Interaction of bacteriophage K10 with its receptor, the lamB protein of Escherichia coli.

The lamB protein of Escherichia coli was initially recognized as the receptor for bacteriophage lambda. It is now shown also to constitute the receptor for phage K10. The lamB protein interacts with phage K10 in vitro, but this interaction does not lead to phage inactivation. Most lambda-resistant labB mutants are also resistant to K10, and vice versa. However, a significant proportion of the mutants resistant to one of the phages is sensitive to the other. Nineteen K10-resistant lambda-sensitive mutants have been studied. Only six of them produce a lamB protein which seems totally unimpaired in its ihe same deletion interval of the lamB gene. The corresponding region of the lamB polypeptide must be specifically involved in the interaction with phage K10. An unusual pattern of K10 host range mutants has been obtained; two calsses of such mutants could be defined, growing on two distinct classes of K10-resistant lamB mutants.     

Lambda Receptor in the Outer Membrane of Escherichia coli as a Binding Protein for Maltodextrins and Starch Polysaccharides

The starch polysaccharides amylose and amylopectin are not utilized by Escherichia coli, but are bound by the bacteria. The following evidence supports the view that the outer membrane lambda receptor protein, a component of the maltose/ maltodextrin transport system is responsible for the binding. (i) Amylose and amylopectin both inhibit the transport of maltose into E. coli. (ii) Both polysaccharides prevent binding of non-utilizable maltodextrins by the intact bacterium, a process previously shown to be dependent on components of the maltose transport system (T. Ferenci, Eur. J. Biochem., in press). (iii) A fluorescent amylopectin derivative, O-(fluoresceinyl thiocarbamoyl)-amylopectin, has been synthesized and shown to bind to E. coli in a reversible, saturable manner. Binding of O-(fluoresceinyl thiocarbamoyl)-amylopectin is absent in mutants lacking the lambda receptor, but mutations in any of the other components of the maltose transport system do not affect binding as long as lambda receptor is present. (iv) Using the inhibition of lambda receptor-dependent O-(fluoresceinyl thiocarbamoyl)-amylopectin binding as an assay, the affinities of the lambda receptor for maltodextrins and other sugars have been estimated. The affinity for dextrins increases with increasing degree of polymerization (K(d) for maltose, 14 mM; for maltotetraose, 0.3 mM; for maltodecaose, 0.075 mM). Maltose and some other di- and trisaccharides are inhibitory to amylopectin binding, but only at concentrations above 1 mM.     

Protein interactions in the outer membrane of Escherichia coli.

Specific protein interactions in Escherichia coli outer membrane were analyzed using chemical cross-linking with truly cleavable reagents and symmetrical two-dimensional sodium dodecyl sulphate/polyacrylamide gel electrophoresis. The major outer membrane proteins were shown to form cross-linked complexes. These include multimers of lambda receptor, protein I, II, III and the free form of lipoprotein. Lipoprotein was also found to be cross-linked to proteins II and III. The identity of many of these complexes was verified using appropriate mutants missing the proteins in question. No new protein interactions were detected in the mutants even when three of the major proteins were missing. Proteins II, III and the free form of lipoprotein could also be cross-linked to the peptidoglycan layer of the cell wall.     

Occurrence of the bacteriophage lambda receptor in some enterobacteriaceae.

In Escherichia coli K-12, the receptor for phage lambda is an outer membrane protein which inactivates the phage in vitro. Lambda receptor activity was found in extracts from all wild strains of E. coli tested, although most of them fail to support growth of the phage. In some cases this failure is due to a masking of the receptor in vivo, the bacteria being unable to adsorb the phage or to react with antireceptor antibodies. In other cases, adsorption does occur, and the nature of the block in phage growth was not investigated. Most Mal+ strains of Shigella have lambda receptor, whereas most Mal- strains do not have it. Synthesis of the lambda receptor in Shigella is thus presumably controlled by the positive regulator gene of the maltose regulon as is the case in E. coli K-12. Phage lambda adsorbs on many Mal+ strains of Shigella and even yields plaques on some of them, although at a low frequency. No lambda receptor activity could be found in extracts of several strains of Salmonella and Levinea.     

Diploidy for a structural gene specifying a major protein of the outer cell envelope membrane from Escherichia coli K-12.

Homogenotes, heterogenotes, and intergeneric hybrids have been studied that are diploid for the structural gene of a major outer cell envelope membrane protein (protein II) from Escherichia coli. This protein can act as a phage receptor. In wild-type homogenotes, diploidy for the gene did not cause a gene dosage effect. It could be shown with two heterogenotes that both the chromosomal mutant and the episomal wild-type genes are expressed, and in each case more of the mutant than the wild-type protein species was found in the cell envelope. In on case of 21 phage-resistant mutants missing protein II was a trans effect observed of the mutant gene on the expression of the episomal wild type gene. Transfer of E. coli episomes carrying the protein II structural gene into Salmonella typhimurium and Proteus mirabilis resulted in intergeneric hybrids that became sensitive to the relevant phage and harbored the E. coli protein II in their cell envelopes. The results may be taken as suggestive evidence for a simple feedback mechanism for the regulation of synthesis of protein II, and they show that there are no highly specific requirements on protein primary structure for incorporation into an outer cell envelope membrane.     

Behavior of coliphage lambda in hybrids between Escherichia coli and Salmonella

Salmonella typhosa hybrids able to adsorb lambda were obtained by mating S. typhosa recipients with Escherichia coli K-12 donors. After adsorption of wild-type lambda to these S. typhosa hybrids, no plaques or infective centers could be detected. E. coli K-12 gal(+) genes carried by the defective phage lambdadg were transduced to S. typhosa hybrids with HFT lysates derived from E. coli heterogenotes. The lysogenic state which resulted in the S. typhosa hybrids after gal(+) transduction differed from that of E. coli. Ability to produce lambda, initially present, was permanently segregated by transductants of the S. typhosa hybrid. S. typhosa lysogens did not lyse upon treatment for phage induction with mitomycin C, ultraviolet light, or heat in the case of thermoinducible lambda. A further difference in the behavior of lambda in Salmonella hybrids was the absence of zygotic induction of the prophage when transferred from E. coli K-12 donors to S. typhosa. A new lambda mutant class, capable of forming plaques on S. typhosa hybrids refractory to wild-type lambda, was isolated at low frequency by plating lambda on S. typhosa hybrid WR4254. Such mutants have been designated as lambdasx, and a mutant allele of lambdasx was located between the P and Q genes of the lambda chromosome. Plaques were formed also on the S. typhosa hybrid host with a series of lambda(i21) hybrid phages which contain the N gene of phage 21. The significance of these results in terms of Salmonella species as hosts for lambda is discussed.     

On Some Genetic Aspects of Phage λ Resistance in E. COLI K12

Most mutations rendering E. coli K12 resistant to phage lambda, map in two genetic regions malA and malB.-The malB region contains a gene lamB specifically involved in the lambda receptor synthesis. Twenty-one independent lamB mutations studied by complementation belonged to a single cistron. This makes it very likely that lamB is monocistronic. Among the lamB mutants some are still sensitive to a host range mutant of phage lambda. Mutations mapping in a proximal gene essential for maltose metabolism inactivate gene lamB by polarity confirming that both genes are part of the same operon. Because cases of intracistronic complementation have been found, the active lamB product may be an oligomeric protein.-Previously all lambda resistant mutations in the malA region have been shown to map in the malT cistron. malT is believed to be a positive regulatory gene necessary for the induction of the "maltose operons" in the malA region and in the malB region of the E. coli K12 genetic map. No trans dominant malT mutation have been found. Therefore if they exist, they occur at a frequency of less than 10(-8), or strongly reduce the growth rate of the mutants.     

Mutants defective in the 33K outer membrane protein of Salmonella typhimurium.

Salmonella typhimurium LT2 lines, if phenotypically rough, are fully sensitive to bacteriocin 4-59, produced by Salmonella canastel strain SL1712. Bacteriocin-resistant mutants fell into three classes. Those resistant to phage ES18 and to albomycin proved to be mutants of class chr (equivalent to tonB of Escherichia coli); these mutants still adsorb the bacteriocin and so are classified as tolerant. Another class of (incompletely) tolerant mutants was resistant to phage PH51; their envelope fractions lacked the band corresponding to outer membrane protein 34K, known to serve for adsorption of phage PH51. A third class of mutants, which did not adsorb the bacteriocin, was unaltered in sensitivity to phages. Their envelopes lacked the 33K band, indicating absence of the outer membrane protein 33K, considered to correspond to outer membrane protein II* of E. coli, which in that species is determined at locus ompA (formerly tolG or con). Phage P22 HT105/1 cotransduced the 33K S. typhimurium gene (to be called ompA, to accord with E. coli usage) with pyrD+ at about 30% frequency when the donor allele was ompA+ or one ompA, but at only 3 to 11% when the donor allele was another ompA. When the donor carried either of two long deletions of the put (proline utilization) operon, phage P22 HT105/1 cotransduced put (and ompA+) with pyrD+ at low frequency. The cotransduction data indicate that ompA of S. typhimurium is located between pyrD and put, nearer the former. This corresponds to the map position of ompA in E. coli K-12.     

Functional Interchangeability of DNA Replication Genes in SALMONELLA TYPHIMURIUM and ESCHERICHIA COLI Demonstrated by a General Complementation Procedure

Twenty-four genes from Salmonella typhimurium that affect DNA replication were isolated from a lambda-Salmonella genomic library by lysogenic complementation of temperature-sensitive mutants of Salmonella or E. coli, using a new plaque complementation assay. The complementing lambda clones, which make red plaques in this assay, and noncomplementing mutant derivatives, which make uncolored plaques, were used to further characterize the temperature-sensitive Salmonella mutants and to establish the functional similarity of E. coli and Salmonella DNA replication genes. For 17 of 18 E. coli mutants representing distinct loci, a Salmonella gene that complemented the mutant was found. This result indicates that single Salmonella replication proteins are able to function in otherwise all E. coli replication complexes and suggests that the detailed properties of Salmonella and E. coli replication proteins are very similar. The other seven Salmonella genes that were cloned were unrelated functionally to any E. coli genes examined. --As an aid to the derivation of chromosomal mutations affecting some of the cloned genes, a general method was developed for placing a transposon in the Salmonella chromosome in a segment corresponding to cloned DNA. Chromosomal mutations were derived in Salmonella affecting a gene (dnaA) that was cloned by complementation of an E. coli mutant by using the transposon-encoded drug resistance as a selectable marker in local mutagenesis.     

Physical interaction between the phage lambda receptor protein and the carrier-immobilized maltose-binding protein of Escherichia coli

When Triton X-100/EDTA extracts of the outer membrane of Escherichia coli K12 were passed through a column containing maltose-binding protein covalently linked to Sepharose 6MB beads, the phage lambda receptor protein or LamB protein was quantitatively and specifically adsorbed to the column and was eluted with a solution containing 1 M NaCl, but not with that containing 0.5 M maltose. The binding did not take place when columns containing inactivated Sepharose beads alone, or Sepharose bound to histidine-binding protein of Salmonella typhimurium, were used. This interaction is consistent with the hypothesis that the periplasmic maltose-binding protein interacts with the part of the LamB protein exposed on the inner surface of the outer membrane, thereby increasing the specificity of the solute penetration process through the LamB channel.     

Tricarboxylate transport in a Cit+ Escherichia coli: evidence for the role of an outer membrane protein

A strain of Escherichia coli of bovine origin able to use tricarboxylates as single carbon source is described. Tricarboxylate utilization (Cit+) and fluorocitrate sensitivity (FCs) could be transferred conjugatively to E. coli K12 and were not plasmid borne. No evidence was found for tct gene products of Salmonella typhimurium. A citrate-inducible outer membrane protein of 21-22 kilodaltons (kd) was found only in Cit+ strains. A protein (21-22kd) protein was also found in wild-type E. coli K12 and in fluorocitrate-resistant mutants of Cit+ strains, but it was present in a cryptic form no longer inducible by citrate. Fluorocitrate-resistant mutants of Cit+ strains were still able to transport citrate by a fluorocitrate-insensitive system. High levels of the 22-kd protein correlated with reduced growth induction times on citrate and with the ability to effectively transport citrate.     

In vivo and in vitro functional alterations of the bacteriophage lambda receptor in lamB missense mutants of Escherichia coli K-12

lamB is the structural gene for the bacteriophage lambda receptor in Escherichia coli K-12. In vivo and in vitro studies of the lambda receptor from lamB missence mutants selected as resistant to phage lambda h+ showed the following. (i) Resistance was not due to a change in the amount of lambda receptor protein present in the outer membrane but rather to a change in activity. All of the mutants were still sensitive to phage lambda hh*, a two-step host range mutant of phage lambda h+. Some (10/16) were still sensitive to phage lambda h, a one-step host range mutant. (ii) Resistance occurred either by a loss of binding ability or by a block in a later irreversible step. Among the 16 mutations, 14 affected binding of lambda h+. Two (lamB106 and lamB110) affected inactivation but not binding; they represented the first genetic evidence for a role of the lambda receptor in more than one step of phage inactivation. Similarly, among the six mutations yielding resistance to lambda h, five affected binding and one (lamB109) did not. (iii) The pattern of interactions between the mutated receptors and lambda h+ and its host range mutants were very similar, although not identical, in vivo and in vitro. Defects were usually more visible in vitro than in vivo, the only exception being lamB109. (iv) The ability to use dextrins as a carbon source was not appreciably affected in the mutants. Possible working models and the relations between phage infection and dextrins transport were briefly discussed.     

Bacteriophage-induced functions in Escherichia coli K (lambda) infected with rII mutants of bacteriophage T4

Rutberg, Blanka (Karolinska Institutet, Stockholm, Sweden), and Lars Rutberg. Bacteriophage-induced functions in Escherichia coli K(lambda) infected with rII mutants of bacteriophage T4. J. Bacteriol. 91:76-80. 1966.-When Escherichia coli K(lambda) was infected with rII mutants of phage T4, deoxycytidine triphosphatase, one of the phage-induced early enzymes, was produced at initially the same rate as in r(+)-infected cells. Deoxyribonuclease activity was one-third to one-half of that of r(+)-infected cells. This lower deoxyribonuclease activity was observed also in other hosts or when infection was made with rI or rIII mutants. Presence of chloramphenicol did not allow a continued synthesis of phage deoxyribonucleic acid in rII-infected K(lambda). No phage lysozyme was detected nor was any antiphage serum-blocking antigen found in rII-infected K(lambda). It is suggested that the rII gene is of significance for the expression of phage-induced late functions in the host K(lambda).     

Sequence of amino acids in lamB responsible for spontaneous ejection of bacteriophage lambda DNA

The DNA sequence of the promoter-distal half of lamB from Shigella sonnei 3070 has been determined and compared with the known sequence for the Escherichia coli K12 gene. The only predicted amino acid changes in this region of LamB, the receptor protein for bacteriophage lambda, lie between positions 381 and 390, where seven of the ten amino acids are altered. Evidence is presented that indicates that this region is responsible for the ability of the S. sonnei receptor, but not the E. coli receptor, to trigger spontaneous ejection of DNA from the bacteriophage in vitro. DNA injection in vivo must be more complex and involve also the host Pel protein and the lambda tail proteins gpJ, gpH, and gpV.     

Effect of Long Generation Times on Growth of Bacteroides thetaiotaomicron in Carbohydrate-Limited Continuous Culture

lamB is the structural gene for the bacteriophage lambda receptor, a multifunctional protein located in the outer membrane of Escherichia coli K-12. We present a method for deletion mapping of any lamB mutations with a recognizable pheno-type. This method involves a transducing phage constructed by in vitro recombination which can also be used for complementation, deoxyribonucleic acid sequence, and in vitro protein synthesis studies with the mutated lamB gene. Using this method, we mapped 18 lamB missense mutations which confer resistance to phage lambda h+ (wild-type host range). The main results were the following. (i) None of the 18 mutations was located in the first 4 deletion intervals out of the 11 of the genetic map. (ii) These mutations were clustered according to their phenotype as follows. (a) Class I mutations, which allow growth of lambda h and lambda hh* (one-step and two-step host range mutants of lambda, respectively), were located in three regions--three in interval V, four in interval VIII-IX, and three in interval X-XI. Only the last three mutations still allowed growth of phage K10 which also uses the lambda receptor, and two of them still allowed reversible binding of lambda h+. (b) All seven class II mutations allowed only growth of lambda hh* and mapped in interval V. These results are discussed in the frame of a genetic approach to the functional topology of the lambda receptor.     

Isolation and characterization of dnaJ null mutants of Escherichia coli.

Bacteriophage lambda requires the lambda O and P proteins for its DNA replication. The rest of the replication proteins are provided by the Escherichia coli host. Some of these host proteins, such as DnaK, DnaJ, and GrpE, are heat shock proteins. Certain mutations in the dnaK, dnaJ, or grpE gene block lambda growth at all temperatures and E. coli growth above 43 degrees C. We have isolated bacterial mutants that were shown by Southern analysis to contain a defective, mini-Tn10 transposon inserted into either of two locations and in both orientations within the dnaJ gene. We have shown that these dnaJ-insertion mutants did not grow as well as the wild type at temperatures above 30 degrees C, although they blocked lambda DNA replication at all temperatures. The dnaJ-insertion mutants formed progressively smaller colonies at higher temperatures, up to 42 degrees C, and did not form colonies at 43 degrees C. The accumulation of frequent, uncharacterized suppressor mutations allowed these insertion mutants to grow better at all temperatures and to form colonies at 43 degrees C. None of these suppressor mutations restored the ability of the host to propagate phage lambda. Radioactive labeling of proteins synthesized in vivo followed by immunoprecipitation or immunoblotting with anti-DnaJ antibodies demonstrated that no DnaJ protein could be detected in these mutants. Labeling studies at different temperatures demonstrated that these dnaJ-insertion mutations resulted in altered kinetics of heat shock protein synthesis. An additional eight dnaJ mutant isolates, selected spontaneously on the basis of blocking phage lambda growth at 42 degrees C, were shown not to synthesize DnaJ protein as well. Three of these eight spontaneous mutants had gross DNA alterations in the dnaJ gene. Our data provide evidence that the DnaJ protein is not absolutely essential for E. coli growth at temperatures up to 42 degrees C under standard laboratory conditions but is essential for growth at 43 degrees C. However, the accumulation of extragenic suppressors is necessary for rapid bacterial growth at higher temperatures.     

Distribution of mannosamine and mannosaminuronic acid among cell walls of Bacillus species

Some Escherichia coli K-12 lamB mutants, those producing reduced amounts of LamB protein (one-tenth the wild type amount), grow normally on dextrins but transport maltose when present at a concentration of 1 microM at about one-tenth the normal rate. lamB Dex- mutants were found as derivatives of these strains. These Dex- mutants are considerably impaired in the transport of maltose at low concentrations (below 10 microM), and they have a structurally altered LamB protein which is impaired in its interaction with phages lambda and K10 but still interacts with a lambda host range mutant lambda hh*. The Dex- mutants are double lamB mutants carrying one mutation, already present in the parental strains, that reduces LamB synthesis and a second that alters LamB structure. The secondary mutations, present in different independent Dex- mutants, are clustered in the same region of the lamB gene. Dex+ revertants were isolated and analyzed: when the altered LamB protein is made in wild-type amount, due to a reversion of the first mutation, the phenotype reverts to Dex+. However, these Dex+ revertants are still very significantly impaired in maltose transport at low concentrations (below 10 microM).     

Mutants (ompA) affecting a major outer membrane protein of Escherichia coli K12.

Seventy independent mutants have been analyzed affecting a major protein, polypeptide II, of the outer cell envelope membrane from Escherichia coli K12. They were classified as nonsense mutants of the amber type (20%), mutants most likely of the missense type possessing the protein at normal concentrations (9%), and mutants either missing the protein or harboring it at much reduced concentrations for unknown reasons (71%). Forty of the mutants were analyzed genetically and all were found to map at or near ompA, the structural gene for protein II. Two-dimensional electrophoretic analyses of envelopes from such mutants revealed an unusual heterogeneity of the protein which on such patterns appeared as at least 12 well separated spots, and the majority of these is due to artifacts of the method but apparently specific for this protein. In no case was a polypeptide fragment found in envelopes from the nonsense mutants. The results are discussed regarding two different phages which use the protein as a receptor and concerning the biosynthetic incorporation of the protein into the outer membrane.     

Negative dominance in gene lamB: random assembly of secreted subunits issued from different polysomes

lamB is the structural gene for the lambda receptor, an oligomeric outer membrane protein from Escherichia coli K12 involved in phage lambda adsorption. We show that, under certain conditions, in a strain diploid for gene lamB, all the missense lamB mutations conferring lambda resistance that we have tested are dominant with respect to wild-type. We propose a model which allows a quantitative interpretation of the data. It is based on negative complementation at the level of oligomerisation. Wild-type and mutant subunits would assemble at random forming homo- and hetero-oligomers. Only wild-type homo-oligomers would be efficient for phage inactivation. For some classes of missense mutations the hetero-oligomers would have the capacity to bind, but not to inactivate the phage. The model confirms that active lambda receptor is a trimer and implies that for this secreted protein there is no preferential assembly of subunits originating from the same polysome.