Repressor gene finO in plasmids R100 and F: constitutive transfer of plasmid F is caused by insertion of IS3 into F finO.

Fertility factor F confers bacterial conjugation, a process which involves at least 20 tra genes. Resistance plasmids such as R100, R6-5, and R1 have homology with F in the tra region. Conjugal transfer of these plasmids is, however, repressed, while transfer of F is constitutive. Repression of R transfer is due to the existence of the two genes, called finO and finP; constitutive transfer of F is believed to be due to a lack of finO in F. In this paper, we report the identification and DNA sequence of the finO gene of R100, encoding a protein of 21,265 daltons. We show that F does actually encode finO, but the gene has been inactivated by insertion of IS3. Lederberg and Tatum (Nature [London] 158:558, 1946), who discovered sexuality in bacteria, may have had an Escherichia coli K-12 strain harboring such an finO F factor, which facilitated the generation of recombinant progeny useful for genetic analysis of bacteria and established the foundation for molecular genetics.     

DNA sequence analysis of point mutations in traA, the F pilin gene, reveal two domains involved in F-specific bacteriophage attachment

Summary Six missense point mutations in traA (WPFL43,44,45,46,47 and 51), the gene encoding F pilin in the transfer region of the F plasmid, have been characterized for their effect on the transfer ability, bacteriophage (R17, QB and fl) sensitivity and levels of piliation expressed by the plasmid. The sequence analysis of the first five of these mutations revealed two domains in the F pilin subunit exposed on the surface of the F pilus which mediate phage attachment. These two domains include residues 14–17 (approximately) and the last few residues at the carboxy-terminus of the pilin protein. One of these mutants had a pleiotropic affect on pilus function and was thought to have affected pilus assembly. The sixthe point mutant (WPFL51), previously thought to be in traA, was complemented by chimeric plasmids carrying the traG gene of the F transfer region, which may be involved in the acetylation of the pilin subunit. A traA nonsense mutant (JCFL1) carried an amber mutation near the amino-terminus which is well suppressed in SuI⁺ (supD) and SuIII⁺ (supF) strains. Neither the antigenicity of the pilin nor the efficiency of plating of F-specific bacteriophages were affected when this plasmid was harbored by either suppressor strain. A second amber mutant (JCFL25) which is not suppressible, carried its mutation in the codon for the single tryptophan in F pilin, suggesting that this residue is important in subunit interactions during pilus assembly. Two other point mutants (JCFL32 and 44) carried missense mutations in the leader sequence (positions 9 and 13) which affected the number of pili per cell presumably by altering the processing of propilin to pilin.     

Candidate cis-elements for human renin gene expression in the promoter region

The regulation of renin gene expression, the rate‐limiting enzyme of the system, is thought to be fundamental to the total system. Previously, we mapped six putative cis‐elements in the promoter region of the human renin gene with nuclear proteins from human chorionic cells and human renal cortex by DNase I protection assay (footprint A–F). Each footprint contains Ets motif like site (A), HOXñPBX recognition sequence (B), unknown sequence as DNA binding consensus (C), CRE (D), COUP‐TFII (ARP‐1) motif like site (E), and AGE3 like site (F). Footprint D has been characterized by means of functional studies as the genuine human renin gene CRE interacting with CREB in cooperation with the site of footprint B. To obtain further clues to the specific expression in the promoter region, these putative cis‐elements were conducted to a consensus‐specific binding assay to compare renin‐producing and non‐renin‐producing cells by EMSA and electromobility super‐shift assay. Different sequence‐specific DNA/protein binding was obtained among the different cell lines with footprint B site, with COUP‐TFII (ARP‐1) motif like site and possibly with footprint F site. The results implicate these putative cis‐elements and each corresponding trans‐factor in the specific expression of the human renin gene in the promoter region. Further functional characterization of these elements would provide important data for a better understanding of human renin gene expression. © 2004 Wiley‐Liss, Inc.     

Genetic Analysis of the Role of the Transfer Gene, traN, of the F and R100-1 Plasmids in Mating Pair Stabilization during Conjugation

Mating pair stabilization occurs during conjugative DNA transfer whereby the donor and recipient cells form a tight junction which requires pili as well as TraN and TraG in the donor cell. The role of the outer membrane protein, TraN, during conjugative transfer was examined by introduction of a chloramphenicol resistance cassette into the traN gene on an F plasmid derivative, pOX38, to produce pOX38N1::CAT. pOX38N1::CAT was greatly reduced in its ability to transfer DNA, indicating that TraN plays a greater role in conjugation than previously thought. F and R100-1 traN were capable of complementing pOX38N1::CAT transfer equally well when wild-type recipients were used. F traN, but not R100-1 traN, supported a much lower level of transfer when there was an ompA mutation or lipopolysaccharide (LPS) deficiency in the recipient cell, suggesting receptor specificity. The R100-1 traN gene was sequenced, and the gene product was found to exhibit 82.3% overall similarity with F TraN. The differences were mainly located within a central region of the proteins (amino acids 162 to 333 of F and 162 to 348 of R100-1). Deletion analysis of F traN suggested that this central portion might be responsible for the receptor specificity displayed by TraN. TraN was not responsible for TraT-dependent surface exclusion. Thus, TraN, and not the F pilus, appears to interact with OmpA and LPS moieties during conjugation, resulting in mating pair stabilization, the first step in efficient mobilization of DNA.     

Molecular cloning, sequence and regulation of expression of the recA gene of the phototrophic bacterium Rhodobacter sphaeroides

The recA gene of Rhodobacter sphaeroides 2.4.1 has been isolated by complementation of a UV-sensitive RecA^– mutant of Pseudomonas aeruginosa. Its complete nucleotide sequence consists of 1032 bp, encoding a polypeptide of 343 amino acids. The deduced amino acid sequence displayed highest identity to the RecA proteins from Rhizobium mehloti, Rhizobium phaseoli, and Agrobacterium tumefaciens. An Escherichia coli-like SOS consensus region, which functions as a binding site for the LexA repressor molecule was not present in the 215 by upstream region of the R. sphaeroides recA gene. Nevertheless, by using a recA-lacZ fusion, we have shown that expression of the recA gene of R. sphaeroides is inducible by DNA damage. A recA-defective strain of R. sphaeroides was obtained by replacement of the active recA gene by a gene copy inactived in vitro. The resulting recA mutant exhibited increased sensitivity to UV irradiation, and was impaired in its ability to perform homologous recombination as well as to trigger DNA damage-mediated expression. This is the first recA gene from a Gram-negative bacterium that lacks an E. coli-like SOS box but whose expression has been shown to be DNA damage-inducible and auto-regulated.     

Surface exclusion genes traS and traT of the F sex factor of Escherichia coli K-12. Determination of the nucleotide sequence and promoter and terminator activities

The DNA encoding the surface exclusion genes traS and traT of the F sex factor of Escherichia coli K-12 has been sequenced and the biological activity of the various terminators and promoters determined. The data show that traS encodes a 16,861 Mr protein with no apparent signal sequence, as expected for its cytoplasmic membrane location. The protein is extremely hydrophobic. traS has its own promoter and a weak terminator region follows the gene. After the traS termination loop there is a small intergenic region before the traT promoter. The traT gene encodes a 25,932 Mr precursor for the 23,709 Mr mature protein. The amino-terminal signal peptide is 21 amino acid residues, consistent with it being an outer membrane lipoprotein. A very strong termination loop follows the gene and adjacent to this a further loop can be predicted from the sequence. These secondary structures would be expected to enhance the stability of the mRNA in the presence of 3' specific ribonucleases accounting for the apparent long half-life of the messenger. The amino acid sequence of the mature product of traT of F differs from that of R100 by only a single amino acid substitution (Gly for Ala at position 119), whereas that of pED208 (Folac) differs at 40 positions. traT lies in a region of heteroduplex homology between F and R100, and the nucleotide sequence confirms this and demonstrates that this homology breaks down immediately preceding and following the coding region. Sequence analysis shows that this is also so for pED208. Thus the entire traS of F, R100 and pED208 are very different at the DNA level. An open reading frame, preceded by a typical promoter sequence and a weak and poorly located Shine-Dalgarno sequence, follows traT and corresponds to the start of traD. Alone, this promoter appears to be inactive.     

A replication region of the IncHI plasmid, R27, is highly homologous with the RepFIA replicon of F

A region of the IncHI plasmid R27 has been found to share very close nucleotide sequence homology with the RepFIA replicon of F. This region has been located on a 1.6 kb segment of R27 plasmid DNA, and corresponds to ori-2 and the E gene of F. The incC repeat sequence region shows reduced homology, with the F repeats being an imperfect subset of a larger repeated sequence found in R27. The E gene homologue of R27 is able to initiate replication from the F ori-2 sequence and to repress the E gene promoter of F. The results are consistent with the observed incompatibility behaviour of R27, and have a bearing on the specificity of interaction of E protein with its DNA-binding sites.     

Genetic and structural characterization of the avirulence gene avrBs3 from Xanthomonas campestris pv. vesicatoria

Summary The avirulence gene avrBs3 from Xanthomonas campestris pv. vesicatoria was cloned and found to be localized on a self-transmissable plasmid. Genetic analysis of an avrBs3 insertion mutation revealed that avrBs3 constitutes a single locus, specifying the resistant phenotype on pepper plants. Southern blot experiments showed that no DNA sequences homologous to avrBs3 were present in other races of X. c. pv. vesicatoria, which are unable to induce a hypersensitive reaction on ECW-30R. However, the DNA of several different pathovars of X. campestris hybridized to the avrBs3 probe. A deletion analysis defined a region of 3.6–3.7 kb essential for avrBs3 activity. The nucleotide sequence of this region was determined. A 3561 nucleotide open reading frame (ORF1), encoding a 125000 dalton protein, was found in the 3.7 kb region that was sufficient for avrBs3 activity. A second long ORF (2351 nucleotides) was identified on the other strand. A remarkable feature of both ORFs is the presence of 17 direct repeats of 102 bp which share 91%–100% homology with each other.     

Genetic and physical mapping of xa13, a recessive bacterial blight resistance gene in rice

 The recessive gene, xa13, confers resistance to Philippine race 6 (PXO99) of the bacterial blight pathogen Xanthomonas oryzae pv oryzae. Fine genetic mapping and physical mapping were conducted as initial steps in an effort to isolate the gene. Using nine selected DNA markers and two F₂ populations of 132 and 230 plants, xa13 was fine-mapped to a genomic region <4 cM on the long arm of rice chromosome 8, flanked by two RFLP markers, RG136 and R2027. Four DNA markers, RG136, R2027, S14003, and G1149, in the target region were used to identify bacterial artificial chromosome (BAC) clones potentially harboring the xa13 locus from a rice BAC library. A total of 11 BACs were identified, forming four separate contigs including a single-clone contig, 29I3, associated with the RG136 STS marker, the S14003 contig consisting of four clones (44F8, 41O2, 12A16, and 12F20), the G1149 contig with two clones, 23D11 and 21H18, and the R2027 contig consisting of four overlapping clones, 42C23, 30B5, 6B7 and 21H14. Genetic mapping indicated that the xa13 locus was contained in the R2027 contig. Chromosomal walking on the R2027 contig resulted in two more clones, 33C7 and 14L3. DNA fingerprinting showed that the six clones of the R2027 contig were overlapping. Clone 44F8 hybridized with a single fragment from the clone 14L3, integrating the R2027 and S14003 contigs into a single contig consisting of ten BAC clones with a total size of approximately 330 kb. The physical presence of the xa13 locus in the contig was determined by mapping the ends of the BAC inserts generated by TAIL-PCR. In an F₂ population of 230 plants, the BAC-end markers 42C23R and 6B7F flanked the xa13 locus. The probes 21H14F and 21H14R derived from BAC clone 21H14 were found to flank xa13 at a distance of 0.5 cM on either side, using a second F₂ population of 132 plants. Thus, genetic mapping indicated that the contig and the 96-kb clone, 21H14, contained the xa13 locus. Received: 15 August 1998 / Accepted: 29 September 1998     

Fine mapping of the tomato<Emphasis Type="Italic"> I-3</Emphasis> gene for fusarium wilt resistance and elimination of a co-segregating resistance gene analogue as a candidate for<Emphasis Type="Italic"> I-3</Emphasis>

The I-3 gene from the wild tomato species Lycopersicon pennellii confers resistance to race 3 of the devastating vascular wilt pathogen Fusarium oxysporum f. sp. lycopersici. As an initial step in a positional cloning strategy for the isolation of I-3, we converted restriction fragment length polymorphism and conserved orthologue set markers, known genes and a resistance gene analogue (RGA) mapping to the I-3 region into PCR-based sequence characterised amplified region (SCAR) and cleaved amplified polymorphic sequence (CAPS) markers. Additional PCR-based markers in the I-3 region were generated using the randomly amplified DNA fingerprinting (RAF) technique. SCAR, CAPS and RAF markers were used for high-resolution mapping around the I-3 locus. The I-3 gene was localised to a 0.3-cM region containing a RAF marker, eO6, and an RGA, RGA332. RGA332 was cloned and found to correspond to a putative pseudogene with at least two loss-of-function mutations. The predicted pseudogene belongs to the Toll interleukin-1 receptor-nucleotide-binding site-leucine-rich-repeat sub-class of plant disease resistance genes. Despite the presence of two RGA332 homologues in L. esculentum, DNA gel blot and PCR analysis suggests that no other homologues are present in lines carrying I-3 that could be alternative candidates for the gene.Communicated by R. Hagemann     

Characterisation of an in vivo system for nicking at the origin of conjugal DNA transfer of the sex factor F

Transfer of the F plasmid between conjugating Escherichia coli cells has been assumed to require endonucleolytic cleavage at a specific site (oriT) on a specific strand of the F molecule. Using a lambda transducing phage which contains oriT we have detected this nicking process in vivo. Nicking of DNA occurred in the strand that included the “transferred” F strand and at a location within the transducing segment consistent with all previous genetic and restriction enzyme cleavage data on the position of oriT in F. Genetic study of the nicking process using Flac tra^? point and deletion mutants, and also λtra phages which carried various parts of the transfer region, indicated that the products of two transfer operon genes, traY and the previously unidentified gene traZ, were directly involved in nicking at oriT. The product of traJ was also required for nicking, but the possibility that this was solely due to the regulatory function of the traJ product could not be excluded. The plasmid specificities of oriT, traY and traZ between F and the related F-like plasmids R1-19 and R100-1 were investigated using the λoriT nicking system, and shown to be consistent with those determined in genetic complementation tests. The differences in specificity observed imply that the oriT sequence of F differs from those of R1-19 and R100-1.The products of the traM and traI genes are known to be required for the initiation of DNA transfer; their possible roles in modulating the activity of the traY Z endonuclease are discussed.     

An insertion mutation of the bovine F11 gene is responsible for factor XI deficiency in Japanese black cattle

Factor XI deficiency in Japanese black cattle is an hereditary mild bleeding disorder with an autosomal recessive mode of inheritance. To characterize the molecular lesion causing factor XI deficiency in cattle, we isolated an entire coding region of the bovine F11 gene, which comprises 15 exons and 14 introns, and determined its nucleotide sequences. Comparison of the nucleotide sequences of the F11 gene between affected and unaffected animals revealed an insertion of 15 nucleotides in exon 9 of the affected animals. The insertion results in a substitution of one amino acid with six amino acids in a highly conserved amino acid sequence in the fourth apple domain of factor XI protein. Genotyping of the F11 gene in 109 Japanese black cattle revealed that the insertion clearly corresponded to the factor XI activities of the animals. We therefore concluded that the insertion of 15 nucleotides in the F11 gene is the causative mutation for factor XI deficiency in Japanese black cattle. Genotyping of the F11gene by detecting the insertion will be an effective DNA-based diagnostic system to prevent incidence of the disease.     

Characterization of the gene products produced in minicells by pSM1, a derivative of R100

Summary At least ten polypeptides larger than 6 kilodaltons (K) are produced in minicells from the miniplasmid pSM1 in vivo. pSM1 (5804 bp) is a small derivative of the drug resistance plasmid R100 (ca. 90 kb) and carries the R100 essential replication region as well as some non-essential functions. Cloned restriction fragments of pSM1 and plasmids with deletions within pSM1 sequences were used to assign eight of the ten oberserved polypeptides to specific coding regions of pSM1. Two of these polypeptides were identified as RepA1 and RepA2, proteins encoded by the essential replication region of pSM1/R100. The nucleotide sequence consisting of 885 bp outside the essential replication region is presented here. This sequence contains an open reading frame,orf4, for a protein 22.9 K in size, and one of the pSM1-encoded polypeptides was identified as theorf4 gene product. Five additional polypeptides were shown to be the products of other open reading frames mapping outside the essential replication region. Specific functions have been assigned to four of these polypeptides and tentatively to the fifth.     

Nucleotide sequence of the promoter-distal region of the tra operon of plasmid R100, including traI (DNA helicase I) and traD genes

The nucleotide sequence of the promoter-distal region of the tra operon of R100 was determined. There are five open reading frames in the region between traT and finO, and their protein products were identified. Nucleotide sequences of plasmid F corresponding to the junction regions among the open reading frames seen in R100 were also determined. Comparison of these nucleotide sequences revealed strong homology in the regions containing traD, traI and an open reading frame (named orfD). The TraD protein (83,899 Da) contains three hydrophobic regions, of which two are located near the amino-terminal region. This protein also contains a possible ATP-binding consensus sequence at the amino-terminal region and a characteristic repeated peptide sequence (Gln-Gln-Pro)10 at the carboxy-terminal region. The TraI protein (191,679 Da) contains the sequence motif conserved in an ATP-dependent DNA helicase superfamily in its carboxy-terminal region. The protein product of orfD, which is probably a new tra gene (named traX), contains 65% hydrophobic amino acids, especially rich in alanine and leucine. There exist non-homologous regions between R100 and F that could be represented as four I-D (insertion or deletion) loops in heteroduplex molecules. Assignment of each loop to the strand of R100 or F was , however, found to be the reverse from that previously assumed. The three I-D loops that were located between traT and traD, between traD and traI, and between traI and finO had no terminal inverted repeat sequences nor had they any homology with known insertion sequences, while the fourth was IS3, located within the finO gene of F. The sequences in the I-D loops, except IS3, may also code for proteins that are, however, likely to be nonessential for transfer of plasmids.     

Sequence and conservation of genes at the distal end of the transfer region on plasmids F and R6-5

The nucleotide sequence of the region downstream of transfer gene traI, including fertility inhibition gene finO, on the conjugative plasmids F and R6-5, has been determined. Analysis of the F sequence revealed two open reading frames (ORF's), ORF248 and ORF186; ORF186 (finO) is interrupted by the insertion of IS3. The R6-5 sequence also contained ORF248 and an intact ORF186, although an additional ORF (ORF286) was located between the two genes. ORF248, which we have designated traX, and ORF186 (finO) are highly conserved on both plasmids. The organisation of these genes indicates that traI and traX on F, and traI, traX and ORF286 on R6-5 are co-transcribed from their respective promoters upstream of traI. Sequences homologous to traX were detected on a range of conjugative F-like plasmids, whereas sequences homologous to ORF286 were only found on plasmids R6-5, R100 and R1. The conservation of traX sequences suggests a functional importance for that gene and/or its product.     

IncD, a genetic locus in F responsible for incompatibility with several plasmids of the IncFI group

Summary Cloning of mini-F DNA segments has led to the identification and mapping of a locus, incD, involved in incompatibility reactions with many IncFI plasmids. The cloned incD locus expressed incompatibility with F, R386, and six other IncFI plasmids but not with ColV3-K30 or pHH507 which lack sequence homology with the incD region. A sequence of 360 bp (48.66–49.02 FKB) was found to be sufficient for expression of incD incompatibility. Multicopy vectors containing incD are compatible with each other, but can be displaced by mini-F plasmids deleted for incD. These results indicate that incD-mediated incompatibility reactions require the presence of replication genes to which incD is normally linked. The degree of incompatibility exercised by incD is moderate compared with that of other inc loci in F, suggesting that incD is involved in an aspect of plasmid maintennce, such as partition, different from the functions of the other inc loci.     

Development of primer sets for PCR amplification of the PgiC gene in ferns

Polymerase chain reaction (PCR)-based nuclear DNA markers were developed for fern species. We first determined the partial nucleotide sequence of cDNA of the pgiC gene encoding cytosolic phosphoglucose isomerase from Dryopteris caudipinna, and then PCR primers for exon-primed, intron-crossing (EPIC) amplifications were designed. The EPIC primers are universally applicable to the most derived indusiate fern families such as Dryopteridaceae, Thelypteridaceae, and Woodsiaceae. The PCR products of primers 14F/16R containing two introns are moderate in size (534 bp–ca.1000 bp) and are possibly of value in phylogenetic reconstruction at specific and generic levels. Codominant nuclear DNA markers applicable to the estimation of mating systems and other population genetic studies were also developed by a combination of single-strand conformation polymorphism (SSCP) and EPIC amplification using primers 14F/15R and 15F/16R. In order to provide a case study using these markers, allelic variation of PCR products using 15F/16R was examined in populations of Arachniodes standishii (Dryopteridaceae). Received: July 4, 2001 / Accepted: September 12, 2001     

The complete mitochondrial genome of Rhynchocypris oxycephalus (Teleostei: Cyprinidae) and its phylogenetic implications

Rhynchocypris oxycephalus (Teleostei: Cyprinidae) is a typical small cold water fish, which is distributed widely and mainly inhabits in East Asia. Here, we sequenced and determined the complete mitochondrial genome of R. oxycephalus and studied its phylogenetic implication. R. oxycephalus mitogenome is 16,609 bp in length (GenBank accession no.: MH885043), and it contains 13 protein‐coding genes (PCGs), two rRNA genes, 22 tRNA genes, and two noncoding regions (the control region and the putative origin of light‐strand replication). 12 PCGs started with ATG, while COI used GTG as the start codon. The secondary structure of tRNA‐Ser (AGN) lacks the dihydrouracil (DHU) arm. The control region is 943bp in length, with a termination‐associated sequence, six conserved sequence blocks (CSB‐1, CSB‐2, CSB‐3, CSB‐D, CSB‐E, CSB‐F), and a repetitive sequence. Phylogenetic analysis was performed with maximum likelihood and Bayesian methods based on the concatenated nucleotide sequence of 13 PCGs and the complete sequence without control region, and the result revealed that the relationship between R. oxycephalus and R. percnurus is closest, while the relationship with R. kumgangensis is farthest. The genus Rhynchocypris is revealed as a polyphyletic group, and R. kumgangensis had distant relationship with other Rhynchocypris species. In addition, COI and ND2 genes are considered as the fittest DNA barcoding gene in genus Rhynchocypris. This work provides additional molecular information for studying R. oxycephalus conservation genetics and evolutionary relationships.     

Conserved structure of genes encoding components of botulinum neurotoxin complex M and the sequence of the gene coding for the nontoxic component in nonproteolyticClostridium botulinum type F

For investigation of the genes of proteins associated in vivo with botulinum neurotoxin (BoNT), polymerase chain reaction (PCR) experiments were carried out with oligonucleotide primers designed to regions of the nontoxic-nonhemagglutinin (NTNH) gene ofClostridium botulinum type C. The primers were used to amplify a DNA fragment from genomic DNA ofC. botulinum types A, B, E, F, G and toxigenic strains ofClostridium barati andClostridium butyricum. The amplified product from all of these strains hybridized with an internal oligonucleotide probe, whereas all nontoxigenic clostridia tested gave no PCR product and showed no reaction with the probe. TheNTNH gene was shown to be located upstream of the gene encoding BoNT, thereby revealing a conserved structure for genes encoding the proteins of the M complex of the progenitor botulinum toxin in these organisms. The sequence of theNTNH gene of nonproteolyticC. botulinum type F was determined by PCR amplification and sequencing of overlapping cloned fragments. NTNH/F showed 71% and 61% identity with NTNH ofC. botulinum type E and type C respectively.