Polyamines eliminate an extreme size bias against transformation of large yeast artificial chromosome DNA

The recent development of vectors and methods for cloning large linear DNA as yeast artificial chromosomes (YACs) has enormous potential in facilitating genome analysis, particularly because of the large cloning capacity of the YAC cloning system. However, the construction of comprehensive libraries with very large DNA segments (400-500 kb average insert size) has been technically very difficult to achieve. We have examined the possibility that this difficulty is due, at least in part, to preferential transformation of the smaller DNA molecules in the yeast transformation mixture. Our data indicate that the transformation efficiency of a 330-kb linear YAC DNA molecule is 40-fold lower, on a molar basis, than that of a 110-kb molecule. This extreme size bias in transformation efficiency is dramatically reduced (to less than 3-fold) by treating the DNA with millimolar concentrations of polyamines prior to and during transformation into yeast spheroplasts. This effect is accounted for by a stimulation in transformation efficiency of the 330-kb YAC molecule; the transformation efficiency of the 110-kb YAC molecule is not affected by the inclusion of polyamines. Application of this finding to the cloning of large exogenous DNA as artificial chromosomes in yeast will facilitate the construction of genomic libraries with significantly increased average insert sizes. In addition, the methods described allow efficient transfer of YACs to yeast strain backgrounds suitable for subsequent manipulations of the large insert DNA.     

Transformation of Escherichia coli with large DNA molecules by electroporation.

We have examined bacterial electroporation with a specific interest in the transformation of large DNA, i.e. molecules > 100 kb. We have used DNA from bacterial artificial chromosomes (BACs) ranging from 7 to 240 kb, as well as BAC ligation mixes containing a range o different sized molecules. The efficiency of electroporation with large DNA is strongly dependent on the strain of Escherichia coli used; strains which offer comparable efficiencies for 7 kb molecules differ in their uptake of 240 kb DNA by as much as 30-fold. Even with a host strain that transforms relatively well with large DNA, transformation efficiency drops dramatically with increasing size of the DNA. Molecules of 240 kb transform approximately 30-fold less well, on a molar basis, than molecules of 80 kb. Maximum transformation of large DNA occurs with different voltage gradients and with different time constants than are optimal for smaller DNA. This provides the opportunity to increase the yield of transformants which have taken up large DNA relative to the number incorporating smaller molecules. We have demonstrated that conditions may be selected which increase the average size of BAC clones generated by electroporation and compare the overall efficiency of each of the conditions tested.     

Construction of yeast artificial chromosome libraries with large inserts using fractionation by pulsed-field gel electrophoresis.

A method for constructing yeast artificial chromosome (YAC) libraries with large insert sizes is reported. High molecular weight human DNA was partially digested with EcoRI and cloned in the vector pYAC4. When unfractionated DNA was used, the mean YAC size was 120kb. Fractionation by pulsed-field gel electrophoresis using a 'waltzer' apparatus to remove small DNA fragments increased the mean YAC size to congruent to 220kb or congruent to 370kb depending on the fractionation conditions. Ligated DNA prepared by this method was stable at 4 degrees C and routinely yielded transformation efficiencies of greater than 700 colonies/micrograms. It should be possible to extend the method to produce even larger inserts and to use high molecular weight DNA from any source.     

Second-generation approach to the construction of yeast artificial-chromosome libraries

We describe an improved method for construction of yeast artificial-chromosome (YAC) libraries that contain large inserts of foreign DNA. The procedure consists of seven steps: (i) preparation of human DNA in agarose beads; (ii) partial digestion of the DNA with EcoRI; (iii) electrophoretic elimination of the smaller partial-digest fragments; (iv) ligation of the EcoRI fragments with vector arms in molten agarose; (v) hydrolysis of agarose with agarase; (vi) fractionation of the recombinant molecules by sucrose-gradient centrifugation; and (vii) transformation of yeast. More than 7000 colonies were obtained starting with 15 micrograms of human DNA, which was fractionated on a single sucrose gradient. The average size of these YACs was approximately 380 kb. It is estimated that the total length of human DNA present in the clones corresponds to 80% of the length of the human haploid genome. The results of screening the clones for a number of single-copy genes indicate that the clones reflect a nearly random sampling of the human genome. The efficiency of the cloning is sufficient to support the construction of multihit libraries for the human genome or for the genomes of other higher organisms.     

Bioactive beads-mediated transformation of rice with large DNA fragments containing Aegilops tauschii genes

Transformation with large DNA molecules enables multiple genes to be introduced into plants simultaneously to produce transgenic plants with complex phenotypes. In this study, a large DNA fragment (ca. 100 kb) containing a set of Aegilops tauschii hardness genes was introduced into rice plants using a novel transformation method, called bioactive beads-mediated transformation. Nine transgenic rice plants were obtained and the presence of transgenes in the rice genome was confirmed by PCR and FISH analyses. The results suggested that multiple transgenes were successfully integrated in all transgenic plants. The expression of one of the transgenes, puroindoline b, was confirmed at the mRNA and protein levels in the T₂ generation. Our study clearly demonstrates that the bioactive bead method is capable of producing transgenic rice plants carrying large DNA fragments. This method will facilitate the production of useful transgenic plants by introducing multiple genes simultaneously.     

DNA assembler,an in vivo genetic method for rapid construction of biochemical pathways

The assembly of large recombinant DNA encoding a whole biochemical pathway or genome represents a significant challenge. Here, we report a new method, DNA assembler, which allows the assembly of an entire biochemical pathway in a single step via in vivo homologous recombination in Saccharomyces cerevisiae. We show that DNA assembler can rapidly assemble a functional d-xylose utilization pathway (∼9 kb DNA consisting of three genes), a functional zeaxanthin biosynthesis pathway (∼11 kb DNA consisting of five genes) and a functional combined d-xylose utilization and zeaxanthin biosynthesis pathway (∼19 kb consisting of eight genes) with high efficiencies (70–100%) either on a plasmid or on a yeast chromosome. As this new method only requires simple DNA preparation and one-step yeast transformation, it represents a powerful tool in the construction of biochemical pathways for synthetic biology, metabolic engineering and functional genomics studies.     

Retrofitting YACs for direct DNA transfer into plant cells

The utility of plant YAC libraries prepared in conventional YAC vectors would be dramatically increased if these YACs could be used directly for plant transformation. A pair of vectors that allow clones from YAC libraries to be modified (retrofitted) for plant transformation by direct DNA transfer methods, such as particle bombardment or electroporation, has been developed. Modification of the YAC is achieved in two sequential yeast transformation steps by taking advantage of the homologous recombination system in yeast. Using this approach, two plant-selectable marker genes and DNA sequence elements required for copy number amplification in yeast can be introduced into YACs present in yeast strain AB1380. The utility of these vectors is demonstrated by retrofitting YACs that contain inserts ranging in size from 80 to 700 kb. The 6- to 12-fold increase in copy number of these modified YACs facilitates the isolation of YAC DNA for direct DNA transformation methods. Retrofitted YACs were used for particle bombardment to examine the efficiency with which their large DNA inserts are transferred into plant cells. The availability of these retrofitting vectors should facilitate the transfer of YAC DNA inserts into plant cells and thus help bridge the gap between existing mapping techniques and plant transformation procedures.     

Rescue of end fragments of yeast artificial chromosomes by homologous recombination in yeast.

Yeast artificial chromosomes (YACs) provide a powerful tool for the isolation and mapping of large regions of mammalian chromosomes. We developed a rapid and efficient method for the isolation of DNA fragments representing the extreme ends of YAC clones by the insertion of a rescue plasmid into the YAC vector by homologous recombination. Two rescue vectors were constructed containing a yeast LYS2 selectable gene, a bacterial origin of replication, an antibiotic resistance gene, a polylinker containing multiple restriction sites, and a fragment homologous to one arm of the pYAC4 vector. The 'end-cloning' procedure involves transformation of the rescue vector into yeast cells carrying a YAC clone, followed by preparation of yeast DNA and transformation into bacterial cells. The resulting plasmids carry end-specific DNA fragments up to 20 kb in length, which are suitable for use as hybridization probes, as templates for direct DNA sequencing, and as probes for mapping by fluorescence in situ hybridization. These vectors are suitable for the rescue of end-clones from any YAC constructed using a pYAC-derived vector. We demonstrate the utility of these plasmids by rescuing YAC-end fragments from a human YAC library.     

Yeast transformation process studied by fluorescence labeling technique

A new method based on fluorescence imaging and flow cytometry was developed to investigate the transformation process of Saccharomyces cerevisiae AY. Yeast and fluorescent-labeled plasmid pUC18 were used as models of cells and DNA molecules, respectively. Binding of DNA molecules to yeast cell surfaces was observed. Factors influencing DNA binding to cell surfaces were investigated. It has been found that poly(ethylene glycol) (PEG) could induce DNA binding to yeast surfaces, while Li(+) showed a weak effect on the binding. When both Li(+) and PEG were used, synergetic effect occurred, resulting in the binding of pUC18 to the surface of more yeast cells compared with that in the presence of PEG or Li(+) only. It was also confirmed that heat shock, Li(+), and PEG all can increase the permeability of yeast cells. This simple method is helpful for understanding the process of yeast transformation and can be used to investigate the interaction of DNA with cell surfaces.     

Biolistic transfer of large DNA fragments to tobacco cells using YACs retrofitted for plant transformation

To determine whether large DNA molecules could be transferred and integrated intact into the genome of plant cells, we bombarded tobacco suspension cells with yeast DNA containing artificial chromosomes (YACs) having sizes of 80, 150, 210, or 550 kilobases (kb). Plant selectable markers were retrofitted on both YAC arms so that recovery of each arm in transgenic calli could be monitored. Stably transformed calli resistant to kanamycin (300 mg/L) were recovered for each size of YAC tested. Two of 12 kanamycin-resistant transformants for the 80 kb YAC and 8 of 29 kanamycin-resistant transformants for the 150 kb YAC also contained a functional hygromycin gene derived from the opposite YAC arm. Southern analyses using probes that spanned the entire 55 kb insert region of the 80 kb YAC confirmed that one of the two double-resistant lines had integrated a fully intact single copy of the YAC DNA while the other contained a major portion of the insert. Transgenic lines that contained only one selectable marker gene from the 80 kb YAC incorporated relatively small portions of the YAC insert DNA distal to the selectable marker. Our data suggest genomic DNA cloned in artificial chromosomes up to 150 kb in size have a reasonable likelihood of being transferred by biolistic methods and integrated intact into the genome of plant cells. Biolistic transfer of YAC DNA may accelerate the isolation of agronomically useful plant genes using map-based cloning strategies.     

Assembly of eukaryotic algal chromosomes in yeast

Background

Synthetic genomic approaches offer unique opportunities to use powerful yeast and Escherichia coli genetic systems to assemble and modify chromosome-sized molecules before returning the modified DNA to the target host. For example, the entire 1 Mb Mycoplasma mycoides chromosome can be stably maintained and manipulated in yeast before being transplanted back into recipient cells. We have previously demonstrated that cloning in yeast of large (>?~?150 kb), high G?+?C (55%) prokaryotic DNA fragments was improved by addition of yeast replication origins every ~100 kb. Conversely, low G?+?C DNA is stable (up to at least 1.8 Mb) without adding supplemental yeast origins. It has not been previously tested whether addition of yeast replication origins similarly improves the yeast-based cloning of large (> 150 kb) eukaryotic DNA with moderate G?+?C content. The model diatom Phaeodactylum tricornutum has an average G?+?C content of 48% and a 27.4 Mb genome sequence that has been assembled into chromosome-sized scaffolds making it an ideal test case for assembly and maintenance of eukaryotic chromosomes in yeast.

Results

We present a modified chromosome assembly technique in which eukaryotic chromosomes as large as ~500 kb can be assembled from cloned ~100 kb fragments. We used this technique to clone fragments spanning P. tricornutum chromosomes 25 and 26 and to assemble these fragments into single, chromosome-sized molecules. We found that addition of yeast replication origins improved the cloning, assembly, and maintenance of the large chromosomes in yeast. Furthermore, purification of the fragments to be assembled by electroelution greatly increased assembly efficiency.

Conclusions

Entire eukaryotic chromosomes can be successfully cloned, maintained, and manipulated in yeast. These results highlight the improvement in assembly and maintenance afforded by including yeast replication origins in eukaryotic DNA with moderate G?+?C content (48%). They also highlight the increased efficiency of assembly that can be achieved by purifying fragments before assembly.

     

What the papers say: Molecular karyotypes: Separating chromosomes on gels

For many years, there has been a gap in our capacity to study the structure and organization of chromosomal DNA molecules. The very small genomes of some viruses and bacteriophages (≤ 50,000 bp or 50 kb) are amenable to analysis by conventional gel electrophoresis, while the extremely large DNA molecules (> 100,000 kb) comprising the chromosomes of higher eukaryotes have been analysed under the light microscope, using a range of banding and in situ hybridization techniques. However, intact DNA molecules with sizes between these two extremes have been largely inaccessible experimentally. This gap has recently been bridged with the development of two-dimensional electrophoretic procedures that allow the separation and purification of chromosome-sized DNA molecules ranging from ～ 50 kb to several thousand kb.^1–3 There are currently two variations of the technique in use: pulsed field gradient (PFG) gel electrophoresis^1,2 and orthogonal-field-alteration gel electrophoresis (OFAGE).³ Both are based on a common principle, differing primarily in the geometry of the electrodes. Already, they have been employed to determine the approximate chromosome sizes and numbers for a variety of lower eukaryotes, including yeast and several protozoa.^2–10 These ‘molecular karyotypes’ provide fundamental information about the genomic organization of each organism, and allow very rapid construction of linkage maps. Surprisingly, they have also revealed a remarkable plasticity in the genomes of several lower eukaryotes.     

Digital mapping of bacterial artificial chromosomes by fluorescence in situ hybridization

The bacterial artificial chromosome (BAC) has become the most popular tool for cloning large DNA fragments. The inserts of most BAC clones average 100-200 kilobases (kb) and molecular characterization of such large DNA fragments is a major challenge. Here we report a simple and expedient technique for physical mapping of BAC inserts. Individual BAC molecules were immobilized on glass slides coated with Poly-L-lysine. The intact circular BAC molecules were visualized by fluorescence in situ hybridization using BAC DNA as a probe. The 7.4 kb BAC vector was extended to approximately 2.44 kb per micrometer. Digitally measured linear distances can be transformed into kilobases of DNA using the extension of BAC vector as a standard calibration. We mapped DNA fragments as small as 2 kb directly on circular BAC molecules. A rice BAC clone containing both tandem and dispersed repeats was analyzed using this technique. The distribution and organization of the different repeats within the BAC insert were efficiently determined. The results showed that this technique will be especially valuable for characterizing BAC clones that contain complex repetitive DNA sequences.     

Protoplast transformation of Kluyveromyces marxianus

The dairy yeast Kluyveromyces marxianus is a promising cell factory for producing bioethanol and heterologous proteins, as well as a robust synthetic biology platform host, due to its safe status and beneficial traits, including fast growth and thermotolerance. However, the lack of high-efficiency transformation methods hampers the fundamental research and industrial application of this yeast. Protoplast transformation is one of the most commonly used fungal transformation methods, but it yet remains unexplored in K. marxianus. Here, we established the protoplast transformation method of K. marxianus for the first time. A series of parameters on the transformation efficiency were optimized: cells were collected in the late-log phase and treated with zymolyase for protoplasting; the transformation was performed at 0 °C with carrier DNA, CaCl₂, and PEG; after transformation, protoplasts were recovered in a solid regeneration medium containing 3–4% agar and 0.8 m sorbitol. By using the optimized method, plasmids of 10, 24, and 58 kb were successfully transformed into K. marxianus. The highest efficiency reached 1.8 × 10⁴ transformants per μg DNA, which is 18-fold higher than the lithium acetate method. This protoplast transformation method will promote the genetic engineering of K. marxianus that requires high-efficiency transformation or the introduction of large DNA fragments.     

Genetic transformation of Saccharomyces cerevisiae with single-stranded circular DNA vectors

We asked if single-stranded vector DNA molecules could be used to reintroduce cloned DNA sequences into a eukaryotic cell and cause genetic transformation typical of that observed using double-stranded DNA vectors. DNA was presented to Saccharomyces cerevisiae following a standard transformation protocol, genetic transformants were isolated, and the physical state of the transforming DNA sequence was determined. We found that single-stranded DNA molecules transformed yeast cells 10- to 30-fold more efficiently than double-stranded molecules of identical sequence. More cells were competent for transformation by the single-stranded molecules. Single-stranded circular (ssc) DNA molecules carrying the yeast 2 μ plasmid-replicator sequence were converted to autonomously replicating double-stranded circular (dsc) molecules, suggesting their efficient utilization as templates for DNA synthesis in the cell. Single-stranded DNA molecules carrying 2 μ plasmid non-replicator sequences recombined with the endogenous multicopy 2 μ plasmid DNA. This recombination yielded either the simple molecular adduct expected from homologous recombination (40% of the transformants examined) or aberrant recombination products carrying incomplete transforming DNA sequences, endogenous 2 μ plasmid DNA sequences, or both (60% of the transformants examined). These aberrant recombination products suggest the frequent use of a recombination pathway that trims one or both of the substrate DNA molecules. Similar aberrant recombination products were detected in 30% of the transformants in cotransformation experiments employing single-stranded and double-stranded DNA molecules, one carrying the 2 μ plasmid replicator sequence and the other the selectable genetic marker. We conclude that single-stranded DNA molecules are useful vectors for the genetic transformation of a eukaryotic cell. They offer the advantage of high transformation efficiency, and yield the same intracellular DNA species obtained upon transformation with double-stranded DNA molecules. In addition, single-stranded DNA molecules can participate in a recombination pathway that trims one or both DNA recombination substrates, a pathway not detected, at least at the same frequency, when transforming with double-stranded DNA molecules     

Isolation and characterization of yeast ring chromosome III by a method applicable to other circular DNAs

A method is described for the isolation and purification of covalently closed circular (ccc) DNA from yeast (Saccharomyces cerevisiae). Spheroplasts are lysed at pH 12.45 which denatures linear but not ccc DNA. Next, the lysate is taken through a gentle high-salt-phenol extraction to remove single-stranded DNA. The ccc DNA, recovered by ethanol precipitation, can be further studied by agarose gel electrophoresis, can be cut with restriction endonucleases and can be used to transform Escherichia coli. This method efficiently purifies large (approx. 190 kb) and small (approx. 1.5 kb, TRP1-RI Circle) circular DNAs and thus has general applicability for isolation and purification of plasmids from yeast.     

Features of integration of recombinant cosmids, containing Aspergillus terreus DNA, in the Saccharomyces cerevisiae genome

A genome clonotheque of 25-40 kb Sau3A fragments of Aspergillus terreus DNA was constructed in the episomal cosmid vector pES33 containing the ARG4 gene of yeast. 23 independently originated stable Arg+ transformants were selected after transformation of the cir0 yeast strain ESH-O with pooled cosmid molecules. Both genetic and Southern analysis showed that 39% of these stable transformants occurred due to recombination between DNA sequences from A. terreus and Saccharomyces cerevisiae chromosome XII which took place most likely in the regions of homology within the ribosomal clusters. The data present the first evidence of in vivo recombination between foreign sequences and their S. cerevisiae counterparts.     

Targeted alterations in yeast artificial chromosomes for inter-species gene transfer.

In order to facilitate alterations of large DNA molecules for their introduction into mammalian cells we have characterised the mechanism of site-specific modifications in yeast artificial chromosomes (YACs). Newly developed yeast integration vectors with dominant selectable marker genes allow targeted integration into left (centromeric) and right (non-centromeric) YAC arms as well as alterations to the human derived insert DNA. In transformation experiments, integration proceeds exclusively by homologous recombination although yeast prefers linear ends of homology for predefined insertions. Targeted regions can be rescued which expedite the cloning of internal human sequences and the identification of 5' and 3' YAC/insert borders. Integration of the neomycin resistance gene into various parts of the YAC allowed the transfer and stable integration of large DNA molecules into a variety of mammalian cells including embryonic stem cells.