Germinal Excision and Reinsertion Frequencies of the Mobile Element Ds Transposed from Two Unlinked T-DNA Loci in Tomato

Acceptor sites of unlinked transposed Ds element from two T-DNA loci in tomato were mapped. Experimental data obtained from TC₁ progeny testing were employed for estimation of germinal excision frequency (GEF) of Ds element and frequency of its reinsertion (FR). The donor T-DNAs 1481J and 1601D, containing a 35S:NPT transformation marker, a 35S:BAR or nos:BAR excision marker conferring phosphinothricine resistance and a Ds element in the 5 untranslated leader of the nos (or 35S): BAR gene, were located on chromosome 7 and 8, respectively. Ds transposition was induced by 105121 T-DNA carrying stabilized Ac (sAc) which provides a source of transposase and 2:GUS marker conferring -glucuronidase activity. Tomato plants harbouring the Ds in 1481J or 1601D locus and sAc were crossed and F₁D, were crossed individually as seed parents to wild-type plants to generate TC₁ progenies. TC₁ seed was germinated on phosphinothricine (Basta)-containing medium, and individual seedlings carrying a transposed Ds and lacking sAc were identified by PCR (to detect the Ds) on phosphinothricine resistant individuals that lacked -glucuronidase activity. From segregation ratio in TC₁ the germinal excision and reinsertion frequencies of the Ds element were estimated for individual F₁ plants. A total of 14560 TC₁ seedlings of 1481J and 16195 TC₁ seedlings of 1601D was analyzed. We observed high variation between individual plants as regards both GEF and FR despite of donor locus (1481J or 1601D), however, the average germinal excision frequencies as well as average frequencies of reinsertion were very similar for both donor loci: GEF_1481J = 24 %, GEF_1501D = 25 %, FR_1481J = 42 %, FR_1601D = 46 %.     

Host-dependent modification of bacteriophage T7 and SAMase-negative T3 derivatives affecting their adsorption ability

Summary When passaging phage T7 and SAMase-negative T3 mutants betweenE. coli strains with identical (EcoB) or without (EcoO) DNA host specificity, phenotypically a host-controlled modification and restriction is observed. This phenomenon is not due to classical modification and restriction of the bacteriophage DNA but depends on the reversibly altered adsorption capacity of the phages on the different host strains.     

Characterization of an unusual <Emphasis Type="Italic">Ds</Emphasis> transposable element in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>: Insertion of an abortive circular transposition intermediate

The maize Ac/Dstransposable elements, which belong to the hAT transposon superfamily, are widely used as insertional mutagens in numerous plant species. Molecular studies suggest that Ac/Ds elements transpose in a conservative non-replicative fashion; however the molecular mechanism of transposition remains unclear. We describe here the identification of an unusual Ds element, Ds-mmd1, in a transgenic Arabidopsis line. Ds-mmd1 is rearranged relative to the original Ds element, such that the original 5 and 3 ends are internal and previously internal sequences are the new 5 and 3 termini of Ds-mmd1. Short duplications of plant genomic DNA and Ds sequences are present at the Ds-mmd1 junctions, suggesting that a circular Dsmolecule was part of the events that created the Ds-mmd1 element. In addition, a revertant analysis on mmd1 plants demonstrated that Ds-mmd1 can be eliminated from the genome in an Ac-dependent process.     

T-even type phages can change their host range by recombination with gene 34 (tail fibre) or gene 23 (head)

Summary T-even type phages recognize their cellular receptors with the tip of their long tail fibres. The gene products involved in receptor recognition are proteins 37 and 38. While screening libraries of phage K3 with a probe of gene38 from phage T2, a class of weakly hybridizing clones was found in addition to the expected clones of gene38 of K3. One of these clones was identified as being from gene23 of the phage which codes for the major head subunit; another clone originated from gene34, which codes for the proximal half of the long tail fibres. Neither gene product 23 nor 34 is involved in receptor recognition. Phages can recombine with the DNA of the gene23 and gene34 clones and change the host range. This paper is dedicated to Prof. Dr. Wolfgang Beermann, Tübingen, on the occation of his 65^th birthday     

Tracing the interaction of bacteriophage with bacterial biofilms using fluorescent and chromogenic probes

Phages T4 and E79 were fluorescently-labeled with rhodamine isothiocyanate (RITC), fluoroscein isothiccyanate (FITC), and by the addition of 46-diamidino-2-phenylindole (DAPI) to phage-infected host cells ofEscherichia coli andPseudomonas aeruginosa. Comparisons of electron micrographs with scanning confocal laser microscope (SCLM) images indicated that single RITC-labeled phage particles could be visualized. Biofilms of each bacterium were infected by labeled phage. SCLM and epifluorescence microscopy were used to observe adsorption of phage to single-layer surface-attached bacteria and thicker biofilms. The spread of the recombinant T4 phage, YZA1 (containing an rll-LacZ fusion), within alac E. coli biofilm could be detected in the presence of chromogenic and fluorogenic homologs of galactose. Infected cells exhibited blue pigmentation and fluorescence from the cleavage products produced by the phage-encoded -galactosidase activity. Fluorescent antibodies were used to detect nonlabeled progeny phage. Phage T4 infected both surface-attached and surface-associatedE. coli while phage E79 adsorbed toP. aeruginosa cells on the surface of the biofilm, but access to cells deep in biofilms was somewhat restricted. Temperature and nutrient concentration did not affect susceptibility to phage infection, but lower temperature and low nutrients extended the time-to-lysis and slowed the spread of infection within the biofilm.     

Characterization of a phage specific to hemorrhagicEscherichia coli O157:H7 and disclosure of variations in host outer membrane protein OmpC

Phage AR1, previously known to infectEscherichia coli O157:H7 with high specificity, was further characterized for its genetic properties. The phage DNA sequences including capsid genes and a putative -glucosyltransferase gene(-gt) have been deduced. These sequences are conservative but not identical to those of T4 phage. However, a nonessential gene,SegD, organized within the capsid gene cluster of T4 is missing in the corresponding region of AR1 genome, and this characteristic has not been observed among T-even related phages. The difference between AR1 and T4 was further exemplified by their distinct host ranges. Strains ofE. coli O157:H7 collected from different sources were permissive to AR1 but resistant to T4 that normally infects K-12 strains ofE. coli through contact with the outer membrane protein OmpC. Thus, the O157:H7 strains must have a varied OmpC. Indeed, the OmpC sequence of O157:H7 strains was proved to differ from that of K-12 strains by a total of 15 amino acid substitutions and two gaps (a five-residue deletion and a four-residue insertion). The OmpC molecules are relatively conserved across the gram-negative bacteria, and this is the first time OmpC divergence has been found within the sameE. coli species. Since OmpC is located in the outer membrane and its expression is regulated by environmental conditions, alteration of the structure in pathogenic O157:H7 strains may have biological significance.     

Establishment of a gene tagging system in Arabidopsis thaliana based on the maize transposable element Ac

Summary An Ac-derived, two-component transposable element system has been developed and analyzed with respect to its use in Arabidopsis thaliana. This system consists of an immobilized Ac element (Ac clipped wing, Ac_cl) as the source of transactivating transposase and a nonautonomous Ds element, Ds_A, which is inserted into a chimaeric neomycinphosphotransferase gene used as excision marker. After separate introduction of Ac_c1 and Ds_A into Arabidopsis thaliana, progeny analysis of crosses between five different Ac_cl lines and seven different Ds_A lines shows that: (1) different Ac_cl lines differ greatly in their capacity to transactivate Ds_A; (2) different Ds_A lines do not differ significantly with respect to Ds_A transactivation by one Ac_cl line; (3) reintegration of excised Ds_A elements, both at (genetically) linked and unlinked sites, occurs in about 50% of the excision events; and (4) plants with a high rate of somatic excisions can be used as source of new Ds_A transpositions, allowing the creation of a large number of independent Ds_A insertions.     

Reaktivierung von UV-Schäden in Salmonella typhimurium

Summary The uv- and x-ray sensitivity for colony formation of Salmonella typhimurium has been compared. If the comparation is done on the basis of equal sensitivity of the bacterial gene responsible for host reactivation of uv-damaged P22, the uv-sensitivity of colony formation is only 1/4 of the sensitivity to x-ray irradiation.It is concluded, that 3/4 of the uv-damage to colony formation in Salmonella typhimurium can be reactivated by the cell itself. This reactivable sector of uv-damage in the bacterial cell is the same as the sector of hostreactivable uv-damages in the phage P22 which is able to grow and to be hostreactivated in Salmonella typhimurium.     

Inhibition of modification and restriction for phages lambda and T-1 by co-infecting T3

Summary The host controlled modifications of phage -DNA byEscherichia coli B, K, and C (P1) can be suppressed by preinfecting the bacteria with UV-irradiated phage T3. Since UV-irradiated T3 induces an enzyme which cleaves S-adenosylmethionine into homoserine and thiomethyl adenosine, and since S-adenosylmethionine is the only methyl group donor for DNA methylation, we conclude that methylation is a required step in the host controlled modification of -DNA.T3 itself successfully infectsE. coli K and B with its nonmethylated DNA. Also, restricted phage or T1 will be accepted by the restrictive hostsE. coli B, K, and C(P1) if these are preinfected with UV-T3. It thus appears that T3 is capable of blocking the restriction mechanisms in these hosts.The inability of T3 to grow on C(P1) is not understood. Since T3-DNA is restricted but not degraded into nucleotides byE. coli C(P1) we presume that degradation is not the initial step in restriction.Supported by Grant No. GB 1033 R of the National Science Foundation.Postdoctoral fellow of the Deutsche Forschungsgemeinschaft.     

Excision and transposition of two Ds transposons from the bronze mutable 4 derivative 6856 allele of Zea mays L

Summary The regulatory mutation bronze mutable 4 Derivative 6856 (bz-m4 D6856) contains a complex 6.7 kb Dissociation (Ds) element tagged with a duplication of low copy bz 3 flanking sequences (Klein et al. 1988). This creates a unique opportunity to study the transposition of a single member of the repetitive family of Ds elements. Eighteen full purple revertants (Bz alleles) of bz-m4 were characterized enzymatically and by genomic mapping. For 17 of the Bz alleles, reversion to a wild-type phenotype was caused by excision of the 6.7 kb Ds transposon. Nine of these Bz alleles retained the transposon somewhere in their genome. In this study we show that like Ac (Schwartz 1989; Dooner and Belachew 1989), the 6.7 kb Ds element can transpose within a short physical distance, both proximal and distal to its original position. Additional bz sequences have been mapped immediately distal to the mutant locus in bz-m4 D6856; genetic evidence suggests these are flanked by two additional Ds elements. The remaining Bz revertant, Bz :107, arose from excision of a more complex 13 kb Ds element.     

Adsorption of bacteriophage on bacterial surface and on the surface of Hg dropping electrode

Summary The influence of the ionic strength of the medium on the adsorption of bacteriophage T 2 to the surfaces of a mercury dropping electrode on one hand and ofbacteria E. coli B on the other hand was studied. The adsorption on the mercury surface was determined by measurement of the differential capacity of the electrode double layer, the adsorption to bacteria was estimated from the decrease of free phage particles in a bacterial suspension with time. The adsorption to the mercury electrode increases with increasing ionic strength of the medium, but adsorption to the surface of bacteria increases at first, has a maximum at concentrations between 0,1 to 0,5 M and decreases with further increase of ionic strength. The decrease of adsorption of phage to the bacterial surface is assumed to be caused by the blocking of specific sites on the bacterial surface by adsorbed ions which sterically prevent the adsorption of the phage. Such specific sites are not present on the electrode surface, therefore adsorption increases further with increasing ionic strength probably due to the neutralization of surface charges of the phage and of the electrode. The saturated surface-concentration of the phage _s was calculated from the dependence of the differential capacity on the concentration. It is concluded from _s value obtained that the phage particles are scattered with wide intervals on the electrode surface with a degree of coverage of approximately 140.Abbreviations used DNA deoxyribonucleic acid - N Avogadro number The authors wishes to express their gratitude to the late Prof.Ferdinand Hercík, director of the Institute of Biophysics, for the initiation of this work and stimulating interest. The authors are also indebted to Dr. J.Koudelka for his kind gift of phage T 2 sample and to Dr. M.Vízdalová for her valuable comments during preparation of this article.     

Functions related to the receptor protein specified by the tsx gene of Escherichia coli

The receptor protein for the phage T6 and colicin K, coded by the tsx gene, facilitated the diffusion of all nucleosides and deoxynucleosides except cytidine and deoxcytidine through the outer membrane of Escherichia coli K-12 and Escherichia coli B. The tsx protein was coregulated with the nucleoside uptake system. Constitutive cytR and deoR mutants contained higher amounts of this protein than wild type strains. There was a good correlation between the initial rate of nucleoside uptake and the adsorption rate of phage T6. From the observation that nucleosides did not compete with each other in the translocation across the outer membrane and that they did not inhibit T6 adsorption it was concluded that the tsx protein forms a pore to which nucleosides have only little if any binding affinity.A major outer membrane protein specified by the ompA gene influenced the function of the tsx protein. Outer membranes of ompA mutants showed an enhanced binding of colicin K but the strains were colicin K insensitive (tolerant). The T6 phage adsorbed at the same rate and plated with the same efficiency as to ompA ⁺ strains. The uptake rate of thymidine and of adenosine was reduced by 16–33% in ompA mutants.The adsorption rate of phage T6 on mutants with altered lipopolysaccharide was the same or even higher than on wild type strains. However the plating efficiency was reduced ranging from 0–46%. Lipopolysaccharide plays no role in the primary adsorption of phage T6 but it is apparently required in a later step of the infection process.Non Standard Abbreviations LPS lipopolysaccharide - cAMP-CRP complex of cyclic adenosine 3,5-monophosphate (cAMP) and its receptor protein (CRP)     

Interactions between a genetically markedPseudomonas fluorescens strain and bacteriophage ΦR2f in soil: Effects of nutrients, alginate encapsulation, and the wheat rhizosphere

The introduction of bacteriophages could potentially be used as a control method to limit the population size of engineered bacteria that have been introduced into soil. Hence, the ability of a species-specific phage, R2f, to infect and lyse its host, a Pseudomonas fluorescens R2f transposon Tn5 derivative, in soil, was studied. Control experiments in liquid media revealed that productive lysis of host cells by phage R2f occurred when cells were freely suspended, whereas cells present in alginate beads resisted lysis. The presence of nutrients enhanced the degree of lysis as well as the production of phage progeny, both with the suspended cells and with cells escaped from the alginate beads. Experiments in which host cells and phage R2f were introduced into two soils of different texture revealed that host cells were primarily lysed in the presence of added nutrients, and phage reached highest titres in these nutrient-amended soils. Encapsulation of the host cells in alginate beads inhibited lysis by the phage in soil. Populations of free host cells introduced into soil that colonized the rhizosphere of wheat were not substantially lysed by phage R2f. However, P. fluorescens R2f populations colonizing the rhizosphere after introduction in alginate beads were reduced in size by a factor of 1,000. Cells migrating from the alginate beads towards the roots may have been in a state of enhanced metabolic activity, allowing for phage R2f infection and cell lysis. Correspondence to: J.D. van Elsas     

Morphologie und Wirtskreis eines neu isolierten Rhodopseudomonas palustris-Phagen

Zusammenfassung Aus Teichwasser in der Nähe Freiburgs wurde ein Bacteriophage angereichert, der Rhodopseudomonas palustris, Stamm 1 e 5 befällt. Dieser, als Rp 1 bezeichnete Phage kann in anaeroben Lichtkulturen von Rps. palustris bis zu einem Titer von 10⁹ vermehrt werden. Der Infektionscyclus findet auch in aerober Dunkelkultur statt. Von 17 untersuchten Rps. palustris-Stämmen wird nur der Stamm 1 e 5 befallen und bei ihm die Entwicklung von Plaques beobachtet. Das Capsid des Phagen ist icosaedrisch. Die Capsomeren erscheinen pentagonal. Das Capsid hat einen Durchmesser von 380–390 . Die Festheftung des Phagen an der Oberfläche der Wirtszelle oder an den Thylakoiden erfolgt mit einer röhrenförmigen Struktur, die 200 lang und 55–60 dick ist.

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Morphology and host range of a new isolated Rhodopseudomonas palustris-phage

Summary A Phage active against Rhodopseudomonas palustris was isolated from freshwater ponds near Freiburg. The Phage is called Rp 1. Rp 1 could be propagated to titres of 10⁹ plaque-forming units/ml in anaerobic light cultures. It is also synthesized in aerobic dark cultures of Rps. palustris strain 1 e 5. The host range of this phage is very narrow. Only one of seventeen strains of Rps. palustris is able to propagate the phage. The other tested Athiorhodaceae do not give rise to plaque development. The Rp 1 virus consists of an icosahedral head (380–390 in diameter) and a tail like structure. After degradation of the capsid pentagonal capsomeres become visible. The phages are attached by a hollow tube (length 200 , diameter 55–60 ) to the host cell. In negative stained preparations of phages many Rp 1 are seen attached to the thylakoid of the bacteria.

     

Kinetics of proflavin binding to bacteriophages T2L and T4D

We have measured the kinetics of proflavin binding to T-even bacteriophages—the 700 S and 1000 S forms of T2L, T4D, and T4D os41—by difference spectroscopy at 430 nm. Measurements were carried out from 22° to 37°C. Binding is very slow to encapsulated DNA compared to free DNA, requiring hours to reach equilibrium. The kinetic data are compatible with the two-step mechanism where P is proflavin, N is nucleotide, and PN₁ and PN₂ are complexes. Computer integration of the rate equations allows evaluation of the rate constants; previous equilibrium measurements gave thermodynamic parameters. For all phage studied, the bimolecular step is endothermic with high positive entropy; the second, unimolecular step is highly exothermic with small negative entropy change. Both forms of T2L bind proflavin with essentially the same rate, as do T4D and the osmotic shock resistant mutant T4D os41. This suggests that the encapsulated DNA is equally accessible to proflavin in both forms of each phage. However, T4D binds dye appreciably faster than T2L, indicating that capsid permeability or DNA environment (glucosylation or packing) is different in the two species.     

Mapping of transposable element<Emphasis Type="Italic"> Dissociation</Emphasis> inserts in<Emphasis Type="Italic"> Brassica oleracea</Emphasis> following plant regeneration from streptomycin selection of callus

To investigate the potential of heterologous transposons as a gene-tagging system in broccoli (Brassica oleracea var. italica), we have introduced a Dissociation (Ds)-based two-element transposon system. Ds has been cloned into a 35S-SPT excision-marker system, with transposition being driven by an independent 35S-transposase gene construct. In three successive selfed generations of plants, there was no evidence of germinal-excision events. In a previous study, we overcame this apparent inability to produce B. oleracea plants with germinal excisions by performing a novel tissue-culture technique to select for fully green shoots from seed with somatic excision events. The results showed a very high efficiency of regeneration of fully green plants (up to 65%), and molecular analysis showed that the plants contained the equivalent of a germinal-excision event. In this study, we followed the previous work by using inverse and nested PCR to generate probes of flanking genomic DNA adjacent to independently reinserted Ds elements, and these were hybridised to DNA from a double-haploid mapping population of B. oleracea. Seventeen Ds insertions and the original Ds T-DNA site have been localised, and these are spread over six (out of nine) linkage groups. Distribution of inserts show that 15 were found on a different linkage group to the original launch site, and of these 11 were found to be clustered on two separate groups. Previous studies in other plant species have found that germinal excision of Ds predominantly moves to sites linked close to the donor site. However, this study shows a potential to produce plants with Ds insertion scattered over many unlinked sites.Comunicated by C. Möllers     

Development of an efficient two-element transposon tagging system in Arabidopsis thaliana

Summary Modified Ac and Ds elements, in combination with dominant markers (to facilitate monitoring of excision, reinsertion and segregation of the elements) were introduced into Arabidopsis thaliana ecotype Landsberg erecta. The frequencies of somatic and germinal transactivation of the Ds elements were monitored using a streptomycin resistance assay. Transactivation was significantly higher from a stable Ac (sAc) carrying a 537 by deletion of the CpG-rich 5 untranslated leader of the transposase mRNA than from a wild-type sAc. However, substitution of the central 1.77 kb of the transposase open reading frame (ORF) with a hygromycin resistance marker did not alter the excision frequency of a Ds element. -Glucuronidase (GUS) or iaaH markers were linked to the transposase source to allow the identification of plants in which the transposase source had segregated away from the transposed Ds element, eliminating the possibility of somatic or germinal re-activation. Segregation of the excision marker, Ds and sAc was monitored in the progeny of plants showing germinal excision of Ds. 29% of the plants inheriting the excision marker carried a transposed Ds element.     

Cloning and expression in Escherichia coli, Bacillus subtilis, and Streptococcus sanguis of a gene for staphylokinase--a bacterial plasminogen activator

Summary The gene coding for the bacterial plasminogen activator staphylokinase was cloned from the Staphylococcus aureus phage 42D, a serogroup F phage used for lysotyping, onto the standard Escherichia coli plasmid vector pACYC184. The coding and flanking sequences of the sak42D gene were largely identical to those of a sak gene cloned from the serologically different S. aureus phage SøC (Sako and Tsuchida 1983). Subcloning of a 2.5 kb phage 42D DNA fragment onto plasmid pGB3631 allowed the sak42D gene to be introduced into the gram-positive hosts Bacillus subtilis and Streptococcus sanguis. The sak42D gene was expressed and secreted most efficiently by B. subtilis cells (25 g/ml of culture supernatant) reduced in exoprotease production. In this host expression and secretion of Sak was initiated at the early growth phase and continued through the logarithmic phase. Formation of Sak was, however, also observed with the other cloning hosts. The Sak elaborated by the heterologous hosts was serologically identical with authentic Sak derived from S. aureus.     

Host genes involved in the replication of single-stranded DNA phage ?K

Summary Using various replication mutants of E. coli, the host genes that participate in the replication of some K12-specific single-stranded DNA phages have been determined. Functional products of dnaE,-F,-G and -Z genes are required for the multiplication of K, whereas dnaA,-B,-C(D), H,-I and -P are dispensable for viral replication. In contrast with polB, recA, B, C, or xth functions, host rep activity is essential for K. At the restrictive temperature, the yield of K was markedly reduced in the ligts7 mutant and partially decreased in a polA ^ts strain. The phage K is thus less dependent on the host cells than X174 and A which require additionally the dnaB,-C(D) and -H functions. Replication of phage St-1 depends on dnaG and -Z gene products, but not on dnaP function. Although not much affected in polA ^ts host, growth of St-1 was significantly diminished in dnaF or ligts7 mutants.     

Isolation and characterization of lambda b221poriCasnA, a plaque-forming specialized transducing phage carrying the origin of replication of the Escherichia coli chromosome

Summary A specialized transducing phage, b221poriCasnA has been isolated carrying oriC the origin of chromosomal replication of Escherichia coli. All phage genes required for lytic growth are retained, thus the phage is capable of lytic growth. The presence of the oriC locus confers upon infecting phage DNA the ability to replicate as a plasmid using only host DNA replication functions. The presence of both oriC and asnA markers has allowed the development of a plaque assay for origin function which can be used to identify mutants at these loci. Comparison of restriction endonuclease cleavage sites present on b221poriCasnA DNA to those on tis parent, b221 rex::Tn10 suggests the steps involved in the formation of the transducing phage.