Role of the G segment in the growth of phage Mu

Site-specific DNA Inversion by Serine Recombinases

Reversible site-specific DNA inversion reactions are widely distributed in bacteria and their viruses. They control a range of biological reactions that most often involve alterations of molecules on the surface of cells or phage. These programmed DNA rearrangements usually occur at a low frequency, thereby preadapting a small subset of the population to a change in environmental conditions, or in the case of phages, an expanded host range. A dedicated recombinase, sometimes with the aid of additional regulatory or DNA architectural proteins, catalyzes the inversion of DNA. RecA or other components of the general recombination-repair machinery are not involved. This chapter discusses site-specific DNA inversion reactions mediated by the serine recombinase family of enzymes and focuses on the extensively studied serine DNA invertases that are stringently controlled by the Fis-bound enhancer regulatory system. The first section summarizes biological features and general properties of inversion reactions by the Fis/enhancer-dependent serine invertases and the recently described serine DNA invertases in Bacteroides. Mechanistic studies of reactions catalyzed by the Hin and Gin invertases are then discussed in more depth, particularly with regards to recent advances in our understanding of the function of the Fis/enhancer regulatory system, the assembly of the active recombination complex (invertasome) containing the Fis/enhancer, and the process of DNA strand exchange by rotation of synapsed subunit pairs within the invertasome. The role of DNA topological forces that function in concert with the Fis/enhancer controlling element in specifying the overwhelming bias for DNA inversion over deletion and intermolecular recombination is emphasized.

Crossing the line: selection and evolution of virulence traits

The evolution of pathogens presents a paradox. Pathogenic species are often absolutely dependent on their host species for their propagation through evolutionary time, yet the pathogenic lifestyle requires that the host be damaged during this dependence. It is clear that pathogenic strategies are successful in evolutionary terms because a diverse array of pathogens exists in nature. Pathogens also evolve using a broad range of molecular mechanisms to acquire and modulate existing virulence traits in order to achieve this success. Detailing the benefit of enhanced selection derived through virulence and understanding the mechanisms through which virulence evolves are important to understanding the natural world and both have implications for human health.

Two DNA invertases contribute to flagellar phase variation in Salmonella enterica serovar Typhimurium strain LT2

Salmonella enterica serovar Typhimurium strain LT2 possesses two nonallelic structural genes, fliC and fljB, for flagellin, the component protein of flagellar filaments. Flagellar phase variation occurs by alternative expression of these two genes. This is controlled by the inversion of a DNA segment, called the H segment, containing the fljB promoter. H inversion occurs by site-specific recombination between inverted repetitious sequences flanking the H segment. This recombination has been shown in vivo and in vitro to be mediated by a DNA invertase, Hin, whose gene is located within the H segment. However, a search of the complete genomic sequence revealed that LT2 possesses another DNA invertase gene that is located adjacent to another invertible DNA segment within a resident prophage, Fels-2. Here, we named this gene fin. We constructed hin and fin disruption mutants from LT2 and examined their phase variation abilities. The hin disruption mutant could still undergo flagellar phase variation, indicating that Hin is not the sole DNA invertase responsible for phase variation. Although the fin disruption mutant could undergo phase variation, fin hin double mutants could not. These results clearly indicate that both Hin and Fin contribute to flagellar phase variation in LT2. We further showed that a phase-stable serovar, serovar Abortusequi, which is known to possess a naturally occurring hin mutation, lacks Fels-2, which ensures the phase stability in this serovar.

DNA sequences of the tail fiber genes of bacteriophage P2: evidence for horizontal transfer of tail fiber genes among unrelated bacteriophages

We have determined the DNA sequence of the bacteriophage P2 tail genes G and H, which code for polypeptides of 175 and 669 residues, respectively. Gene H probably codes for the distal part of the P2 tail fiber, since the deduced sequence of its product contains regions similar to tail fiber proteins from phages Mu, P1, lambda, K3, and T2. The similarities of the carboxy-terminal portions of the P2, Mu, ann P1 tail fiber proteins may explain the observation that these phages in general have the same host range. The P2 H gene product is similar to the products of both lambda open reading frame (ORF) 401 (stf, side tail fiber) and its downstream ORF, ORF 314. If 1 bp is inserted near the end of ORF 401, this reading frame becomes fused with ORF 314, creating an ORF that may represent the complete stf gene that encodes a 774-amino-acid-long side tail fiber protein. Thus, a frameshift mutation seems to be present in the common laboratory strain of lambda. Gene G of P2 probably codes for a protein required for assembly of the tail fibers of the virion. The entire G gene product is very similar to the products of genes U and U' of phage Mu; a region of these proteins is also found in the tail fiber assembly proteins of phages TuIa, TuIb, T4, and lambda. The similarities in the tail fiber genes of phages of different families provide evidence that illegitimate recombination occurs at previously unappreciated levels and that phages are taking advantage of the gene pool available to them to alter their host ranges under selective pressures.

Minute amounts of RNA are synthesized from several regions of the bacteriophage Mu DNA during the lysogenic state

The transcription of phage Mu DNA during the lysogenic state has been quantitatively analysed. For this purpose pulse-labelled RNA from two lysogens and from their nonlysogenic parental strains were hybridized to non-overlapping Mu DNA restriction fragments covering the whole phage genome. The data revealed that all regions of the prophage are transcribed at low rates and that phage promoters are involved in this transcription. For this study an improved assay for quantitative filter hybridization was employed. The high sensitivity and reproducibility that can be obtained with the assay make it suitable for the quantitative analysis of minute amounts of mRNA.

Highly mobile DNA segment of IncI alpha plasmid R64: a clustered inversion region

When R64 DNA was digested with EcoRI, two DNA fragments not equimolar to the plasmid DNA were produced. A DNA region including these fragments was cloned (pKK009), and the pKK009 DNA sample was found to be a mixture of six or more DNA species with EcoRI, PstI, and AvaI cleavage sites at different positions, suggesting a complex rearrangement of DNA. When a part of the pKK009 DNA was removed by HindIII digestion, 33 different types of plasmids (pKK010-series plasmids) were obtained out of 58 clones tested, but no DNA rearrangement could be observed. On the basis of a comparison of the detailed restriction maps of these pKK010-series plasmids, we propose a model in which four DNA segments invert independently or in groups within the 1.95-kilobase region of R64, so that the arrangements of these four segments change randomly. The fixed pKK010-series plasmid DNA was again rearranged in the presence of R64, indicating that trans-acting gene function may be present to mediate the DNA rearrangement. The gene (tentatively designated as rci) was located on a 4.5-kilobase E9' fragment of R64.

A Mu gin complementing function and an invertible DNA region in Escherichia coli K-12 are situated on the genetic element e14

The Gin product catalyzes an inversion of 3,000 base pairs of DNA in the genome of bacteriophage Mu. The orientation of the invertible of G-region determines the host range of the phage. Gin- mutants are complemented by a host function in strain HB101 and several other Escherichia coli K-12 strains. At least three clones in the E. coli gene bank described previously (L. Clarke and J. Carbon, Cell 9:91-99, 1976) contained the gin complementing function. This function, which we named pin, catalyzes an inversion of 1,800 base pairs in the adjacent DNA. The invertible region, named the P-region, together with pin, was further subcloned on pBR322. Conjugation and transduction experiments mapped the pin gene between the genes purB and fabD near position 25 on the E. coli chromosome. Also situated in this region is e14, a cryptic, UV- excisable , genetic element (A. Greener and C.W. Hill, J. Bacteriol . 144:312-321, 1980). We demonstrated that pin and the P-region are part of e 14. The e 14 element was cloned on pBR322 by genetic manipulation techniques in vivo. It has the properties of a defective prophage containing integration and excision functions and a SOS-sensitive repressor.

Involvement of the invertible G segment in bacteriophage mu tail fiber biosynthesis

The orientation [G(+) or G(-)] of the invertible G segment of bacteriophage Mu DNA determines the host range specificity of the phage particles. In this study the hypothesis that the G segment genes are involved in synthesis of Mu tail fibers has been tested. Serum blocking power (SBP) assays demonstrated that among Mu late gene mutants only those defective in genes S or U encoded by the G segment were defective in G(+) SBP and that they lacked the same antigens. Electron microscopy of lysates produced by inversion-defective gin mutants (isolated by their inability to complement a hin inversion-defective mutant of the Salmonella phase variation segment) showed that G(+) phages with amber mutations in S or U made tail-fiberless particles with contracted tail sheaths. Inversion of G to the G(-) orientation or suppression of the amber mutations restored the normal phage particle morphology. These experiments demonstrate that genes S and U are required for Mu G(+) tail fiber biosynthesis and/or attachment.

Bacteriophage P1 carries two related sets of genes determining its host range in the invertible C segment of its genome

The bacteriophage P1 genome carries an invertible C segment consisting of 3-kb unique sequences flanked by 0.6-kb inverted repeats. Host range mutations of P1 have been mapped in the C segment region. P1 derivatives carrying insertions and deletions in the left half of the C segment in one of two orientations termed C(+) do not affect the plaque-forming ability on Escherichia coli K12 and E coli C, whereas those having insertions in the right half of the C segment fail to form plaques on these hosts. An E. coli C mutant which allows the latter insertion mutants with the C segment in the C(-) configuration to form plaques has been isolated. Not only P1 C(-) but also P1 C(+) phages gave plaques on this E. coli C mutant. The results are consistent with the notion that the C segment of P1 carries two sets of genes for host specificity, and that C inversion alters the P1 host range through activation of one set of the genes. Furthermore, extended host range mutants can be isolated by point mutation in either set of the P1 genes. C inversion is a slow process, but it occurs on the phage genome upon its vegetative growth as well as on the prophage in the lysogenic state. The 3-kb invertible G segment of the phage Mu genome is known to be homologous with the central 3-kb part of the C segment of P1 and to carry also two sets of genes for Mu host specificity. While only Mu G(-) grows on E. coli C, both Mu G(+) and Mu G(-) phages form plaques on the E. coli C mutant sensitive to P1 C(-). In the discussion the gene organization of the P1 C segment is compared with that of the Mu G segment.

Expression of the gin and mom genes of bacteriophage Mu

The gin and mom genes are located in the rightmost 1.6-kb segment, designated the beta segment, of bacteriophage Mu DNA. The gin gene is responsible for the inversion of the G segment of Mu, whereas the mom gene is involved in an unusual modification of the DNA. We have analyzed recombinant plasmids carrying one or both ends of Mu DNA for the expression of the Gin and Mom functions. The Gin protein and the presumptive Mom protein are not always detected in minicells, even though the plasmids being tested have the gin- and mom-containing segment of Mu DNA. However, some plasmids, in which the right end segment of Mu DNA is confined to the 1.6-kb beta segment, do give rise to these gene products in minicells. It seems that synthesis of the Gin and Mom proteins is inhibited in minicells, but this inhibition is lifted if most of the DNA to the left of the beta segment is eliminated from the plasmids. The most prominent Mu product detected in minicells is a 23-25-kDal polypeptide, termed here the zeta (zeta) protein. The function of the zeta protein remains unknown. In vitro transcription of Mu DNA with purified Escherichia coli RNA polymerase is limited to only two regions of the genome. The early region of Mu DNA is transcribed at a relatively high efficiency, whereas the beta region is transcribed at a low efficiency. This low-efficiency transcription appears to be specific for the gin gene; the mom gene transcript cannot be detected.

Production and modification of Mu (G-) phage particles in E. coli K12 and Erwinia

We studied the amount of Mu(G+) and Mu(G−) phages in different Mu lysates prepared either upon induction or upon infection ofE. coliandErwiniastrains. We also looked at the level of expression of the modification function (mom) by Mu(G−) phages, both after induction and after infection ofE. coliandErwinia. The expression ofmomseems to be regulated in the same manner inE. coliand in the strain ofErwinia carotovoratested. The proportion of both types of Mu(G+) and Mu(G−) phages in induced lysates is very variable and we found growth conditions favouring the production of Mu(G−) particles. This should extend the use of Mu as a genetic tool and as a generalized transducing phage to many enterobacteria.

Physical characterization of mini-mu and mini-D108

Several derivatives of phages Mu and D108 have been isolated that carry an internal deletion generated by one of the IS1 components of a Tn9 transposon located in the A, B, or S gene of the prenatal phage. The deletions remove most of the lytic functions of the phage but leave intact either genes A and B or gene A and the left and the right end of the phages. These deleted derivatives, called mini-Mu and mini-D108, were physically characterized by electron microscopy and digestion with restriction enzymes. Mini-Mu and mini-D108, which carry an antibiotic resistance marker, are described and some of their genetic properties are summarized in the paper by Toussaint et al. (1981).

Invertible DNA determines host specificity of bacteriophage mu

The function of the invertible G region of bacteriophage Mu is apparently to confer different host specificities on Mu. Two products of genes S and U, situated in the G region are not needed for the infectivity of Mu G(-) particles. In the Mu G(-) phage the S gene product and the 21-K polypeptide, presumably the product of gene U, are missing. Instead, two other polypeptides with different molecular weights are observed.

Binary developmental commitments in normal and abnormal human morphogenesis

An hypothesis is presented to account for the occurrence of overlapping patterns of anomalies in various malformation syndromes. According to this proposal, normal human morphogenesis occurs by means of a series of sequential commitments by neighboring groups of cells to alternative developmental programs.

Inversion induced by temperature bacteriophage mu-1 in the chromosome of Escherichia coli K-12

Induction of the Mu prophage of a lysogenic HfrP4X strongly stimulates the early transfer of the purE gene, which is located far from the origin of transfer. By using a rec- Mu cts62 X lysogenic donor, it was established that this process reflects the inversion of the origin of transfer in part of the Hfr population. Hfr's with inverted polarity of gene transfer were isolated; their analysis suggests that two Mu genomes in opposite orientation surround the inverted DNA fragment. Due to the presence of the Mu genome of the invertible G segment, homologous regions in the same orientation can appear in Mu genomes in opposite orientation. In a Rec+ background, Hfr's with inverted polarity (i) return to their original polarity of transfer by recomination between the two inverted Mu and (ii) produce new F' strains by recombination between the two similarly oriented G segments.

Mapping of the modification function of temperate phage Mu-1

Using internal deletions in the Mu genome, we have mapped the gene coding for Mu modification in the beta segment of Mu DNA.

Map position of the replication terminus on the Escherichia coli chromosome

The directions of replication of several prophages integrated with a known orientation in the vicinity of the terminus (tre) of chromosome replication (trp::Mu, min 27; lambda rev integrated within rac, min 31, man::Mu, min 35), have been established by determining the molecular polarity of Okazaki pieces specific to these prophages. The results obtained strongly suggest that the site tre is located between rac and man, an otherwise genetically silent region.

Chromosomal rearrangements by an IS2 insertion in phage Mu-1

We have isolated and characterized a mutant of temperate phage Mu-1 carrying an IS2 insertion in the middle of its beta region. This mutant gives rise spontaneously to secondary mutants which have deletions of different sizes adjacent to IS2. One particular derivative however, was found to have acquired an additional insertion sequence adjacent to IS2. This derivative gave rise to tertiary mutants carrying a deletion next to the tandem insertion. The tandem insertion was located at the same place in the Mu beta region as another 2.6 kb insertion independently isolated by Chow et al. (1977) and was found to be homologous to that insertion. The properties of this particular secondary mutant show that Mu phage particles lacking their S end are defective for growth and lysogenisation.