Rearrangements of nitrogen fixation (nif) genes in the heterocystous cyanobacteria

In the vegetative cells of heterocystous cyanobacteria, such asAnabaena, two Operons harbouring the nitrogen fixaton (nif) genes contain two separate intervening DNA elements resulting in the dispersion of genes and impaired gene expression. A 11 kb element disrupts thenifD gene in thenifH, D-K operon. It contains a 11 bp sequence (GGATTACTCCG) directly repeated at its ends and harbours a gene,xisA, which encodes a site-specific recombinase. A large 55 kb element interrupts thefdxN gene in thenifB fdxN-nifS-nifU operon. It contains two 5 bp direct repeats (TATTC) at its ends and accommodates at least one gene,xisF, which encodes another site-specific recombinase. During heterocyst differentiation both the discontinuities are precisely excised by two distinct site-specific recombination events. One of them is brought about by the XisA protein between the 11 bp direct repeats. The second one is caused by the XisF protein and occurs between the 5 bp direct repeats. As a consequence the 11kb and 55 kb elements are removed from the chromosome as circles and functionalnif Operons are created. Nitrogenase proteins are then expressed from the rearranged genes in heterocysts and aerobic nitrogen fixation ensues. How these elements intruded thenif genes and how and why are they maintained in heterocystous cyanobacteria are exciting puzzles engaging considerable research effort currently. The unique developmental regulation of these gene rearrangements in heterocystous cyanobacteria is discussed.     

Next generation synthetic vectors for transformation of the plastid genome of higher plants

Plastid transformation vectors are E. coli plasmids carrying a plastid marker gene for selection, adjacent cloning sites and flanking plastid DNA to target insertions in the plastid genome by homologous recombination. We report here on a family of next generation plastid vectors carrying synthetic DNA vector arms targeting insertions in the rbcL-accD intergenic region of the tobacco (Nicotiana tabacum) plastid genome. The pSS22 plasmid carries only synthetic vector arms from which the undesirable restriction sites have been removed by point mutations. The pSS24 vector carries a c-Myc tagged spectinomycin resistance (aadA) marker gene whereas in vector pSS30 aadA is flanked with loxP sequences for post-transformation marker excision. The synthetic vectors will enable direct manipulation of passenger genes in the transformation vector targeting insertions in the rbcL-accD intergenic region that contains many commonly used restriction sites. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

A PCR survey of <Emphasis Type="Italic">Hox</Emphasis> genes in the myzostomid <Emphasis Type="Italic">Myzostoma cirriferum</Emphasis>

Using degenerate primers, we were able to identify seven Hox genes for the myzostomid Myzostoma cirriferum. The recovered fragments belong to anterior class (Mci_lab, Mci_pb), central class (Mci_Dfd, Mci_Lox5, Mci_Antp, Mci_Lox4), and posterior class (Mci_Post2) paralog groups. Orthology assignment was verified by phylogenetic analyses and presence of diagnostic regions in the homeodomain as well as flanking regions. The presence of Lox5, Lox4, and Post2 supports the inclusion of Myzostomida within Lophotrochozoa. We found signature residues within flanking regions of Lox5, which are also found in annelids, but not in Platyhelminthes. As such the available Hox genes data of myzostomids support an annelid relationship. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

ParA resolvase catalyzes site-specific excision of DNA from the Arabidopsis genome

The small serine resolvase ParA from bacterial plasmids RK2 and RP4 catalyzes the recombination of two identical 133 bp recombination sites known as MRS. Previously, we reported that ParA is active in the fission yeast Schizosaccharomyces pombe. In this work, the parA recombinase gene was placed under the control of the Arabidopsis OXS3 promoter and introduced into Arabidopsis lines harboring a chromosomally integrated MRS-flanked target. The ParA recombinase excised the MRS-flanked DNA and the excision event was detected in subsequent generations in the absence of ParA, indicating germinal transmission of the excision event. The precise site-specific deletion by the ParA recombination system in planta demonstrates that the ParA recombinase can be used to remove transgenic DNA, such as selectable markers or other introduced transgenes that are no longer desired in the final product.     

Mechanism of Ds1 excision from the genome of maize streak virus

Summary We have previously shown that the maize transposable element Ds1 introduced into maize plants by agroinfection can be excised from the genome of geminivirus maize streak virus (MSV). Excision depended strictly on the presence of an active Ac element in the plants. In this study, the excision products or footprints left in the MSV genome after Ds1 excision were extensively characterized and the effects of flanking sequences on Ds1 excision were analysed. Most types of footprints obtained were comparable to those described for Ds1 excision in the maize genome, and could be explained by the models proposed for excision of plant transposable elements. In two revertants, however, some terminal sequences of the Ds1 element were found to have been left behind at the excision site. The finding of this novel type of Ds1 footprint indicated that gene conversion events occurred during and/or after Ds1 excision from the MSV genome. A partial deletion of one copy of the 8 by duplications flanking the Ds1 element had no effect on the frequency or on the types of footprints of Ds1 excision from the MSV genome. Thus, the duplicated 8 by sequences flanking the transposable element are not involved in Ds1 excision. These results, as well as a statistical analysis of the modifications of the bases flanking the Ds1 element after excision, are discussed in terms of excision models.     

Structure Analysis of Two <Emphasis Type="Italic">Toxoplasma gondii</Emphasis> and <Emphasis Type="BoldItalic">Neospora caninum</Emphasis> Satellite DNA Families and Evolution of Their Common Monomeric Sequence

A family of repetitive DNA elements of approximately 350 bp—Sat350—that are members of Toxoplasma gondii satellite DNA was further analyzed. Sequence analysis identified at least three distinct repeat types within this family, called types A, B, and C. B repeats were divided into the subtypes B1 and B2. A search for internal repetitions within this family permitted the identification of conserved regions and the design of PCR primers that amplify almost all these repetitive elements. These primers amplified the expected 350-bp repeats and a novel 680-bp repetitive element (Sat680) related to this family. Two additional tandemly repeated high-order structures corresponding to this satellite DNA family were found by searching the Toxoplasma genome database with these sequences. These studies were confirmed by sequence analysis and identified: (1) an arrangement of AB1CB2 350-bp repeats and (2) an arrangement of two 350-bp-like repeats, resulting in a 680-bp monomer. Sequence comparison and phylogenetic analysis indicated that both high-order structures may have originated from the same ancestral 350-bp repeat. PCR amplification, sequence analysis and Southern blot showed that similar high-order structures were also found in the Toxoplasma-sister taxon Neospora caninum. The Toxoplasma genome database ( ) permitted the assembly of a contig harboring Sat350 elements at one end and a long nonrepetitive DNA sequence flanking this satellite DNA. The region bordering the Sat350 repeats contained two differentially expressed sequence-related regions and interstitial telomeric sequences.     

Site-specific integration and excision of pMEA100 in Nocardia mediterranei

Summary Nocardia mediterranei strain LBG A3136 contains the 23.7 kb element pMEA100 in a chromosomally integrated form as well as in the free state (Moretti et al. 1985). The integrated form of this element can be excised precisely from the Nocardia chromosome without any accompanying rearrangements in flanking chromosomal DNA. After transfer into plasmid-free mutant strains, pMEA100 reintegrates site specifically into its original chromosomal locus. The exact mapping of the pMEA100 integration site was accomplished by restriction analysis and DNA sequencing. The attachment site of pMEA100, the junctions of its integrated form and plasmid-free chromosomal DNA of N. mediterranei contain an identical 47 bp long sequence which is probably required for site-specific recombination connected with integration and excision of pMEA100. Only one such sequence was found in the chromosome of pMEA100-free N. mediterranei derivatives as suggested by the single integration locus.     

Analysis of the cis-acting DNA elements required for piggyBac transposable element excision

The terminal DNA sequence requirements for piggyBac transposable element excision were explored using a plasmid-based assay in transfected, cultured insect cells. A donor plasmid containing duplicate 3′piggyBac terminal inverted repeats was constructed that allowed individual nucleotides or groups of nucleotides within one of the 3′ repeats to be mutated. The relative extent of excision using the mutated end versus the wild-type end was then assayed. Removal of even one of the terminal 3′ G nucleotides from the piggyBac inverted repeat, or removal of the dinucleotide AA from the flanking TTAA target site prevents excision of piggyBac at the mutated terminus. Incorporation of an asymmetric TTAC target site at the 3′ end does not prevent excision from the mutated end. Thus, both piggyBac DNA and flanking host DNA appear to play crucial roles in the excision process. Received: 9 July 1996 / Accepted: 6 May 1997     

Reductive genome evolution in chemoautotrophic intracellular symbionts of deep-sea <Emphasis Type="Italic">Calyptogena</Emphasis> clams

To understand reductive genome evolution (RGE), we comparatively analyzed the recently reported small genomes of two chemoautotrophic, intracellular symbionts of deep-sea clams, Calyptogena okutanii and C. magnifica. Both genomes lack most genes for DNA recombination and repair such as recA and mutY. Their genome architectures were highly conserved except one inversion. Many deletions from small (<100 bp) to large (1–11 kbp) sizes were detected and the deletion numbers decreased exponentially with size. Densities of deletions and short-repeats, as well as A+T content were higher in non-coding regions than in coding regions. Because Calyptogena symbiont genomes lack recA, we propose that deletions and the single inversion occurred by RecA-independent recombination (RIR) at short-repeats with simultaneous consumption of repeats, and that short-repeats were regenerated by accelerated mutations with enhanced A+T bias due to the absence of mutY. We further propose that extant Calyptogena symbiont genomes are in an actively reducing stage of RGE consisting of small and large deletions, and the deletions are caused by short-repeat dependent RIR along with regeneration of short-repeats. In future, the RGE rate will slowdown when the gene repertoires approach the minimum gene set necessary for intracellular symbiotic life. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. H. Kuwahara and Y. Takaki equally contributed to this work.     

High frequency excision of Ty elements during transformation of yeast.

Yeast (Saccharomyces cerevisiae) transposons (Ty elements) are excised from up to 20% of supercoiled plasmids during transformation of yeast cells. The excision occurs by homologous recombination across the direct terminal repeats (deltas) of the Ty element, leaving behind a single delta in the transforming plasmid. Only the initial transforming plasmid is susceptible to excision, and no high frequency excision is observed in plasmids that have become established in transformed cells or in plasmids that are resident in cells undergoing transformation. High frequency excision from plasmids during yeast transformation is not specific for Ty elements and can be observed with other segments of plasmid DNA bounded by direct repeats. The frequency of Ty excision from supercoiled plasmids is greatly reduced when the host yeast cells contain the rad52 mutation, a defect in double-strand DNA repair. When linear or ligated-linear plasmid DNAs containing a Ty element are used for transformation, few or no excision plasmids are found among the transformant colonies. These results suggest that when a yeast cell is transformed with a supercoiled plasmid, the plasmid DNA is highly susceptible to homologous recombination for a short period of time.     

Identification and mapping of regions that confer plasmid functions and of sites for excisive recombination of plasmid pMMC7105

Summary Strain PP808 of Pseudomonas syringae pv. phaseolicola contains pEXC8080 (34.6 kb), the smallest of several plasmids that originated by partial excision of the cryptic plasmid, pMMC7105 (150 kb), from the host chromosome. This excision plasmid is derived entirely of sequences from pMMC7105 and contains a 24 kb region referred to as common DNA, which is present in each of the other excision plasmids. A six enzyme restriction endonuclease map was constructed of pEXC8080. The replication region was mapped by identifying small restriction fragments that conferred replication properties to pMB1 plasmids that otherwise fail to replicate in Pseudomonas. This region is located within the common DNA and is 0.8–3.8 kb in size. Sequences from pEXC8080 failed to stabilize pMB1 derivatives in Pseudomonas in the absence of antibiotic selection, but stability functions were mapped to a region of pMMC7105 that presumably remains integrated in the chromosome of strain PP808. An incompatibility region was mapped to a 7.3 kb region on pEXC8080 that is closely linked to, but not included within, the replication region. The recombination site was mapped to a 1.2 kb region of the fusion fragment that was formed upon excision of pEXC8080. RS-I, a repetitive sequence, found on pMMC7105 was present in the fusion fragment at the site of recombination. RS-I was also mapped to BamHI fragments that recombined upon excision of pEXC8080 and suggest that it provides sites for homologous recombination.     

Analysis of the cis-acting DNA elements required for piggyBac transposable element excision

The terminal DNA sequence requirements for piggyBac transposable element excision were explored using a plasmid-based assay in transfected, cultured insect cells. A donor plasmid containing duplicate 3′piggyBac terminal inverted repeats was constructed that allowed individual nucleotides or groups of nucleotides within one of the 3′ repeats to be mutated. The relative extent of excision using the mutated end versus the wild-type end was then assayed. Removal of even one of the terminal 3′ G nucleotides from the piggyBac inverted repeat, or removal of the dinucleotide AA from the flanking TTAA target site prevents excision of piggyBac at the mutated terminus. Incorporation of an asymmetric TTAC target site at the 3′ end does not prevent excision from the mutated end. Thus, both piggyBac DNA and flanking host DNA appear to play crucial roles in the excision process.     

Creation of<Emphasis Type="Italic"> EcR</Emphasis> isoform-specific mutations in<Emphasis Type="Italic"> Drosophila melanogaster</Emphasis> via local P element transposition,imprecise P element excision,and male recombination

Collections of single P transposable-element insertion strains that currently inactivate more than 25% of essential Drosophila genes have proven to be a valuable tool for genome research in Drosophila melanogaster. For genes unrepresented in these collections, strategies including local P element transposition and transposase-induced imprecise excision can be used to inactivate or delete the gene of interest. Here we report our use of local P element transposition followed by imprecise P element excision and transposase-induced male recombination to generate two deficiencies specific for the EcR-A isoform of the ecdysone receptor (EcR) gene, and four larger deficiencies likely to affect multiple EcR functions. We also report here the determination of sequences flanking six EcR-B deficiencies generated in a previous imprecise excision screen. EcR-A encodes one of a family of three related nuclear receptor proteins that, together with the heterodimer partner USP, mediate ecdysone signaling during Drosophila development. Our results delineate sequences required in vivo for EcR-A function, as well as identifying EcR-A intron 1 sequences that are not essential for EcR function.Communicated by G. Reuter     

Extra sequences found at P element excision sites in Drosophila melanogaster.

Summary. We have previously established a transgenic Drosophila line with a highly transposable P element insertion. Using this strain we analyzed transposition and excision of the P element at the molecular level. We examined sequences flanking the new insertion sites and those of the remnants after excision. Our results on mobilization of the P element demonstrate that target-site duplication at the original insertion site does not play a role in forward excision and transposition. After P element excision an 8 by target-site duplication and part of the 31 by terminal inverted repeat (5–18 bp) remained in all the strains examined. Moreover, in 11 out of 28 strains, extra sequences were found between the two remaining inverted repeats. The double-strand gap repair model does not explain the origin of these extra sequences. The mechanism creating them may be similar to the hairpin model proposed for the transposon Tam in Antirrhinum majus.     

Recessive allelic variations of three microsatellite sites within the<Emphasis Type="Italic">O2</Emphasis> gene in maize

Recessive allelic variations were investigated at 3 microsatellite (SSR) sites within theO2 gene by using 14 inbredo2 lines and a wild-type line in maize. Among the 15 lines, allelic variations were observed at umc1066, phi057, and phi112 sites. Two alleles were found at the umc1066 site—a recessive allele with 2 perfect GCCAGA repeats and a dominant allele with 3 perfect repeats. Three alleles were found at the phi057 site—2 recessive alleles with 3 and 5 perfect GCC repeats, respectively, and another with 4 perfect repeats consistent with a dominant allele. At least 4 alleles exist at the phi112 site—among which 1 recessive allele has a 1-bp deletion, another has a 15-bp deletion, and other has no PCR products compared to the dominant allele; all the alleles have unchanged AG repeats. The phi057 site in exon 6 was identified to be a hypervariable region in the coding sequence of the02 gene, in addition to the 2 hypervariable regions in exon 1 previously reported. The primary mechanisms underlying the variations in repeat numbers and regions flanking the SSR within theO2 gene appear to be unequal crossing over and replication slippage. Furthermore, base substitution of SSR motif can create heteroalleles and modify the repeat number of SSR. The lysine content of kernel in theO2 ando2 lines correlates to a considerable extent with nucleotide variations at the umc1066, phi057, and phi112 sites. Our study suggests that it is best to use the 3 markers together in molecular marker-assisted selection for high-lysine maize materials.     

Evidence for Recombination in the Microcystin Synthetase (<Emphasis Type="Italic">mcy</Emphasis>) Genes ofToxic Cyanobacteria <Emphasis Type="Italic">Microcystis</Emphasis><Emphasis Type="Bold">spp</Emphasis>

Recombination has been suggested to be an important factor for the genetic variation of bacterial genes, but few studies have dealt with intragenic recombination between the same or closely related species of cyanobacteria. Here we provide strong evidence for recombination in the microcystin synthetase (mcy) gene cluster of the toxic cyanobacteria Microcystis spp. This gene cluster contains 10 genes (mcyA to J) that encode a mixed polyketide synthase (PKS)/nonribosomal peptide synthetase (NRPS) complex. mcy gene sequences were determined for four selected regions (within mcyA, D, G, and J) within the mcy gene cluster from 1 Canadian and 10 Asian toxic Microcystis and compared with previously published mcy sequences. Split decomposition analysis indicated a reticulate phylogeny of mcyA, and several potential recombination tracts of mcyA were identified by the RDP analysis and a runs test implemented in GENECONV. In contrast, no recombination was detected in the mcyD, G, and J sequences. However, discrepancies among the four mcy gene genealogies were evident from the results of independent split decomposition analyses, which were further supported by incongruence length difference (ILD) tests. Taken together, these findings suggest that both intragenic and intergenic recombination within the mcy gene cluster contributes to the genetic diversity of the mcy genes of Microcystis spp.This article contains online supplementary material.     

Transposon Tn21 encodes a RecA-independent site-specific integration system

Summary The IncW plasmid R388 and the DNA region of Tn21 containing the Sm^r and the Su^r genes are capable of RecA-independent recombination. This recombination occurs at a relatively high frequency (up to 10^-4 recombinants per recipient molecule) and results in integration of the two plasmids. No detectable repeats are formed in the process. The crossover points have been confined to a 0.4-kb homologous segment in both plasmids which contains a 59-bp DNA sequence presumably involved in the acquisition of new genes by Tn21 and its relatives (Cameron et al. 1986). It is likely that the recombination occurs precisely at this point. At least one trans-acting function (an integrase) is required for the site-specific recombination. It has been localized to a 1456-bp BstEII-BamHI fragment of Tn21 and can efficiently complement the integration of plasmids containing the integration site.     

Excision of the piggyBac transposable element in vitro is a precise event that is enhanced by the expression of its encoded transposase

The piggyBac Lepidopteran transposable element moves from the cellular genome into infecting baculovirus genomes during passage of the virus in cultured TN-368 cells. We have constructed genetically tagged piggyBac elements that permit analysis of excision when transiently introduced on plasmids into the piggyBac-deficient Spodoptera frugiperda IPLB-SF21AE cell line. Precise excision of the element from these plasmids occurs at a higher frequency in the presence of a helper plasmid that presumably supplies the piggyBac transposase. The results suggest that the piggyBac transposon encodes a protein that functions to facilitate not only insertion, but precise excision as well. This is the first demonstration of piggyBac mobility from plasmid sources in uninfected Lepidopteran cells.     

Analysis of DNA repeats in bacterial plasmids reveals the potential for recurrent instability events

Structural instability has been frequently observed in natural plasmids and vectors used for protein expression or DNA vaccine development. However, there is a lack of information concerning hotspot mapping, namely, DNA repeats or sequences identical to the host genome. This led us to evaluate the abundance and distribution of direct, inverted, and tandem repeats with high recombination potential in 36 natural plasmids from ten bacterial genera, as well as in several widely used bacterial and mammalian expression vectors. In natural plasmids, we observed an overrepresentation of close direct repeats in comparison to inverted ones and a preferential location of repeats with high recombination potential in intergenic regions, suggesting a highly plastic and dynamic behavior. In plasmid vectors, we found a high density of repeats within eukaryotic promoters and non-coding sequences. As a result of this in silico analysis, we detected a spontaneous recombination between two 21-bp direct repeats present in the human cytomegalovirus early enhancer/promoter (huCMV EEP) of the pCIneo plasmid. This finding is of particular importance, as the huCMV EEP is one of the most frequently used regulatory elements in plasmid vectors. Because pDNA integration into host gDNA can have adverse consequences in terms of plasmid processing and host safety, we also mapped several regions with high probability to mediate integration into the Escherichia coli or human genomes. Like repeated regions, some of these were located in non-coding regions of the plasmids, thus being preferential targets to be removed.