Therefore, the interaction of NusG with rho is important both for rho-dependent termination and for antitermination by N at rho-dependent terminators.

RNaselll activation of bacteriophage lambda N synthesis

The bacteriophage lambda N gene product is one of the first genes expressed during phage development. N protein allows the expression of other phage genes by altering the transcription elongation process so as to prevent transcription termination. We have found that N levels may be modulated soon after induction or infection. Using N-lacZ fusions, we determined that cells containing RNaselll have at least a fourfold greater expression than cells defective for RNaselll. This effect is exerted at the post-transcriptional level. RNaselll processes an RNA stem structure in the N-leader RNA. Removal of the stem structure by deletion increases N expression and prevents further stimulation by RNaselll. The base of this stable stem is adjacent to the N ribosome binding site. We present a model for control of N synthesis in which this stable stem inhibits ribosome access to the N mRNA.

Characterization of the biochemical properties of recombinant ribonuclease III

An Escherichia coli double strand specific endoribonuclease, RNase III, was cloned, expressed in large amounts, and purified to homogeneity. Enzyme activity was monitored by assaying fractions for the ability to correctly process exogenous RNA containing specific RNase III cleavage sites. DEAE-Sepharose ion exchange chromatography in the presence of a linear KCl gradient (from 0.02 M to 0.75 M) demonstrated that RNase III exists as two distinct forms. One form elutes at a KCl concentration of 0.13 M and the other elutes at 0.33 M. The presence of stoichiometric amounts of the GTP-binding protein Era during purification results in the conversion of the low salt form into the high salt form. Size exclusion chromatography demonstrated that both forms exist as a dimer in solution. In order to investigate the nature of the dimer, protein cross-linking was performed and cross-linked products were detected by silver staining. The protein-protein dimer can be visualized at protein:cross-linker molar ratios as low as 1:15 within 1 minute of exposure to cross-linker in 0.1 M KCl. Upon addition of substrate RNA to the cross-linking reaction a second form of the protein-protein dimer (with a slightly smaller apparent molecular weight) becomes prominent. Induction of the new form is absolutely dependent upon the addition of substrate mRNA to the reaction mixture. We postulate that the RNase III dimer undergoes a dramatic conformational change upon recognition of RNA which we are able to trap by cross-linking.

Escherichia coli glyA mRNA decay: the role of 3' secondary structure and the effects of the pnp and rnb mutations

The Escherichia coli glyA structural gene is followed by two REP sequences and a rho-independent transcription terminator. These sequences are essential for maintaining glyA mRNA stability and gene expression by blocking the 3' to 5' exonucleolytic activities of polynucleotide phosphorylase and ribonuclease II. The results support the model of cooperative endonucleolytic and 3' to 5' exonucleolytic activities in mRNA decay.

Efficient modification of E. coli RNA polymerase in vitro by the N gene transcription antitermination protein of bacteriophage lambda

The N gene protein of bacteriophage lambda prevents termination of transcription by E. coli RNA polymerase. We describe here the conditions of a cell-free reaction system in which pure N stimulates net transcription up to tenfold and therefore nearly stoichiometrically modifies transcribing RNA polymerase molecules. The reaction contains micrococcal nuclease-treated S100 extract derived from E. coli and a plasmid template DNA containing the lambda early promoter PL, the N utilization site nutL, and the Rho-dependent terminator tL1. Stimulation by N in this system is specific and biologically relevant since it is absent with vector pBR322 DNA and with extracts derived from E. coli strains bearing the nusA1 and nusE71 mutations known to block N function in vivo. We use the system to provide further evidence that ribosomes are not necessary for N function and to demonstrate the direct involvement in N function of the NusA protein of E. coli.

Cleavage within an RNase III site can control mRNA stability and protein synthesis in vivo

We report that processing at a cloned bacteriophage T7 RNase III site results in strong stabilization of the mRNA relative to the full-length transcript. In contrast, processing by RNase III of the bacteriophage lambda int transcript leads to rapid degradation of the messenger. It is proposed that the mode of cleavage within the RNase III site determines mRNA stability. Single cleavage leaves part of the phage T7 RNase III site in a folded structure at the generated 3' end and stabilizes the upstream mRNA whereas double cleavage at the lambda int site removes the folded structure and accelerates degradation. In addition, the processed transcript is as active a messenger as the unprocessed one and can direct protein synthesis for longer times. This increased efficiency is accompanied by a proportional (3-4 fold) increase in protein levels. In contrast, processing at the lambda int site reduces Int synthesis. Thus, processing may either stabilize mRNA and stimulate gene expression or destabilize a messenger and prevent protein synthesis. The end result appears to be determined by the mode of cleavage within the RNase III site.

The 5' ends of Escherichia coli lac mRNA

We identified the predominant 5' ends of an mRNA in Escherichia coli to the exact nucleotides. There are four such ends of lac mRNA in fully induced cells. About 70% of the molecules have the reported major in vitro end, A-A-U-U-G (at +1), which is located 38 nucleotides before the A-U-G translation start. Another 15% start with A-U-U-G at +2, and about 8% start with A-U-U-A-G at -52. A fourth class of molecules begin with either A-G, C-A-G, A-C-A-G, or a weak A-C-A-C-A-G (at +24), observed only once. The origins of this latter set (less than or equal to 10% of the total) are not known, but they could represent "ragged" ends of the mRNA when it is degraded to the beginning of the ribosome-protected region of the message. The A-U-U-A-G molecules are probably initiated from an upstream promoter whose position would coincide with the cAMP-CRP DNA binding site for the major promoter.

Conservation of genome form but not sequence in the transcription antitermination determinants of bacteriophages lambda, phi 21 and P22

Comparisons are made among DNA sequences upstream from terminators in both leftwards and rightwards early operons of related coliphages lambda, phi 21 and P22. These sequences include both left and right determinants of response to phage-coded antitermination proteins, "N", as well as the N structural genes themselves. Despite almost total disparity of DNA sequence, the three genomes can be discerned to include the same elements in the same order and spacing: downstream from the early left promoter are sequentially a site of recognition for host nusA protein, a dyad symmetry "nut" essential for N function in lambda, overlapping sites for processing of the transcript by RNAase III and then the N structural genes; downstream from the cro gene on the right are sites of nusA recognition and nut dyad symmetries homologous to those on the left. Because the N proteins of lambda, phi 21 and P22 do not for the most part complement each other, a specific site of N recognition has been postulated for each N-responding operon. The nut dyad symmetry qualifies as such a site, since the loop of the left dyad in lambda is marked by mutations that block N function leftwards, and since DNA sequences here show close homology between the loops of left and right dyads for each phage, but less if not little homology for different phages.

"N" transcription antitermination proteins of bacteriophages lambda, phi 21 and P22

Comparison is made among the amino acid sequences of three transcription antitermination proteins, based upon the DNA sequences of their genes in bacteriophages lambda, phi 21 and P22. The three proteins are all small (about 100 amino acids), hydrophilic and basic, but otherwise show little homology. A basic region near the amino terminus has several amino acid positions common to all three proteins and is the locus of mutations that alter six different amino acid positions inactivating the lambda N protein. A less basic region near the center is the locus of three mutations affecting the interaction of lambda N with host nusA protein. The N gene of phi 21 has an amino terminus more like that of P22, and a carboxy terminus clearly related to that of lambda.

Removal of a terminator structure by RNA processing regulates int gene expression

The int gene of phage lambda encodes a protein involved in site-specific recombination. Its expression is regulated differentially during successive phases of the lambda infective cycle. The gene is transcribed early after infection from one promoter, pL, and later from a second promoter pI. Each transcription event requires different positive activation factors, lambda N and cII proteins, respectively. Transcription from the pI promoter, located adjacent to int, passes through int and terminates 277 nucleotides beyond int at tI. Polymerases initiating at pL transcribe through tI and into the b segment of lambda DNA. The read-through pL transcript is sensitive to cleavage by the endonuclease, RNase III, both in vivo and in vitro. Two specific cuts are made by RNase III in a double-stranded structure about 260 nucleotides beyond int in the location of the tI terminator. Functionally, the processed pL transcript is unable to synthesize the int gene product, whereas the terminated and unprocessed pI transcript expresses int. Interestingly, unprocessed pL transcripts made in hosts defective in RNase III (rnc-) can express int. Thus a correlation exists between processing and negative control of int expression. The place where processing occurs, some 260 nucleotides beyond int, is called sib, and the control of int expression from this site is called retroregulation. Retroregulation by sib is not restricted just to the int gene; we show that if the sib site is cloned beyond a bacterial gene, the gene is controlled by sib and RNase III. Specific models are discussed with respect to control of gene expression by RNase III from a site beyond the controlled gene.

Comparative studies of the effect of DNA superhelicity on in vitro transcription catalyzed by Escherichia coli S100 proteins and purified RNA polymerase

The effect of DNA superhelicity on in vitro transcription catalyzed by purified Escherichia coli RNA polymerase or S100 crude extract proteins was examined at various KCl concentrations. DNA from a recombinant plasmid pMT48 harboring the pL promotor-controlled fused N-trp genes and the pR promotor-controlled tof (cro) gene was employed as a template. Stimulation of transcription by superhelicity is generally more pronounced with the S100 crude extract proteins than with pure RNA polymerase. At KCl concentrations lower than 100 mM with pure RNA polymerase, there is no significant difference in the template activity between the supercoiled and relaxed forms of pMT48 DNA. In contrast, the dependence of efficient template activity on superhelicity is great over a whole range of KCl concentrations from 1.7 to 400 mM in the system using the S100 crude extract. The relative insensitivity of the pR promotor to superhelicity can be observed in either transcription assay system. Analysis of the kinetics of pL-promoted synthesis of trp mRNA indicates that diminished transcription in vitro on a relaxed template results mainly from less frequent RNA chain initiations, but at least in part from premature arrest of the chain elongation.

Processing of procaryotic ribonucleic acid

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Termination of transcription by nusA gene protein of Escherichia coli

The nusA gene protein of Escherichia coli and N gene protein of bacteriophage lambda interact in vitro and cooperate in vivo to prevent transcription termination. In vitro the nusA gene protein causes RNA polymerase to pause in the tR2 terminator region of lambda DNA. A completed termination event at tR2 requires both the nusA gene protein and the previously described E. coli termination factor rho. The nusA gene protein is therefore both a transcription termination factor and a protein which couples antitermination factors to the elongating transcription complex.

Downstream regulation of int gene expression by the b2 region in phage lambda

Expression of the int gene after phage lambda infection normally requires the products of genes cII and cIII. However, when the phage carries a deletion in the nonessential b2 region adjacent to int, efficient synthesis of active Int protein does not require cII and cIII function. This inhibition of Int synthesis by nucleotide sequences downstream from the int structural gene behaves in a cis-dominant fashion in mixed infections. It is specific for PL- and not pI-initiated transcripts. Based on these observations, and those of others, a model is proposed in which Int translation from the pL transcript is inhibited by the interaction of downstream b2 nucleotide sequences and nucleotide sequences in the int region. The data imply a novel temporal mechanism regulating prophage lambda induction: circularization of the prophage genome results in the transposition of inhibitory b2 region sequences next to int and blocks further Int protein synthesis beyond the low level required for excision. As a consequence of this process, the control of int expression is transferred from the pL promoter to pI and the cII/cIII system. Such a genetic regulatory mechanism involving the rearrangement of genetic elements downstream from a structural gene may be of general use during development in other systems.

Chemistry and biology of E. coli ribosomal protein L12

E. coli ribosomal protein L12, because of its unique features, has been studied in more detail than perhaps any of the other ribosomal proteins. Unlike the other ribosomal proteins that are generally present in stoichiometric amounts, there are four copies of L12 per ribosome, some of which are acetylated on the N-terminal serine. The acetylated species, referred to as L7, has not been shown, as yet, to possess any different biological activity than L12. A specific enzyme that acetylates L12 to form L7, using acetyl-CoA as the acetyl donor, has been purified from E. coli extracts. L12 is also unique in that it does not contain cysteine, tryptophan, histidine, or tyrosine, is very acidic (pI: 4.85) and has a high content of ordered secondary structure (approximately 50%). The protein is normally found in solution as a dimer and also forms a tight complex with ribosomal protein L10. There are three methionine residues in L12, located in the N-terminal region of the protein, one or more of which are essential for biological activity. Oxidation of the methionines to methionine sulfoxide prevents dimer formation and inactivates the protein. The four copies of L12 are located in the crest region(s) of the 50S ribosomal subunit. There is good evidence that the soluble factors, such as IF-2, EF-Tu, EF-G and RF, interact with L12 on the ribosome during the process of protein synthesis. This interaction is essential for the proper functioning of each of the factors and for GTP hydrolysis associated with the individual partial reactions of protein synthesis. The L12 gene is located on an operon that contains the genes for L10 and beta beta' subunits of RNA polymerase at about 88 min on the bacterial chromosome. DNA-directed in vitro systems have been used to study the unique regulation of the expression of these genes. Autogenous regulation, translational control, and transcription attenuation are regulatory mechanisms that function to control the synthesis of these proteins.

Transfer RNA precursors are accumulated in Escherichia coli in the absence of RNase E

A temperature-sensitive Escherichia coli mutant, which contains a heat-labile RNase E, fails to produce 5-S rRNA at a non-permissive temperature. It accumulates a number of RNA molecules in the 4-12-S range. One of these molecules, a 9-S RNA, is a precursor to 5-S rRNA [Ghora, B. K. and Apirion, D. (1978) Cell, 15, 1055-1056]. These molecules were purified and processed in a cell-free system. Some of these RNA molecules, after processing, give rise to products the size of transfer RNA, but not to 5-S-rRNA. Further characterization of the processed products of one such precursor molecule shows that it contains tRNA1Leu and tRNA1His. RNase E is necessary but not sufficient for the processing of this molecule to mature tRNAs in vitro. The accumulation of such tRNA precursors in an RNase E mutant cell and the obligatory participation of RNase E in its processing indicate that RNase E functions in the maturation of transfer RNAs as well as of 5-S rRNA.

The cII-independent expression of the phage lambda int gene in RNase III-defective E. coli

This study compares the rates of lambda protein synthesis after infection of rnc- cells, which are defective in ribonuclease III (RNase III), with the analogous rates in an isogenic rnc+ host. Temporal differences in gene expression are reflected in a delay in turn-off of lambda early proteins as well as in the delayed appearance of late phage functions in rnc- host cells. Moreover, in the two hosts there is a striking difference in the regulation of gene int expression, which in wild-type cells requires the product of the lambda cII (and cIII )genes, whereas Int synthesis occurs in the absence of cII in RNase III-defective cells. These results suggest that RNase III may be a negative regulator of Int synthesis. The expression of int is also shown to be cII- and cIII-independent in rnc+ cells infected with b2-deleted phages, thus confirming previous studies on the negative regulation of int by the b2-region. Possible mechanisms of these two inhibitory effects on int expression are considered and the significance of int regulation in the control of site-specific recombination is discussed.

L factor that is required for beta-galactosidase synthesis is the nusA gene product involved in transcription termination

The DNA-dependent in vitro synthesis of Escherichia coli beta-galactosidase requires the presence of a soluble protein referred to as L factor [Kung, H., Spears, C. & Weissbach, H. (1975) J. Biol. Chem. 250, 1556-1562]. In the present study, comparison of physical, immunological, and biological properties shows that L factor is the product of the E. coli nusA gene. The nusA gene product is known to interact with bacteriophage lambda N gene protein and to prevent premature termination of transcription from the early lambda promoters. Our results suggest that premature transcription termination in the lac operon of E. coli may also be overcome by the nusA protein.

The N protein of bacteriophage lambda, defined by its DNA sequence, is highly basic

Nucleotide sequence has been determined for the restriction fragments and cloned DNA from the pL-N-tL1 region of bacteriophage lambda. A unique reading frame for the N gene is defined by the absence of natural nonsense codons and by the presence of seven nonsense codons generated by mutations in N. This reading frame is initiated at two alternative ATG codons, the second of which is probably the in vivo translation start. Reading is stopped at a single TAG codon. The protein coded is therefore 133 or, more probably, 107 amino acids long, rich in lysine, arginine and proline.

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.

In vivo enhancement of general and specific transcription in Escherichia coli by DNA gyrase activity

The effect of drugs which inhibit DNA gyrase, including nalidixic acid, oxolinic acid and coumerycin, on transcription of Escherichia coli bacteria, phage and plasmid genomes was studied. Quantitative estimates of the synthesis of RNA under drug-treatment conditions showed that synthesis of many RNA species, including trp mRNA, was subject to inhibiton by the drug. Transcription directed by the lambda promoter pR was selectively less sensitive to the drug action than transcription initiated at the lambda promoter pL. Evidence was obtained showing that diminished transcription resulted from less frequent RNA chain initiation rather than a premature arrest of the chain elongation. Inhibiton of transcription by these DNA gyrase inhibitors was observed even in the absence of DNA replication. The inhibition by oxolinic acid or coumerycin was not observed in an E. coli strain bearing a nalAr mutation or a cour mutation, respectively. The reduction of trp mRNA synthesis in oxolinic acid-treated cells cannot be attributed to the increase in the rate of nascent mRNA degradation. These results indicate that DNA gyrase is generally required for intracellular RNA synthesis, and suggest that the supercoiling of DNA by this winding enzyme enhances the initiation of transcription.