Targeted inactivation of the tobacco plastome origins of replication A and B

According to the Kolodner and Tewari model [Kolodner, R.D. and Tewari, K.K. (1975) Nature, 256, 708.], plastid DNA replication involves displacement-loop and rolling-circle modes of replication, which are initiated on a pair of origins of replication (ori). In accordance with the model, such a pair of oris -oriA and oriB- was described in Nicotiana tabacum [Kunnimalaiyaan, M. and Nielsen B.L. (1997b) Nucl. Acids Res. 25, 3681.]. However, as reported previously, both copies of oriA can be deleted without abolishing replication. Deletion of both oriBs was not found [Mühlbauer, S.K. et al. (2002) Plant J. 32, 175.]. Here we describe new ori inactivation lines, in which one oriB is deleted and the other copy is strongly mutated. In addition, lines oriA and oriB were deleted from the same inverted repeat. In contrast to the expectations of the model, neither oriA nor oriB is essential. Some of the deletions led to reduced growth of plants and reduced plastid DNA copy number in later stages of leaf development. The gross structure of plastid DNA was unchanged; however, the location of the ends of branched plastid DNA complexes was different in the inactivation mutants. Taken together, the results indicate that there are additional mechanisms of plastid DNA replication and/or additional origins of replication. These mechanisms seem to be different from those found in eubacteria, which, according to the endosymbiont theory, are the progenitors of plastids.     

Generation and maintenance of tandemly repeated extrachromosomal plasmid DNA in Chlamydomonas chloroplasts

Unusual chloroplast transformants of Chlamydomonas reinhardtii that contain 2000 copies of a mutant version of the chloroplast atpB gene, maintained as an extrachromosomal tandem repeat, have recently been described. In this paper studies have been undertaken to (i) address possible mechanisms for generating and maintaining the amplified DNA and (ii) determine whether it is possible to use chloroplast gene amplification to overexpress chloroplast or foreign genes. Data presented here indicate that high copy number transformants harbor characteristic rearrangements in both copies of the chloroplast genome large inverted repeat. These rearrangements appear to be a consequence of, or required for, maintenance of the amplified DNA. In an attempt to mimic the apparently autonomous replication of extrachromosomal DNA in the chloroplast, transformation was carried out with a plasmid that lacked homology with the chloroplast genome or with the same plasmid carrying a putative chloroplast DNA replication origin ( oriA ). Transformants were recovered only with the plasmid containing oriA , and all transformants contained an integrated plasmid copy at oriA , suggesting that establishment or maintenance of the extrachromosomal tandem repeat requires conditions that were not replicated in this experiment. To determine whether other genes could be maintained at high copy number in the chloroplast, plasmids carrying the wild-type atpB gene or the bacterial aadA gene were introduced into a high copy number transformant. Surprisingly, the copy number of the plasmid tandem repeat declined rapidly after the secondary transformation events, even when strong selective pressure for the introduced gene was applied. Thus, chloroplast transformation can either create or destabilize high copy number tandem repeats.     

Proliferation of direct repeats near the Oenothera chloroplast DNA origin of replication

The spacer between the 16S and 23S rRNA genes of the chloroplast DNA has been implicated as an origin of replication in several species of plants. In the evening primrose, Oenothera, this site was found to vary greatly in size, with plastid genomes (plastomes) being readily distinguished. To determine whether plastome "strength" in transmission could be correlated with variation at oriB, the 16S rRNA-trnI spacer was sequenced from five plastomes. The size variation was found to be due to differential amplification (and deletion) of combinations of sequences belonging to seven families of direct repeats. From these comparisons, one short series of direct repeats and one region capable of forming a hairpin structure were identified as candidates for the factor that could be responsible for the differences between strong and weak plastome types. Ample sequence variation allowed phylogenetic inferences to be made about the relationships among the plastomes. Phylogenetic trees also could be constructed for most of the families of direct repeats. The amplifications and deletions of repeats that account for the size variation at oriB are proposed to have occurred through extensive replication slippage at this site.      

Structure of discontinuities in kinetoplast DNA-associated minicircles during S phase in Crithidia fasciculata

Kinetoplast DNA (kDNA) is a novel form of mitochondrial DNA consisting of thousands of interlocked minicircles and 20–30 maxicircles. The minicircles replicate free of the kDNA network but nicks and gaps in the newly synthesized strands remain at the time of reattachment to the kDNA network. We show here that the steady-state population of replicated, network-associated minicircles only becomes repaired to the point of having nicks with a 3′OH and 5′deoxyribonucleoside monophosphate during S phase. These nicks represent the origin/terminus of the strand and occur within the replication origins (oriA and oriB) located 180° apart on the minicircle. Minicircles containing a new L strand have a single nick within either oriA or oriB but not in both origins in the same molecule. The discontinuously synthesized H strand contains single nicks within both oriA and oriB in the same molecule implying that discontinuities between the H-strand Okazaki fragments become repaired except for the fragments initiated within the two origins. Nicks in L and H strands at the origins persist throughout S phase and only become ligated as a prelude to network division. The failure to ligate these nicks until just prior to network division is not due to inappropriate termini for ligation.     

Molecular characterization of the actin-encoding gene and the use of its promoter for a dominant selection system in the methylotrophic yeast Hansenula polymorpha

The actin gene (ACT) from the methylotrophic yeast Hansenula polymorpha was cloned and its structural feature was characterized. In contrast to the actin genes of other ascomycetous yeasts, which have only one large intron, the H. polymorpha ACT gene was found to be split by two introns. The H. polymorpha ACT introns were correctly processed in the heterologous host Saccharomyces cerevisiae despite appreciable differences in the splice site sequences. The promoter region of H. polymorpha ACT displayed two CCAAT motifs and two TATA-like sequences in a configuration similar to that observed in the S. cerevisiae actin promoter. A set of deleted H. polymorpha ACT promoters was exploited to direct expression of the bacterial hygromycin B resistance (hph) gene as a dominant selectable marker in the transformation of H. polymorpha. The resistance level of H. polymorpha transformants to the antibiotic was shown to be dependent on the integration copy number of the hph cassette. The selectivity of the hygromycin B resistance marker for transformants of higher copy number was remarkably increased with the deletion of the upstream TATA-like sequence, but not with the removal of either CCAAT motif, from the H. polymorpha promoter. The dosage-dependent selection system developed in this study should be useful for genetic manipulation of H. polymorpha as an industrial strain to produce recombinant proteins.     

Efficient plastid transformation in tobacco using the<Emphasis Type="Italic"> aphA-6</Emphasis> gene and kanamycin selection

Here we report on the development of a new dominant selection marker for plastid transformation in higher plants using the aminoglycoside phosphotransferase gene aphA-6 from Acinetobacter baumannii. Vectors containing chimeric aphA-6 gene constructs were introduced into the tobacco chloroplast using particle bombardment of alginate-embedded protoplast-derived micro colonies or polyethylene glycol (PEG)-mediated DNA uptake. Targeted insertion into the plastome was achieved via homologous recombination, and plastid transformants were recovered on the basis of their resistance to kanamycin. Variations in kanamycin resistance in transplastomic lines were observed depending on the 5' and 3' regulatory elements associated with the aphA-6 coding region. Transplastomic plants were fertile and showed maternal inheritance of the transplastome in the progeny.     

A guide to choosing vectors for transformation of the plastid genome of higher plants

Plastid transformation, originally developed in tobacco (Nicotiana tabacum), has recently been extended to a number of crop species enabling in vivo probing of plastid function and biotechnological applications. In this article we report new plastid vectors that enable insertion of transgenes in the inverted repeat region of the plastome between the trnV and 3'rps12 or trnI and trnA genes. Efficient recovery of transplastomic clones is ensured by selection for spectinomycin (aadA) or kanamycin (neo) resistance genes. Expression of marker genes can be verified using commercial antibodies that detect the accumulation of neomycin phosphotranseferase II, the neo gene product, or the C-terminal c-myc tag of aminoglycoside-3'-adenylytransferase, encoded by the aadA gene. Aminoglycoside-3'-adenylytransferase, the spectinomycin inactivating enzyme, is translationally fused with green fluorescent protein in two vectors so that transplastomic clones can be selected by spectinomycin resistance and visually identified by fluorescence in ultraviolet light. The marker genes in the new vectors are flanked by target sites for Cre or Int, the P1 and phiC31 phage site-specific recombinases. When uniform transformation of all plastid genomes is obtained, the marker genes can be excised by Cre or Int expressed from a nuclear gene. Choice of expression signals for the gene of interest, complications caused by the presence of plastid DNA sequences recognized by Cre, and loss of transgenes by homologous recombination via duplicated sequences are also discussed to facilitate a rational choice from among the existing vectors and to aid with new target-specific vector designs.     

The two largest chloroplast genome-encoded open reading frames of higher plants are essential genes

The chloroplast genomes of most higher plants contain two giant open reading frames designated ycf1 and ycf2. In tobacco, ycf1 potentially specifies a protein of 1901 amino acids. The putative gene product of the ycf2 reading frame is a protein of 2280 amino acids. In an attempt to determine the functions of ycf1 and ycf2, we have constructed several mutant alleles for targeted disruption and/or deletion of these two reading frames. The mutant alleles were introduced into the tobacco plastid genome by biolistic chloroplast transformation to replace the corresponding wild-type alleles by homologous recombination. Chloroplast transformants were obtained for all constructs and tested for their homoplastomic state. We report here that all transformed lines remained heteroplastomic even after repeated cycles of regeneration under high selective pressure. A balanced selection was observed in the presence of the antibiotic spectinomycin, resulting in maintenance of a fairly constant ratio of wild-type versus transformed genome copies. Upon removal of the antibiotic and therewith release of the selective pressure, sorting out towards the wild-type plastid genome occurred in all transplastomic lines. These findings suggest that ycf1 and ycf2 are functional genes and encode products that are essential for cell survival. The two reading frames are thus the first higher plant chloroplast genes identified as being indispensable.     

Instability of Tn5 inserts in cyanobacterial cloning vectors.

Transposon Tn5 was used to produce random insertions in two hybrid cloning vectors for the unicellular cyanobacterium Anacystis nidulans. The transposon-containing plasmids were used to localize essential replication functions and to characterize the stability of large inserts in these vectors. The effect of the insertions on plasmid function was tested by transformation into a derivative of A. nidulans that had been cured of the endogenous plasmid used to construct the vectors. A region of approximately 4 kilobases was essential for successful plasmid transformation and replication. This region has also been shown to be involved in plasmid replication by deletion analysis. High rates of excision of Tn5 inserts within this region and restoration of normal replication function were observed when transformants were selected by using a resistance marker outside the replication region in the absence of selection for the transposon-coded kanamycin resistance. Transposon inserts outside this region were not deleted.     

The presence of a defective LEU2 gene on 2 mu DNA recombinant plasmids of Saccharomyces cerevisiae is responsible for curing and high copy number.

The copy number of 2 mu DNA-derived plasmids in CIR+ Saccharomyces cerevisiae transformants is determined by its selective marker and is usually much lower than that of the endogenous plasmid. Only plasmids containing the leu2 allele of pJDB219, designated as leu2-d, under selective conditions displayed a higher copy number than did endogenous 2 mu DNA and by displacement generated cured cells. Spontaneous loss of 2 mu DNA occurred with a frequency of about 0.02% per generation. Curing plasmids, like pMP78, have copy numbers of 35; noncuring plasmids, like pDB248 or YEp6, have copy numbers of 4 to 8. The 2 mu DNA copy number in strains AH22 and YNN27 were determined to be 40 and 100, respectively. The high copy number of leu2-d-containing plasmids can be explained by its weak expression of less than 5% that of the wild-type LEU2 gene. The leu2-d allele has a deletion of the 5'-end sequence starting from 29 base pairs before the ATG initiation codon, but surprisingly, its expression is still regulated. On YRp7, which contains the chromosomal autonomic replication sequence ARS1, the defective leu2-d allele could not complement a leu2 host strain. This suggests a more stringent control of replication of ARS1-containing plasmids than of 2 mu-containing plasmids.     

Generation of marker-free plastid transformants using a transiently cointegrated selection gene

Genetic engineering of higher plant plastids typically involves stable introduction of antibiotic resistance genes as selection markers. Even though chloroplast genes are maternally inherited in most crops, the possibility of marker transfer to wild relatives or microorganisms cannot be completely excluded. Furthermore, marker expression can be a substantial metabolic drain. Therefore, efficient methods for complete marker removal from plastid transformants are necessary. One method to remove the selection gene from higher plant plastids is based on loop-out recombination, a process difficult to control because selection of homoplastomic transformants is unpredictable. Another method uses the CRE/lox system, but requires additional retransformation and sexual crossing for introduction and subsequent removal of the CRE recombinase. Here we describe the generation of marker-free chloroplast transformants in tobacco using the reconstitution of wild-type pigmentation in combination with plastid transformation vectors, which prevent stable integration of the kanamycin selection marker. One benefit of a procedure using mutants is that marker-free plastid transformants can be produced directly in the first generation (T0) without retransformation or crossing.     

Comparative genome hybridization reveals widespread aneuploidy in Candida albicans laboratory strains

Clinical strains of Candida albicans are highly tolerant of aneuploidies and other genome rearrangements. We have used comparative genome hybridization (CGH), in an array format, to analyse the copy number of over 6000 open reading frames (ORFs) in the genomic DNA of C. albicans laboratory strains carrying one (CAI-4) to three (BWP17) auxotrophies. We find that during disruption of the HIS1 locus all genes telomeric to HIS1 were deleted and telomeric repeats were added to a 9 nt sequence within the transforming DNA. This deletion occurred in approximately 10% of transformants analysed and was stably maintained through two additional rounds of transformation and counterselection of the transformation marker. In one example, the deletion was repaired, apparently via break-induced replication. Furthermore, all CAI-4 strains tested were trisomic for chromosome 2 although this trisomy appears to be unstable, as it is not detected in strains subsequently derived from CAI-4. Our data indicate CGH arrays can be used to detect monosomies and trisomies, to predict the sites of chromosome breaks, and to identify chromosomal aberrations that have not been detected with other approaches in C. albicans strains. Furthermore, they highlight the high level of genome instability in C. albicans laboratory strains exposed to the stress of transformation and counterselection on 5-fluoro-orotic acid.     

Plastome characteristics of Cannabaceae

Cannabaceae is an economically important family that includes ten genera and ca.117 accepted species. To explore the structure and size variation of their plastomes,we sequenced ten plastomes representing all ten genera of Cannabaceae.Each plastome possessed the typical angiosperm quadripartite structure and contained a total of 128 genes.The Inverted Repeat (IR) regions in five plastomes had experienced small expansions (330-983 bp) into the Large Single-Copy (LSC) region.The plastome of Chaetachme aristata has experienced a 942-bp IR contraction and lost rpl22 and rps19 in its IRs.The substitution rates of rps19 and rpl22 decreased after they shifted from the LSC to IR.A 270-bp inversion was detected in the Parasponia rugosa plastome,which might have been mediated by 18-bp inverted repeats.Repeat sequences,simple sequence repeats,and nucleotide substitution rates varied among these plastomes. Molecular markers with more than 13% variable sites and 5% parsimony-informative sites were identified,which may be useful for further phylogenetic analysis and species identification.Our results show strong support for a sister relationship between Gironniera and Lozanell (BS=100).Celtis,Cannabis-Humulus,Chaetachme-Pteroceltis,and Trema-Parasponia formed a strongly supported clade,and their relationships were well resolved with strong support (BS=100).The availability of these ten plastomes provides valuable genetic information for accurately identifying species,clarifying taxonomy and reconstructing the intergeneric phylogeny of Cannabaceae.     

Efficient male germ line transformation for transgenic tobacco production without selection

Microspores at late uninucleate/early binucleate stages were isolated from flower buds of tobacco (Nicotiana tabacum L.) and in vitro culture methods optimised for their maturation to fully functional viable pollen which, after application to the stigma of emasculated plants in situ, led to the generation of large numbers of seed. Efficient protocols were established for the biolistic introduction of a construct containing a reporter gene and selectable marker into these microspores and hence, after in vitro maturation and in situ fertilisation, for the generation of transgenic plants. Stable transformants of low copy number were generated by this procedure. The efficiency of transformation achieved allows the production of large numbers of transgenic plants without selection, dispensing with the requirement for a selectable marker in plant transgenesis.     

A novel selectable marker based on Aspergillus niger arginase expression

Selectable markers are valuable tools in transforming asexual fungi like Aspergillus niger. An arginase (agaA) expression vector and a suitable arginase-disrupted host would define a novel nutritional marker/selection for transformation. The development of such a marker was successfully achieved in two steps. The single genomic copy of A. niger arginase gene was disrupted by homologous integration of the bar marker. The agaA disruptant was subsequently complemented by transforming it with agaA expression vectors. Both citA and trpC promoters were able to drive the expression of arginase cDNA. Such agaA+ transformants displayed arginase expression pattern distinct from that of the parent strain. The results are also consistent with a single catabolic route for arginine in this fungus. A simple yet novel arginine-based selection for filamentous fungal transformation is thus described.     

A novel extrachromosomally maintained transformation vector for the lignin-degrading basidiomycete Phanerochaete chrysosporium.

A stable extrachromosomally maintained transformation vector (pG12-1) for the lignin-degrading filamentous fungus Phanerochaete chrysosporium is described. The vector is 6.3 kb and contains a Kanr marker, pBR322 ori, and a 2.2-kb fragment (ME-1) derived from an endogenous extrachromosomal DNA element of P. chrysosporium. Vector pG12-1 was able to transform P. chrysosporium to G418 resistance and was readily and consistently recoverable from the total DNA of transformants via Escherichia coli transformation. Southern blot analyses indicated that pG12-1 is maintained at a low copy number in the fungal transformants. The vector is demonstrable in the total DNA of individual G418-resistant basidiospore progeny of the transformants only after amplification by polymerase chain reaction. Exonuclease III and dam methylation analyses, respectively, indicated that pG12-I undergoes replication in P. chrysosporium and that it is maintained extrachromosomally in a circular form. The vector is stably maintained in the transformants even after long-term nonselective growth. There is no evidence for integration of the vector into the chromosome at any stage.     

Cloning, mapping and molecular analysis of the pyrG (orotidine-5'-phosphate decarboxylase) gene of Aspergillus nidulans

We have modified the transformation procedures of Ballance et al. [Biochem. Biophys. Res. Commun. 112 (1983) 284-289] to give increased rates of transformation in Aspergillus nidulans. With the modified procedures we have been able to complement pyrG89, a mutation in the orotidine-5'-phosphate decarboxylase gene of A. nidulans, by transformation with a library of wild-type (wt) sequences in pBR329. We have recovered, by marker rescue from one such transformant, a plasmid (pJR15) that carries an A. nidulans sequence that complements pyrG89 efficiently. In three experiments, this plasmid gave an average of 1985 stable transformants/micrograms of transforming DNA. We have analyzed ten of these genetically and by Southern hybridization. In five transformants a single copy of the transforming plasmid had integrated at the pyrG locus, in one transformant several copies of pJR15 had integrated at this locus, in one transformant several copies of the plasmid had integrated into other sites, and in three transformants, the wt allele had apparently replaced the mutant allele with no integration of pBR329 sequences. Sequence and S1 nuclease protection analysis revealed that pJR15 contains a gene that predicts an amino acid sequence with regions of strong homology to the orotidine-5'-phosphate decarboxylases of Neurospora crassa and Saccharomyces cerevisiae. We conclude that this gene is the wt pyrG allele. Finally, we have compared the 5'- and 3'-noncoding sequences and intron splice sequences to other genes of A. nidulans and have mapped the pyrG locus to a region between the fpaB and galD loci on linkage group I.     

BHRF1 of Epstein-Barr virus, which is homologous to human proto-oncogene bcl2, is not essential for transformation of B cells or for virus replication in vitro.

The Epstein-Barr virus (EBV) genome contains an open reading frame, BHRF1, that encodes a presumptive membrane protein with sequence similarity to the proto-oncogene bcl2, which is linked to human B-cell follicular lymphoma. Potential roles for BHRF1 in EBV's ability to growth transform human B cells and to replicate in B cells in culture were investigated by generating EBV mutants that lack most of the open reading frame. This was accomplished by recombination of plasmids carrying mutations in BHRF1 with the transformation-defective EBV strain P3HR1. Because BHRF1 resides close to the deletion in P3HR1 that renders this strain transformation defective, B-cell transformation could be used to select for recombination events in the region. B-cell clones were established by recombinants which lacked most of the BHRF1 open reading frame, although most of these initial B-cell transformants also carried nonrecombinant (BHRF1+) P3HR1 genomes, at levels ranging from a fraction of a copy to four copies per cell. Secondary B-cell transformants that lacked BHRF1+ EBV at detectable levels were found to release transforming, BHRF1-deficient EBV at levels that were within the normal range for EBV-immortalized B-cell clones. These studies demonstrate that BHRF1 is nonessential for growth transformation of B cells and for virus replication and release from these cells in culture.