Control of phage lambda development by stability and synthesis of cII protein: role of the viral cIII and host hflA, himA and himD genes

Circuit simulation of genetic networks

Genetic networks with tens to hundreds of genes are difficult to analyze with currently available techniques. Because of the many parallels in the function of these biochemically based genetic circuits and electrical circuits, a hybrid modeling approach is proposed that integrates conventional biochemical kinetic modeling within the framework of a circuit simulation. The circuit diagram of the bacteriophage lambda lysislysogeny decision circuit represents connectivity in signal paths of the biochemical components. A key feature of the lambda genetic circuit is that operons function as active integrated logic components and introduce signal time delays essential for the in vivo behavior of phage lambda.

Enhanced activity of the bacteriophage lambda PL promoter at low temperature

We found that the activity of the phage lambda PL promoter is inversely dependent on temperature. Both in vivo and in vitro transcription assays revealed that the rather unique temperature response of PL is a sum of an intrinsic property of the promoter and its activation by integration host factor. We also found that at low temperature, phage lambda can lysogenize efficiently but cannot complete the lytic cycle. We hypothesize that by sensing the low environmental temperature the PL promoter plays a role in determining the direction of phage lambda development.

Degradation of sigma 32, the heat shock regulator in Escherichia coli, is governed by HflB

The heat shock response in Escherichia coli is governed by the concentration of the highly unstable sigma factor sigma 32. The essential protein HflB (FtsH), known to control proteolysis of the phage lambda cII protein, also governs sigma 32 degradation: an HflB-depleted strain accumulated sigma 32 and induced the heat shock response, and the half-life of sigma 32 increased by a factor up to 12 in mutants with reduced HflB function and decreased by a factor of 1.8 in a strain overexpressing HflB. The hflB gene is in the ftsJ-hflB operon, one promoter of which is positively regulated by heat shock and sigma 32. The lambda cIII protein, which stabilizes sigma 32 and lambda cII, appears to inhibit the HflB-governed protease. The E. coli HflB protein controls the stability of two master regulators, lambda cII and sigma 32, responsible for the lysis-lysogeny decision of phage lambda and the heat shock response of the host.

Cell growth and lambda phage development controlled by the same essential Escherichia coli gene, ftsH/hflB

The lambda phage choice between lysis and lysogeny is influenced by certain host functions in Escherichia coli. We found that the frequency of lambda lysogenization is markedly increased in the ftsH1 temperature-sensitive mutant. The ftsH gene, previously shown to code for an essential inner membrane protein with putative ATPase activity, is identical to hflB, a gene involved in the stability of the phage cII activator protein. The lysogenic decision controlled by FtsH/HflB is independent of that controlled by the protease HflA. Overproduction of FtsH/HflB suppresses the high frequency of lysogenization in an hflA null mutant. The FtsH/HflB protein, which stimulates cII degradation, may be a component of an HflA-independent proteolytic pathway, or it may act as a chaperone, maintaining cII in a conformation subject to proteolysis via such a pathway. Suppressor mutations of ftsH1 temperature-sensitive lethality, located in the fur gene (coding for the ferric uptake regulator), did not restore FtsH/HflB activity with respect to lambda lysogenization.

The Escherichia coli hflA locus encodes a putative GTP-binding protein and two membrane proteins, one of which contains a protease-like domain

The hflA (high frequency of lysogenization) locus of Escherichia coli governs the lysis-lysogeny decision of bacteriophage lambda by controlling stability of the phage cII protein. hflA contains three genes, hflX, hflK, and hflC, encoding polypeptides of 50, 46, and 37 kDa, respectively. We have determined the nucleotide sequence of 3843 base pairs containing hflA and have found three large open reading frames corresponding to hflX, hflK, and hflC. HflX contains the three sequence motifs typical of GTP-binding proteins and appears to be a member of a distinct family of putative GTPases. HflC and HflK appear to be integral membrane proteins which show some similarity to each other and to a human membrane protein. The C-terminal region of HflC contains a domain resembling the catalytic domain of ClpP, a bacterial ATP-dependent protease. We hypothesize that HflK and HflC constitute a distinct membrane-bound protease whose activity may be modulated by HflX GTPase.

Fate of the SpoIIID switch protein during Bacillus subtilis sporulation depends on the mother-cell sigma factor, sigma K

Sporulation of Bacillus subtilis involves the differentiation of two cell types, the mother cell and the forespore. Two key regulators of mother-cell gene expression are SpoIIID, a DNA-binding protein that activates or represses transcription of many different genes, and sigma K, a subunit of RNA polymerase that directs the enzyme to transcribe genes encoding proteins that form the spore coat. Previous studies showed that SpoIIID is needed to produce sigma K, but suggested that SpoIIID represses sigma K-directed transcription of genes encoding spore coat proteins. Here we show that a feedback loop connects the levels of sigma K and SpoIIID, such that production of sigma K leads to a decrease in the level of SpoIIID. The existence of the feedback loop was demonstrated by using antibodies prepared against SpoIIID to measure the level of SpoIIID during sporulation of wild-type cells, mutants defective in sigma K production, and a mutant engineered to produce sigma K earlier than normal. The feedback loop operates at the level of synthesis and/or stability of spoIIID mRNA, as demonstrated by measuring the level of spoIIID mRNA during sporulation of wild-type cells and mutants defective in sigma K production. Our results suggest that a rise in the level of sigma K during the stage (IV) of spore cortex formation causes a decrease in the level of SpoIIID, which, at least in part, establishes the switch to the stage V (spore coat formation) pattern of mother-cell gene expression.

Involvement of the Escherichia coli RNA polymerase alpha subunit in transcriptional activation by the bacteriophage lambda CI and CII proteins

Escherichia coli cells harbouring the rpoA341 mutation produce an RNA polymerase which transcribes inefficiently certain operons subject to positive control. Here, we demonstrate that the rpoA341 allele also prevents lysogenization of the host strain by bacteriophage lambda, a process dependent upon the action of two phage-encoded activators. This phenomenon was shown to arise from an inability to establish an integrated prophage rather than a failure to maintain the lysogenic state. The inability of the rpoA341 host to support lysogenization could be completely reversed by CII-independent expression of int and cI in trans. These results led us to propose that the inhibition of lysogenization arises from a defective interaction between the phage lambda transcriptional activator CII and the mutant RNA polymerase at the phage promoters pI and pE. Finally, we also provide genetic evidence for impaired transcription of the cI gene from the CI-activated promoter, pM in the rpoA341 background.

Bacteriophage lambda as a cloning vector

Extensive research has been directed toward the development of multipurpose lambda vectors for cloning ever since the potential of using coliphage lambda as a cloning vector was recognized in the late 1970s. An understanding of the intrinsic molecular organization and of the genetic events which determine lysis or lysogeny in lambda has allowed investigators to modify it to suit the specific requirements of gene manipulations. Unwanted restriction sites have been altered and arranged together into suitable polylinkers. The development of a highly efficient in vitro packaging system has permitted the introduction of chimeric molecules into hosts. Biological containment of recombinants has been achieved by introducing amber mutations into the lambda genome and by using specific amber suppressor hosts. Taking advantage of the limited range of genome size (78 to 105% of the wild-type size) for its efficient packaging, an array of vectors has been devised to accommodate inserts of a wide size range, the limit being 24 kbp in Charon 40. The central dispensable fragment of the lambda genome can be replaced by a fragment of heterologous DNA, leading to the construction of replacement vectors such as Charon and EMBL. Alternatively, small DNA fragments can be inserted without removing the dispensable region of the lambda genome, as in lambda gt10 and lambda gt11 vectors. In addition, the introduction of many other desirable properties, such as NotI and SfiI sites in polylinkers (e.g., lambda gt22), T7 and T3 promoters for the in vitro transcription (e.g., lambda DASH), and the mechanism for in vivo excision of the intact insert (e.g., lambda ZAP), has facilitated both cloning and subsequent analysis. In most cases, the recombinants can be differentiated from the parental phages by their altered phenotype. Libraries constructed in lambda vectors are screened easily with antibody or nucleic acid probes since several thousand clones can be plated on a single petri dish. Besides the availability of a wide range of lambda vectors, many related techniques such as rapid isolation of lambda DNA, a high efficiency of commercially available in vitro packaging extracts, and in vitro amplification of DNA via the polymerase chain reaction have collectively contributed to lambda's becoming one of the most powerful and popular tools for molecular cloning.

Interaction between bacteriophage lambda and its Escherichia coli host

Bacteriophage lambda relies to a large extent on processes requiring interactions between viral- and host-encoded proteins for its lytic growth, establishment of lysogeny, and release from the prophage state. Both biochemical and genetic studies of these interactions have yielded new information about important host and lambda functions. In particular, mutations in Escherichia coli that compromise lambda DNA replication, genome packaging, transcription elongation, and site-specific recombination have led to the identification of bacterial genes whose products are chaperones, transcription factors, or DNA-binding proteins.

Proteases and protein degradation in Escherichia coli

In E. coli, protein degradation plays important roles in regulating the levels of specific proteins and in eliminating damaged or abnormal proteins. E. coli possess a very large number of proteolytic enzymes distributed in the cytoplasm, the inner membrane, and the periplasm, but, with few exceptions, the physiological functions of these proteases are not known. More than 90% of the protein degradation occurring in the cytoplasm is energy-dependent, but the activities of most E. coli proteases in vitro are not energy-dependent. Two ATP-dependent proteases, Lon and Clp, are responsible for 70-80% of the energy-dependent degradation of proteins in vivo. In vitro studies with Lon and Clp indicate that both proteases directly interact with substrates for degradation. ATP functions as an allosteric effector promoting an active conformation of the proteases, and ATP hydrolysis is required for rapid catalytic turnover of peptide bond cleavage in proteins. Lon and Clp show virtually no homology at the amino acid level, and thus it appears that at least two families of ATP-dependent proteases have evolved independently.

Membrane localization of the HflA regulatory protease of Escherichia coli by immunoelectron microscopy

The hflA locus of Escherichia coli specifies a multisubunit protease that selectively degrades the cII transcriptional activator of phage lambda. The regulated turnover of cII is critical for the choice between the lytic and lysogenic pathways of viral development. Previous cell fractionation work has indicated that HflA is associated with the inner membrane fraction. We have sought to demonstrate that the HflA protease is localized in the cell membrane of intact cells. To achieve this goal, we have combined electron microscopy of thin-sectioned E. coli cells with antibody tagging by a colloidal gold label. Using antibody to purified HflA protein, we have found preferential membrane labeling for hflA+ cells but not for hflA mutant cells. We conclude that HflA protease is localized in the cell membrane. The membrane location for HflA protein may serve as a component of a targeting mechanism to limit the action of the regulatory protease to selected cytoplasmic proteins.

Translation control of gene expression

The bacteriophage lambda cIII gene product is an early regulator of the lysogenic pathway. The availability of a set of cIII expression mutants allowed us to establish the structure-function relationship of the cIII mRNA. We demonstrated, using defined in vitro systems, that the cIII mRNA is present in two conformations at equilibrium. Mutations that have been shown to lead to cIII overexpression were found to freeze the RNA in one conformation (structure B), and permit efficient binding to the 30S ribosomal subunit. Mutations that have been shown to prevent cIII translation cause the mRNA to assume the alternative conformation (structure A). In this structure, the translation initiation region is occluded, thereby preventing 30S ribosomal subunit binding. Translation of the cIII gene is regulated by RNaseIII. We have localized the RNaseIII responsive element (RRE) to the cIII coding region. We suggest that the regulation of the equilibrium between the two mRNA conformations provides a mechanism for the control of cIII gene expression. The way in which RNaseIII participates in this regulation is as yet unknown.

Multiple effects of Fis on integration and the control of lysogeny in phage lambda

Fis is a small, basic, site-specific DNA-binding protein present in Escherichia coli. A Fis-binding site (F) has been previously identified in the attP recombination site of phage lambda (J. F. Thompson, L. Moitoso de Vargas, C. Koch, R. Kahmann, and A. Landy, Cell 50:901-908, 1987). The present study demonstrates that in the absence of the phage-encoded Xis protein, the binding of Fis to F can stimulate integrative recombination and therefore increase the frequency of lambda lysogeny in vivo. Additionally, Fis exerts a stimulatory effect on both integration and lysogeny that is independent of binding to the attP F site. Maintenance of the lysogenic state also appears to be enhanced in the presence of Fis, as shown by the increased sensitivity of lambda prophages encoding temperature-sensitive repressors to partial thermoinduction in a fis mutant. In the presence of Xis, however, Fis binding to F interferes with integration by stimulating excision, the competing back-reaction. Since Fis stimulates both excision and integration, depending on the presence or absence of Xis, respectively, we conclude that Xis binding to X1 is the key determinant directing the formation of an excisive complex.

The activity of the CIII regulator of lambdoid bacteriophages resides within a 24-amino acid protein domain

The CIII protein of lambdoid bacteriophages promotes lysogeny by stabilizing the phage-encoded CII protein, a transcriptional activator of the repressor and integrase genes. We have isolated a set of missense mutations in the cIII gene of phage lambda and of phage HK022 that yield inactive CIII proteins. All the mutations are located in the relatively conserved central region of the protein. A comparative analysis of the CIII protein sequence in lambda, HK022, and the lambdoid bacteriophage P22 leads us to suggest that this central region assumes an amphipathic alpha-helical structure. This part of the lambda cIII gene was cloned within a fragment of the lacZ gene (the alpha-complementing fragment). The resulting fusion protein displays CIII activity. Mutations that yield a nonfunctional fusion protein map within its CIII moiety. These results indicate that the central portion of the CIII protein is both necessary and sufficient for CIII activity.

An additional function for bacteriophage lambda rex: the rexB product prevents degradation of the lambda O protein

The rex operon of bacteriophage lambda excludes the development of several unrelated bacteriophages. Here we present an additional lambda rexB function: it prevents degradation of the short-lived protein lambda O known to be involved in lambda DNA replication. We have shown that it is the product of rexB that is responsible for the stabilization of lambda O: when a nonsense mutation is present in rexB, lambda O protein is labile; suppression of the mutation by the corresponding nonsense suppressor causes partial restabilization of lambda O. lambda rexB also stabilizes lambda O in trans. We discuss our results in relation to the function of rexB in lambda DNA replication and its role in the protein degradation pathways of bacteriophage lambda.

Isolation, characterization, and sequence of an Escherichia coli heat shock gene, htpX

We isolated and characterized a new Escherichia coli gene, htpX. The htpX gene has been localized at min 40.3 on the chromosome. We determined its transcription and translation start site. htpX expresses a 32-kDa protein from a monocistronic transcript; expression of this protein is induced by temperature upshift. htpX is expressed from a sigma 32-dependent promoter and is thus part of the heat shock regulon. Cells carrying a htpX gene disruption grow well at all temperatures and under all conditions tested and have no apparent phenotype. However, cells which overexpress a truncated form of the protein display a higher rate of degradation of puromycyl peptides.

Genetic interaction between the beta' subunit of RNA polymerase and the arginine-rich domain of Escherichia coli nusA protein

The nusA11 mutation causes reduced transcription termination and temperature-sensitive growth of Escherichia coli. Suppressor mutations that restored growth of nusA11 mutant cells were isolated and named sna mutations. The intergenic suppressor mutation sna-10 was located in the rpoC gene at 90 min, which encodes the beta' subunit of RNA polymerase. sna-10 complemented the defect in tR1 termination caused by nusA11 and by itself stimulated termination of transcription at the lambda tR1 terminator. sna-10 is specific to the nusA11 allele and unable to suppress cold-sensitive growth of the nusA10 mutant. nusA10 carried two base substitutions at positions 311 and 634, causing two amino acid changes from the wild-type sequence. During these studies, we found three -1 frameshift errors in the wild-type nusA sequence; the correct sequence was confirmed by the peptide sequence and gene fusion analyses. The revised sequence revealed that nusA1 and nusA11 are located in an arginine-rich peptide region and substitute arginine and aspartate for leucine 183 and glycine 181, respectively. The intragenic suppressor study indicated that the nusA11 mutation can be suppressed by changing the mutated aspartate 181 to alanine or changing aspartate 84 to tyrosine.

Genetic analysis of the cIII gene of bacteriophage HK022

The cIII gene product of lambdoid bacteriophages promotes lysogeny by stabilizing the phage-encoded CII protein, a transcriptional activator of the repressor and integrase genes. Previous works showed that the synthesis of the bacteriophage lambda CIII protein has specific translational requirements imposed by the structure of the mRNA. To gain insight into the mRNA structure and its role in regulating cIII translation, we undertook a mutational analysis of the cIII gene of the related bacteriophage HK022. Our data support the hypothesis that in HK022, as in lambda, translation initiation requires a specific mRNA structure. In addition, we found that translation of HK022 cIII, like that of lambda, is strongly reduced in a host deficient in the endonuclease RNase III.

Instability of bacteriophage Mu transposase and the role of host Hfl protein

The activity of the transposase of bacteriophage Mu is unstable, requiring the protein to be synthesized throughout the lytic cycle (Pato and Reich, 1982). Using Western blot analysis, we analysed the stability of the transposase protein during the lytic cycle and found that it, too, is unstable. The instability of the protein is observed both in the presence and the absence of Mu DNA replication, and is independent of other Mu-encoded proteins and the transposase binding sites at the Mu genome ends. Stability of the protein is enhanced in host strains mutated at the hfl locus; however, stability of the transposase activity is not enhanced in these strains, suggesting that functional inactivation of the protein is not simply a result of its proteolysis.

Rhizobium meliloti suhR suppresses the phenotype of an Escherichia coli RNA polymerase sigma 32 mutant

sigma 32, the product of the Escherichia coli rpoH locus, is an alternative RNA polymerase sigma factor utilized to express heat shock genes upon a sudden rise in temperature. E. coli K165 [rpoH165(Am) supC(Ts)] is temperature sensitive for growth and does not induce heat shock protein synthesis. We have isolated a locus from Rhizobium meliloti called suhR that allows E. coli K165 to grow at high temperature and induce heat shock protein synthesis. R. meliloti suhR mutants were viable and symbiotically effective. suhR was found to have no DNA or derived amino acid sequence similarity to the genes of previously sequenced sigma factors or other data base entries, although a helix-turn-helix DNA-binding protein motif is present. suhR did not restore the phenotypic defects of delta rpoH E. coli; suppression of the E. coli K165 phenotype is thus likely to involve E. coli sigma 32. Western immunoblots showed that suhR caused an approximately twofold elevation of sigma 32 levels in K165; RNA blots indicated that rpoH mRNA level and stability were not altered. Stabilization of sigma 32 protein and increased rpoH mRNA translation are thus the most probable mechanisms of suppression.

Integration host factor stimulates the phage lambda pL promoter

Escherichia coli integration host factor (IHF) is a small dimeric protein that binds to a specific DNA consensus sequence and produces DNA bending. Transcription from the bacteriophage lambda pL promoter is stimulated three- to fourfold by IHF both in vivo and in vitro. IHF binds with high-affinity to two tandem sites located just upstream from the pL promoter and enhances the formation of RNA polymerase-promoter closed complexes. The rate of isomerization to open complex is not influenced by IHF. IHF may stimulate recognition of pL by one or more of several mechanisms: (1) by bending DNA; (2) by making protein-protein contacts with RNA polymerase; or (3) by occluding a competing promoter upstream from pL.

The P2 phage old gene: sequence, transcription and translational control

The old (overcoming lysogenization defect) gene product of bacteriophage P2 kills Escherichia coli recB and recC mutants and interferes with phage lambda growth [Sironi et al., Virology 46 (1971) 387-396; Lindahl et al., Proc. Natl. Acad. Sci. USA 66 (1970) 587-594]. Specialized transducing lambda phages, which lack the recombination region, can be selected by plating lambda stocks on E. coli that carry the old gene on a prophage or plasmid [Finkel et al., Gene 46 (1986) 65-69]. Deletion and sequence analyses indicate that the old-encoded protein has an Mr of 65,373 and that its transcription is leftward. Primer extension analyses locate the transcription start point near the right end of the virion DNA. A bacterial mutant, named pin3 and able to suppress the effects of the old gene, has been isolated [Ghisotti et al., J. Virol. 48 (1983) 616-626]. In a pin3 mutant strain, carrying the old gene on a prophage or plasmid, the amount of old transcript is greatly reduced. The effect of the pin3 mutation is abolished by the wild-type allele of argU, an arginine tRNA that reads the rare Arg codons AGA and AGG, which are used for eight of the 14 Arg codons in the old gene. Thus the pin3 allele probably stalls translation of the old mRNA, causing this mRNA to be degraded. Isoelectric focusing and electrophoretic analysis identify the old gene product as a basic protein of approx. 65 kDa.

Gene expression in a cell-free system on the preparative scale

A cell-free system for preparative gene expression is described. It is composed of DNA-free Escherichia coli extract and added plasmid DNA; coupled transcription-translation proceeds with a continuous flow of the feeding solution containing nucleoside triphosphates and amino acids. The system works at a high constant rate for tens of hours. The yield of synthesised proteins after 20-50 h is hundreds of micrograms from 1 ml of the reaction mixture. Electrophoretic analysis of translation products confirms synthesis of proteins of the expected molecular mass.

Purification and properties of the DNA-binding protein HPB12 from Bacillus subtilis nucleoid

We report the purification to homogeneity of a 12 KDa protein (HPB12) present in the nucleoids of Bacillus subtilis. From the purification data the abundance of the protein was estimated to about 20,000 monomers per cell. The HPB12 protein is heat-stable and acid-soluble and binds preferentially to supercoiled and linearized double-stranded DNAs. The binding of the protein to the supercoiled DNA occurs very rapidly and appears to be cooperative. Moreover, the complexes are extremely stable and do not dissociate after 90 min. These properties are consistent with a role of the HPB12 protein in the structure of the B. subtilis chromosome.

UmuC mutagenesis protein of Escherichia coli: purification and interaction with UmuD and UmuD'

The introduction of a replication-inhibiting lesion into the DNA of Escherichia coli produces a marked elevation in mutation rate. The mutation pathway is a component of the induced, multigene SOS response. SOS mutagenesis is a tightly regulated process dependent on two RecA-mediated proteolytic events: cleavage of the LexA repressor to induce the UmuC and UmuD mutagenesis proteins, and cleavage of UmuD to UmuD' to activate the mutation pathway. To investigate the protein-protein interactions responsible for SOS mutagenesis, we have studied the interaction of UmuC, UmuD, and UmuD'. To probe intracellular interaction, we have used immunoprecipitation techniques with antibodies against UmuC or UmuD and UmuD'. We have found that antibody to UmuC precipitates UmuD' from cell extracts, and antibody to UmuD and UmuD' precipitates UmuC. Thus we conclude that UmuC probably associates tightly with UmuD' in cells. For biochemical studies, we have purified the UmuC and UmuD' proteins to use with the previously purified UmuD. UmuC associates strongly with an affinity column of UmuD and UmuD', eluting only under strongly dissociating conditions (2 M urea or 1.5 M KSCN). UmuC also associates efficiently with UmuD or UmuD' in solution, as judged by velocity sedimentation in a glycerol gradient. The likely stoichiometry is one UmuC with a dimeric UmuD or UmuD'. From these experiments and previous work, we infer that SOS mutagenesis depends on the action of the UmuC-UmuD' complex and probably RecA to rescue a stalled DNA polymerase III holoenzyme at the DNA lesion.

Repression of the lambda pcin promoter by integrative host factor

The cin-1 mutation creates a new promoter (pcin) in the tR1 region of bacteriophage lambda. The pcin promoter transcribes the cI repressor gene constitutively. lambda cin-1 does not propagate on Escherichia coli mutants lacking the integrative host factor (IHF). lambda cI- cin-1 grows normally in IHF- mutants, indicating that repressor overproduction from pcin blocks lytic growth. The presence of an IHF binding site which overlaps the pcin promoter led us to the hypothesis that IHF functions as a repressor of pcin transcription. We find that the pcin promoter is fivefold more active in a host lacking IHF than in wild-type cells. In vitro studies show that IHF directly inhibits transcription initiation at pcin. Abortive initiation and gel retardation assays demonstrate that IHF interferes with the binding of RNA polymerase to the pcin promoter. RNA polymerase bound in an open promoter complex is resistant to IHF. We propose that IHF binding to the pcin promoter region blocks the binding of RNA polymerase to the promoter, either by covering specific nucleotides or by distorting DNA structure.

Cloning and DNA sequence analysis of a Lactococcus bacteriophage lysin gene

A gene for the lysin of Lactococcus lactis bacteriphage phi vML3 was cloned using an Escherichia coli/bacteriophage lambda host-vector system. The gene was detected by its expression of antimicrobial activity against L. lactis cells in a bioassay. The cloned fragment was analysed by sub-cloning on to E. coli plasmid vectors and by restriction endonuclease and deletion mapping. Its entire DNA sequence was determined and an open reading frame for the lysin structural gene was identified. The sequenced lysin gene would express a protein of 187 amino acids with a molecular weight of 21,090, which is in good agreement with that of a protein detected after in vitro transcription and translation of DNA encoding the gene. Expression of the lysin gene in E. coli and B. subtilis from an adjacent bacteriophage promoter was readily detected but in L. lactis expression of lysin was found to be lethal. The bacteriophage phi vML3 lysin had sequence homology with protein 15 of B. subtilis bacteriophage PZA. This protein is involved in DNA packaging during bacteriophage maturation rather than in host cell lysis. The cloning and analysis of the phi vML3 lysin gene is of importance in further understanding lactic streptococcal bacteriophages, for the development of positive selection vectors and for biotechnological applications of relevance to the dairy industry.

Nucleotide sequence and expression of the gene for the site-specific integration protein from bacteriophage HP1 of Haemophilus influenzae

The nucleotide sequence of the leftmost 2,363 base pairs of the HP1 genome, which includes the attachment site (attP) and the integration region, was determined. This sequence contained an open reading frame encoding a 337-residue polypeptide, which is a member of the integrase family of site-specific recombination proteins as judged by sequence comparison. The open reading frame was located immediately adjacent to the att site and was oriented so that initiation of translation would begin distal to the att site and end in its immediate vicinity. Expression of this DNA segment in Escherichia coli provided extracts which promoted site-specific recombination between plasmids containing cloned HP1 attP and Haemophilus influenzae attB sites. This recombination was directional, since no reaction was observed between plasmids containing attR and attL sites. The reaction was stimulated by the accessory protein integration host factor of E. coli. Evidence was also obtained that the integration host factor influenced the levels of HP1 integrase expression. The deduced amino acid sequence of HP1 integrase has remarkable similarity to that deduced for the integrase of coliphage 186.

Structure and expression of elongation factor 1 alpha in tomato

A full-length cDNA clone, LeEF-1, has been isolated from tomato for the alpha subunit of elongation factor 1 (EF-1 alpha), a polypeptide which plays a central role in protein synthesis. The 448 amino acid protein encoded by this cDNA appears highly homologous to other EF-1 alpha s having a high degree of similarity (75-78%) to EF1 alpha previously described from both lower eukaryotes and animals. Southern analysis indicated that EF-1 alpha belongs to a small multigene family of 4-8 members in tomato. The pattern of expression of EF-1 alpha mRNA in various tomato tissues was analyzed by Northern analysis, in vitro translation and in situ hybridization. EF-1 alpha mRNA is an abundant species and higher levels of mRNA were found in developing tissues such as young leaves and green fruit compared to the mRNA levels observed in older tissues. The increased levels of EF-1 alpha mRNA therefore appear to correlate with higher levels of protein synthesis in developing tissues.

Determinants of site-specific recombination in the lambdoid coliphage HK022. An evolutionary change in specificity

The temperate bacteriophage HK022, like its relative lambda, inserts its chromosome into a specific site in the bacterial chromosome during lysogenization and excises it after induction. However, we find that the recombinational specificities of the two phages differ: they use different bacterial sites, and neither promotes efficient insertion or excision of the other phage chromosome. In order to determine the basis for this difference in specificity, we sequenced the HK022 elements that are involved in insertion and excision, and compared them to the corresponding lambda elements. The location, orientation, size and overall arrangement of the int and xis genes and the phage attachment sites are nearly identical in the two genomes, as is common for other functionally related elements in lambdoid phages. The Xis proteins of the two phages are functionally interchangeable, and their predicted amino acid sequences differ by but one residue. In contrast, the two Int proteins are not functionally interchangeable, and their sequences, although similar, differ at many positions. These sequence differences are not uniformly distributed: the amino-terminal 55 residues are completely conserved, but the remaining 302 show a pattern of differences interspersed with identities and conservative changes. These findings imply that the specificity difference between HK022 and lambda site-specific recombination is a consequence of the inability of the respective Int proteins to recognize pairs of heterologous attachment sites. The two phage attachment sites are remarkably similar, especially the two "arm" segments, which in lambda contain binding sites for Int, Xis and integration host factor. They are less similar in the segment between the two arms, which in lambda contains the points of recombinational strand exchange and a second class of binding site for Int protein (the "core-type" sites). The two bacterial attachment sites are quite different, although both have a short stretch of perfect homology with their respective phage partners at the points of strand exchange. We propose that the two Int proteins recognize similar or identical sites in the arms of their cognate attachment sites, and that differences in binding or action at the core-type sites is responsible for the divergent specificities. Genetic experiments and sequence comparisons suggest that both proteins recognize different but overlapping families of core-type sites, and that divergence in specificity has been achieved by an alternating succession of small, mutually compatible changes in protein and site.

Genetic structure of the bacteriophage P22 PL operon

The sequence of 1416 base-pairs of the P22 PL operon was determined, linking a continuous sequence from PL through abc2. P22 mutants bearing deletions in the sequenced region were constructed and tested for their phenotypes. Plasmids were constructed to express PL operon genes singly and in combination from Plac UV5. Two previously known genes, 17 and c3, are located within this sequence. In addition, three new genes have been identified: ral, kil and arf. Genes ral and c3 are homologous, as well as functionally analogous, to lambda ral and cIII, respectively. P22 kil, like lambda kil, kills the host cell when it is expressed. The two kil genes, although analogous in cell killing and map location, have no apparent sequence homology. The functions of the P22 and lambda kil genes are unknown; however, P22 kil is essential for lytic growth in the absence of abc. Gene arf (accessory recombination function) is located just upstream from erf; it is essential for P22 growth in the absence of kil or other genes upstream in PL. The growth defect of P22 bearing a deletion that removes arf is complemented by expression of either arf or the lambda red genes from plasmids. Sequences that include the stop codon for gene 17 may form a small stem-loop structure and are nearly identical to lambda sequences that contain the stop codon for ssb, which is near lambda tL 2b. Plasmids that include the P22 structure negatively regulate kil gene expression in cis.

Genetic analysis of bacteriophage lambda cIII gene: mRNA structural requirements for translation initiation

The bacteriophage lambda cIII gene product regulates the lysogenic pathway. The cIII gene is located in the leftward operon, which is transcribed from the pL promoter. We have previously shown (S. Altuvia and A. B. Oppenheim, J. Bacteriol. 167:415-419, 1986) that mutations that show elevated expression lie within the cIII coding sequence. We isolated mutants that show decreased CIII activity. All the mutations were found to cause a drastic reduction in the rate of initiation of cIII translation. Several mutations were found to be scattered within the first 40 nucleotides of the cIII coding region. Additional mutations affected the AUG initiation codon, the Shine-Dalgarno sequence, and the upstream RNaseIII processing site. Computer folding of the cIII mRNA suggested the presence of two alternative RNA structures. All the mutations within the coding region that reduce expression reduce the stability of one specific mRNA structure (structure B). Mutations that increase expression lie in the loops of this structure and may in fact stabilize it by interfering with the formation of the alternative structure (structure A). Thus, it appears that a specific mRNA secondary structure at the beginning of the cIII coding region is essential for efficient translation, suggesting that changes in mRNA structure regulate cIII expression.

Integration host factor (IHF) stimulates binding of the gpNu1 subunit of lambda terminase to cos DNA

The lambda terminase enzyme binds to the cohesive end sites (cos) of multimeric replicating lambda DNA and introduces staggered nicks to regenerate the 12 bp single-stranded cohesive ends of the mature phage genome. In vitro this endonucleolytic cleavage requires spermidine, magnesium ions, ATP and a host factor. One of the E. coli proteins which can fulfill this latter requirement is Integration Host Factor (IHF). IHF and the gpNu1 subunit of terminase can bind simultaneously to their own specific binding sites at cos. DNase I footprinting experiments suggest that IHF may promote gpNu1 binding. Although no specific gpNu1 binding to the left side of cos can be detected, this DNA segment does play a specific role since a cos fragment that does not include the left side or whose left side is replaced by non-cos sequences, is unable to bind gpNu1 unless either spermidine or IHF is present. Binding studies on the right side of cos using individual or combinations of gpNu1 binding sites I, II and III indicate that binding at sites I and II is not optimal unless site III is present.

Characterization of the kafirin gene family from sorghum reveals extensive homology with zein from maize

Electrophoretic analysis of translation products of polyadenylated RNA isolated from mid-maturation sorghum seed in the presence of [(35)S]met, [(3)H]leu, or [(3)H]val revealed two major proteins of kDa and 21 kDa. These products were not detected when [(3)H]lys was supplied as the radioactive substrate. Under similar electrophoretic conditions, kafirin (a major seed storage prolamin of sorghum), migrated as two bands of 22 kDa and 19 kDa. Sequence analysis of two cDNA clones (pSK8 and pSKR2) from sorghum seed mRNA revealed them to be highly homologous with each other and to the 22 kDa zeins from maize, suggesting that they represented kafirin cDNAs. Compared with pSKR2, pSK8 had an insertion of 24 nucleotides and a deletion of 24 nucleotides, so that the coding regions were nearly identical in length. The deduced amino acid sequence for these cDNA clones reveals that kafirin, like zein, is rich in glutamine and nonpolar amino acids, but contains no lysine. Both kafirin and zein have a 21 amino acid signal peptide exhibiting 80% homology and eight copies of a repetitive amino acid block in the C-terminal domain with the consensus: infI (supP) LL finP (supA) LN infQ (supP) LALANPAAYLQQQQ.The kafirin cDNAs were used as probes to screen a sorghum genomic library; one genomic clone (λGK.1) was sequenced and found to be very similar (97.8%) to the pSK8 cDNA clone. Clone λGK.1 contains features typical for a functional gene in that the intronless open reading frame encoding 268 amino acids is flanked at the 5' end by sequences corresponding to the CAAT and TATA promoter boxes (positioned at about -60 and -30 bp, respectively, from the transcriptional initiation site), and at the 3' end by a consensus polyadenylation signal. In common with zein genomic clones, kafirin clones contain a 15 basepair consensus sequence centered at postion -320 relative to the transcriptional initiation site. Under similar hybridization conditions, genomic reconstruction analysis using an oligonucleotide probe indicated the presence of less than 20 copies of kafirin per haploid sorghum genome compared with approximatley 140 copies of zein per haploid maize genome.

Site-specific recombination between cloned attP and attB sites from the Haemophilus influenzae bacteriophage HP1 propagated in recombination-deficient Escherichia coli

Plasmids were constructed which contain both attP and attB DNA segments derived from the insertion sites of the lysogenic bacteriophage HP1 and its host, Haemophilus influenzae. Similar plasmids containing the two junction segments (attL and attR regions) between the phage genome and the lysogenic host chromosome were also prepared. The formation of recombinant dimer plasmids was observed when attP-attB plasmids were propagated in Escherichia coli HB101 (recA), while plasmids containing the junction segments did not form recombinant dimers. Deletion of the phage DNA segment adjacent to the attP site from the attP-attB constructions eliminated detectable recombination, suggesting that this sequence contains the gene encoding the HP1 integrase. No plasmid recombination was observed in strains of E. coli defective in integration host factor. This suggests that integration host factor is important in the expression or activity of the system which produces the site-specific recombination of sequences derived from HP1 and H. influenzae. Further, it suggests that a protein functionally analogous to E. coli integration host factor may be present in H. influenzae.

Life cycle of the budding yeast Saccharomyces cerevisiae

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Cleavage of the cII protein of phage lambda by purified HflA protease: control of the switch between lysis and lysogeny

The activity of the cII protein of phage lambda is probably the critical controlling factor in the choice of the lytic or lysogenic pathway by an infecting virus. Previous work has established that cII activity is regulated through the turnover of cII protein; the products of the hflA and hflB loci of Escherichia coli are needed for a degradative reaction, and lambda cIII functions in stabilizing cII. By using the cloned hflA locus, we have purified a cII-cleaving enzyme that we term HflA. Purified HflA contains three polypeptides; at least two of the subunits are products of the hflA region, and the third is probably a cleavage product of the larger of these two hflA-encoded polypeptides. The HflA protease activity cleaves cII to small fragments. We conclude that the switch between lambda developmental pathways involves regulated cleavage of cII by the specific protease HflA.

Integration host factor binds specifically to sites in the ilvGMEDA operon in Escherichia coli

Integration host factor (IHF) of Escherichia coli is a histone-like protein that is involved both in site-specific recombination and in regulating the expression of a number of phage and bacterial genes. We have shown previously that transcription of the ilvGMEDA operon in E. coli is greatly reduced in IHF mutants. We report here that IHF specifically protects two sites within the ilvGMEDA promoter-regulatory region against DNase I digestion. These sites are located upstream from the promoter and in the leader region just prior to the sequence that specifies the attenuator. The footprinting experiments and gel retardation assays show that these sites have strong affinity for IHF. These data and results with ilvGMEDA-lac promoter fusions suggest a direct role for IHF in expression of the ilvGMEDA operon.

Altered osmoregulation of ompF in integration host factor mutants of Escherichia coli

Osmoregulation of the porin protein OmpF was strongly altered in integration host factor (IHF) mutants. These mutants produced approximately 15-fold more OmpF than did the parent strain when grown in media of intermediate osmolarity. At high osmolarity IHF mutants continued to produce considerable amounts of OmpF, although this protein was undetectable in the parent grown under these conditions. Experiments with an ompF-lacZ chromosomal fusion strain suggested that these changes in osmoregulation in large part involve alterations in transcriptional activity of the ompF promoter. These results add to the growing list of genes whose expression is modified in IHF mutants.

Multiple promoters for transcription of the Escherichia coli DNA topoisomerase I gene and their regulation by DNA supercoiling

There are four transcriptional promoters present in the 5' control region of the Escherichia coli DNA topoisomerase I (topA) gene. These were identified with Bal31 nuclease-generated deletions and mapping of the 5' ends of the mRNAs with avian reverse transcriptase. Recombinant plasmids with all or some of these promoters fused to the galactokinase (galK) gene-coding region have been constructed and used to study transcription from the promoters both in vitro and in vivo. The promoter (P1) closest to the starting ATG codon has a near consensus -35 sequence (GTTGATA) but unusual -10 (CATATCG) sequence. The other three promoters (P2, P3 and P4) are clustered together 60 base-pairs further upstream. Negative DNA supercoiling is required for efficient transcription from P1, P1 + P2 + P3 + P4, P2 + P3 + P4, P3 + P4 and P4 alone. The combination of all four promoters demonstrates greater supercoiling dependence than does any of the other subsets tested.