Cloning of random-sequence oligodeoxynucleotides

Methods are described for cloning random or highly degenerate nucleotide (nt) sequences. The procedures use synthetically derived mixtures of oligodeoxynucleotides (oligos) whose heterogeneous central portions are bounded at their 5' and 3' ends by sequences recognized by restriction endonucleases. Oligo collections of defined length and nt composition are synthesized by utilizing appropriate concentrations of all four nucleotide precursors during each addition step for the central region. Single-stranded oligos with appropriate 5' and 3' ends can be ligated directly, although inefficiently, into double-stranded (ds) DNA molecules with complementary 5' and 3' extensions produced by restriction endonuclease cleavage. A more general and efficient method is to convert the oligo into a ds form by incubating it with the Klenow (large) fragment of Escherichia coli DNA polymerase I. If the 3' ends are palindromic, two oligo molecules will serve as mutual primers for polymerization. The resulting products are ds molecules containing two oligo units separated by the original 3' restriction site and bounded at each end by the original 5' restriction site. After appropriate restriction endonuclease cleavage, oligo units can be cloned by standard procedures. Analysis of 26 recombinant M13 phages indicates that the nt sequences of the cloned oligos are in good accord with what was expected on a random basis.     

Patterns of intracellular compartmentalization, trafficking and acidification of 5'-fluorescein labeled phosphodiester and phosphorothioate oligodeoxynucleotides in HL60 cells.

We have examined the intracellular compartmentalization and trafficking of fluorescein labeled (F) phosphodiester (PO) and phosphorothioate (PS) oligodeoxynucleotides (oligos) in HL60 cells. A series of F-oligos (PO and PS) were incubated for 6 hrs. with HL60 cells and the mean intracellular fluorescence determined by flow cytometry. The F signal was normalized by the addition of the ionophore monensin. An increase in signal intensity following addition of monensin indicated that the oligo was resident in an acidic intracellular environment. F-PS, but not F-PO oligos were found to reside in an acidic environment. An exception was a PO homopolymer of 15 cytidine bases (FOdC15) which was acidified. Using two different methods, the average resident intracellular pH of F-PS oligos and F-OdC15 was shown to be approximately 1 pH unit lower than that of F-PO oligos. Acidification of F-PS oligos could be blocked by the antibiotic bafilomycin, indicating that acidification was occurring in endosomes or vacuoles. F-PO and F-PS oligos were effluxed from HL60 cells from two intracellular compartments. However, approximately 60% of internalized F-PO oligo resided in a 'shallow' compartment that was turned over rapidly (t1/2 = 5-10 min.) whereas only 20% of F-PS oligo resided in this compartment. Conversely, approximately 80% of the internalized F-PS oligo but only 40% of F-PO oligo resided in a 'deep' compartment that turned over with t1/2 = 2-5 hrs. This report is the first quantitative demonstration that PO and PS oligos, and PO oligos of different sequences are trafficked differently by HL60 cells.     

Synthetic modification of silica beads that allows for sequential attachment of two different oligonucleotides

We developed a simple and elegant synthesis strategy that enables us to attach controlled (equimolar) amounts of two different oligonucleotides onto one silica bead. The method involves addition of orthogonally protected lysine followed by activation and derivatization of each amino group with a different moiety. This sequential oligonucleotide attachment enables the use of a combinatorial scheme to generate millions of bead types, each characterized by its two oligo tags. (In our randomly assembled arrays each bead type can then be identified by a series of hybridizations of fluorescently labeled decoder oligos to the address tags.) To demonstrate feasibility of such a scheme we created over 1000 bead types, which were characterized by their two oligo tags. The method enables genotyping or gene expression assays at multiplex levels of hundreds of thousands to millions.     

A more efficient and specific strategy in the ablation of mRNA in Xenopus laevis using mixtures of antisense oligos.

Previously, antisense oligodeoxyribonucleotides (oligos) have been used to ablate specific mRNAs from the maternal RNA pool of Xenopus laevis oocytes. However, this strategy is limited by the dose of oligo which can be used and the fact that 100% cleavage of the target RNA is rare. Further, non-specific cleavage of other RNAs can also occur. We demonstrate that the use of several oligos against the histone H4 RNA results in a marked improvement in the efficiency of target degradation, due to synergistic action between oligos and the existence of RNA in at least two different secondary structures. We show, by using a set of overlapping oligos complementary to the entire H4 RNA, that the amount of oligo required for efficient target ablation is greatly lowered and non-specific effects are reduced.     

Bacterial DNA polymerases participate in oligonucleotide recombination

Synthetic single‐strand oligonucleotides (oligos) with homology to genomic DNA have proved to be highly effective for constructing designed mutations in targeted genomes, a process referred to as recombineering. The cellular functions important for this type of homologous recombination have yet to be determined. Towards this end, we have identified Escherichia coli functions that process the recombining oligo and affect bacteriophage λ Red‐mediated oligo recombination. To determine the nature of oligo processing during recombination, each oligo contained multiple nucleotide changes: a single base change allowing recombinant selection, and silent changes serving as genetic markers to determine the extent of oligo processing during the recombination. Such oligos were often not incorporated into the host chromosome intact; many were partially degraded in the process of recombination. The position and number of these silent nucleotide changes within the oligo strongly affect both oligo processing and recombination frequency. Exonucleases, especially those associated with DNA Polymerases I and III, affect inheritance of the silent nucleotide changes in the oligos. We demonstrate for the first time that the major DNA polymerases (Pol I and Pol III) and DNA ligase are directly involved with oligo recombination.     

Oligo replication advantage driven by GC content and Gibbs free energy

Large scale DNA oligo pools are emerging as a novel material in a variety of advanced applications. However, GC content and length cause significant bias in amplification of oligos. We systematically explored the amplification of one oligo pool comprising of over ten thousand distinct strands with moderate GC content in the range of 35–65%. Uniqual amplification of oligos result to the increased Gini index of the oligo distribution while a few oligos greatly increased their proportion after 60 cycles of PCR. However, the significantly enriched oligos all have relatively high GC content. Further thermodynamic analysis demonstrated that a high value of both GC content and Gibbs free energy could improve the replication of specific oligos during biased amplification. Therefore, this double-G (GC content and Gibbs free energy) driven replication advantage can be used as a guiding principle for the sequence design for a variety of applications, particularly for data storage.

     

Transformation with oligonucleotides creating clustered changes in the yeast genome

We have studied single-strand oligonucleotide (oligo) transformation of yeast by using 40-nt long oligos that create multiple base changes to the yeast genome spread throughout the length of the oligos, making it possible to measure the portions of an oligo that are incorporated during transformation. Although the transformation process is greatly inhibited by DNA mismatch repair (MMR), the pattern of incorporation is essentially the same in the presence or absence of MMR, whether the oligo anneals to the leading or lagging strand of DNA replication, or whether phosphorothioate linkages are used at either end. A central core of approximately 15 nt is incorporated with a frequency of >90%; the ends are incorporated with a lower frequency, and loss of the two ends appears to be by different mechanisms. Bases that are 5-10 nt from the 5' end are generally lost with a frequency of >95%, likely through a process involving flap excision. On the 3' end, bases 5-10 nt from the 3' end are lost about 1/3 of the time. These results indicate that oligos can be used to create multiple simultaneous changes to the yeast genome, even in the presence of MMR.     

An experimental and theoretical study of the inhibition of Escherichia coli lac operon gene expression by antigene oligonucleotides

Previously, we have developed a genetically structured mathematical model to describe the inhibition of Escherichia coli lac operon gene expression by antigene oligos. Our model predicted that antigene oligos targeted to the operator region of the lac operon would have a significant inhibitory effect on beta-galactosidase production. In this investigation, the E. coli lac operon gene expression in the presence of antigene oligos was studied experimentally. A 21-mer oligo, which was designed to form a triplex with the operator, was found to be able to specifically inhibit beta-galactosidase production in a dose-dependent manner. In contrast to the 21-mer triplex-forming oligonucleotide (TFO), several control oligos showed no inhibitory effect. The ineffectiveness of the various control oligos, along with the fact that the 21-mer oligo has no homology sequence with lacZYA, and no mRNA is transcribed from the operator, suggests that the 21-mer oligo inhibits target gene expression by an antigene mechanism. To simulate the kinetics of lac operon gene expression in the presence of antigene oligos, a genetically structured kinetic model, which includes transport of oligo into the cell, growth of bacteria cells, and lac operon gene expression, was developed. Predictions of the kinetic model fit the experimental data quite well after adjustment of the value of the oligonucleotide transport rate constant (9.0 x 10(-)(3) min(-)(1)) and oligo binding affinity constant (1.05 x 10(6) M(-)(1)). Our values for these two adjusted parameters are in the range of reported literature values.     

Specificity of the nick-closing activity of bacteriophage T4 DNA ligase

Bacteriophage T4 DNA ligase effectively joins two adjacent, short synthetic oligodeoxyribonucleotides (oligos), as guided by complementary oligo, plasmid and genomic DNA templates. When a single bp mismatch exists at either side of the ligation junction, the efficiency of the enzyme to ligate the two oligos decreases. Mismatch ligation is approximately five-fold greater if the mismatch occurs at the 3' side rather than at the 5' side of the junction. During mismatch ligation the 5' adenylate of the 3' oligo accumulates in the reaction. The level of the adenylate formation correlates closely with the level of the mismatch ligation. Both mismatch ligation and adenylate formation are suppressed at elevated temperatures and in the presence of 200 mM NaCl or 2-5 mM spermidine. The apparent Km for the oligo template in the absence of salt is 0.05 microM, whereas the Km increases to 0.2 microM in the presence of 200 mM of NaCl. In this report, we demonstrate these properties of T4 DNA ligase for oligo pairs complementary to the beta-globin gene at the sequence surrounding the single bp mutation responsible for sickle-cell anemia. Because of the highly specific nature of the nick-closing reaction, ligation of short oligos with DNA ligase can be used to distinguish two DNA templates differing by a single nucleotide.     

Chromosome-Specific Painting in Cucumis Species Using Bulked Oligonucleotides

Chromosome-specific painting is a powerful technique in molecular cytogenetic and genome research. We developed an oligonucleotide (oligo)-based chromosome painting technique in cucumber (Cucumis sativus) that will be applicable in any plant species with a sequenced genome. Oligos specific to a single chromosome of cucumber were identified using a newly developed bioinformatic pipeline and then massively synthesized de novo in parallel. The synthesized oligos were amplified and labeled with biotin or digoxigenin for use in fluorescence in situ hybridization (FISH). We developed three different probes with each containing 23,000–27,000 oligos. These probes spanned 8.3–17 Mb of DNA on targeted cucumber chromosomes and had the densities of 1.5–3.2 oligos per kilobases. These probes produced FISH signals on a single cucumber chromosome and were used to paint homeologous chromosomes in other Cucumis species diverged from cucumber for up to 12 million years. The bulked oligo probes allowed us to track a single chromosome in early stages during meiosis. We were able to precisely map the pairing between cucumber chromosome 7 and chromosome 1 of Cucumis hystrix in a F₁ hybrid. These two homeologous chromosomes paired in 71% of prophase I cells but only 25% of metaphase I cells, which may provide an explanation of the higher recombination rates compared to the chiasma frequencies between homeologous chromosomes reported in plant hybrids.     

Genomic fingerprinting using arbitrarily primed PCR and a matrix of pairwise combinations of primers.

Polymorphisms in genomic fingerprints generated by arbitrarily primed PCR (AP-PCR) can distinguish between slightly divergent strains of any organism. Single oligodeoxyribonucleotide (oligo) primers have been used to generate such fingerprints, with the same primer being present at the 5' end of both strands for every PCR product. We used three arbitrary oligos, individually and in pairs, to generate six different genomic fingerprints of the same mouse genomic DNAs. Fewer than half of the products in genomic fingerprints generated using the oligos in pairs were the same as those produced by AP-PCR using one of the three oligos alone. Thus, a few oligos could be used in a very large number of single and pairwise combinations, each producing a distinct AP-PCR fingerprint with the potential to identify new polymorphisms. For example, 50 oligos can be used in a matrix of pairwise combinations to produce 2,500 fingerprints, in which at least half the data can be expected to be unique to each pair. We demonstrate this principle by using two oligos, alone and together, to generate three sets of fingerprints and map thirteen polymorphisms in the C57BL/6J x DBA/2J set of recombinant inbred mice.     

Exact word matches in rice pseudomolecules.

Using pseudomolecules of assembled genomic sequence, we computed the frequencies of 6 to 24 bp oligonucleotide (oligo) "words" across the genome of rice (Oryza sativa L. subsp. japonica). All oligos of 10 or fewer basepairs were repeated at least 12 times in the genome. The percentage of unique (non-repeated) oligos ranged from 0.1% for 12 bp oligos to 76.0% for 24 bp oligos. For three 200 kb regions, we annotated each nucleotide position with the genome-wide frequency of the 18 bp oligo starting at that position. These frequencies formed landscapes consisting of high- and low-frequency zones. Low-frequency zones contained occasional high-frequency spikes; these may represent footprints of RIM2 transposon activity. BLASTn searches of high-frequency non-SSR (simple sequence repeat) 18 bp oligos returned few sequences from species other than rice. These results demonstrate that, in rice, words are not randomly used between different regions within the same genome, and indicate that words that are frequently repeated within the rice genome tend to be unique to rice.     

Random mutagenesis using degenerate oligodeoxyribonucleotides

An efficient method for random mutagenesis was applied to a 75-bp target sequence. The mutational changes in the target region are introduced by the technique of oligodeoxyribonucleotide(oligo)-directed, site-specific mutagenesis using mixtures of degenerate oligos. These are designed in such a way that they carry with a high probability randomly distributed substitutions, which are introduced into the oligos by utilizing appropriate concentrations of all four nucleotide precursors during each chain elongation step. These mixtures of degenerate oligos were hybridized to the appropriate M13-hybrid ss-template and then extended in vitro using PolIk. In order to avoid any bias artificially created by the Escherichia coli mismatch repair system, homoduplex molecules were synthesized in vitro according to the method of Taylor et al. [Nucleic Acids Res. 13 (1985) 8765-8785]. After transformation of the appropriate E. coli host, M13 plaques were randomly analysed by DNA sequencing. Using appropriate preparations of template DNA and oligos we attained mutagenesis efficiencies in the range of 20-50%. The analysis of 85 different mutants revealed that the distribution of the mutations is random and that all expected substitutions occur with about the same probability.     

Poliovirus RNA-Dependent RNA Polymerase Synthesizes Full-Length Copies of Poliovirion RNA, Cellular mRNA, and Several Plant Virus RNAs In Vitro

The poliovirus RNA-dependent RNA polymerase was active on synthetic homopolymeric RNA templates as well as on every natural RNA tested. The polymerase copied polyadenylate. oligouridylate [oligo(U)], polycytidylate . oligoinosinate, and polyinosinate. oligocytidylate templates to about the same extent. The observed activity on polyuridylate. oligoadenylate was about fourfold less. Full-length copies of both poliovirion RNA and a wide variety of other polyadenylated RNAs were synthesized by the polymerase in the presence of oligo(U). Polymerase elongation rates on poliovirion RNA and a heterologous RNA (squash mosaic virus RNA) were about the same. Changes in the Mg(2+) concentration affected the elongation rates on both RNAs to the same extent. With two non-polyadenylated RNAs (tobacco mosaic virus RNA and brome mosaic virus RNA3), the results were different. The purified polymerase synthesized a subgenomic-sized product RNA on brome mosaic virus RNA3 in the presence of oligo(U). This product RNA appeared to initiate on oligo(U) hybridized to an internal oligoadenylate sequence in brome mosaic virus RNA3. No oligo(U)-primed product was synthesized on tobacco mosaic virus RNA. When partially purified polymerase was used in place of the completely purified enzyme, some oligo(U)-independent activity was observed on the brome mosaic virus and tobacco mosaic virus RNAs. The size of the product RNA from these reactions suggested that at least some of the product RNA was full-sized and covalently linked to the template RNA. Thus, the polymerase was found to copy many different types of RNA and to make full-length copies of the RNAs tested.     

Efficient selection of unique and popular oligos for large EST databases

MOTIVATION: Expressed sequence tag (EST) databases have grown exponentially in recent years and now represent the largest collection of genetic sequences. An important application of these databases is that they contain information useful for the design of gene-specific oligonucleotides (or simply, oligos) that can be used in PCR primer design, microarray experiments and genomic library screening. RESULTS: In this paper, we study two complementary problems concerning the selection of short oligos, e.g. 20-50 bases, from a large database of tens of thousands of ESTs: (i) selection of oligos each of which appears (exactly) in one unigene but does not appear (exactly or approximately) in any other unigene and (ii) selection of oligos that appear (exactly or approximately) in many unigenes. The first problem is called the unique oligo problem and has applications in PCR primer and microarray probe designs, and library screening for gene-rich clones. The second is called the popular oligo problem and is also useful in screening genomic libraries. We present an efficient algorithm to identify all unique oligos in the unigenes and an efficient heuristic algorithm to enumerate the most popular oligos. By taking into account the distribution of the frequencies of the words in the unigene database, the algorithms have been engineered carefully to achieve remarkable running times on regular PCs. Each of the algorithms takes only a couple of hours (on a 1.2 GHz CPU, 1 GB RAM machine) to run on a dataset 28 Mb of barley unigenes from the HarvEST database. We present simulation results on the synthetic data and a preliminary analysis of the barley unigene database. AVAILABILITY: Available on request from the authors.     

Oligonucleotide recombination in Gram-negative bacteria

This report describes several key aspects of a novel form of RecA-independent homologous recombination. We found that synthetic single-stranded DNA oligonucleotides (oligos) introduced into bacteria by transformation can site-specifically recombine with bacterial chromosomes in the absence of any additional phage-encoded functions. Oligo recombination was tested in four genera of Gram-negative bacteria and in all cases evidence for recombination was apparent. The experiments presented here were designed with an eye towards learning to use oligo recombination in order to bootstrap identification and development of phage-encoded recombination systems for recombineering in a wide range of bacteria. The results show that oligo concentration and sequence have the greatest influence on recombination frequency, while oligo length was less important. Apart from the utility of oligo recombination, these findings also provide insights regarding the details of recombination mediated by phage-encoded functions. Establishing that oligos can recombine with bacterial genomes provides a link to similar observations of oligo recombination in archaea and eukaryotes suggesting the possibility that this process is evolutionary conserved.     

Fast large scale oligonucleotide selection using the longest common factor approach

We present a fast method that selects oligonucleotide probes (such as DNA 25-mers) for microarray experiments on a truly large scale. For example, reliable oligos for human genes can be found within four days, a speedup of one to two orders of magnitude compared to previous approaches. This speed is attained by using the longest common substring as a specificity measure for candidate oligos. We present a space- and time-efficient algorithm, based on a suffix array with additional information, to compute matching statistics (lengths of longest matches) between all candidate oligos and all remaining sequences. With the matching statistics available, we show how to incorporate constraints such as oligo length, melting temperature, and self-complementarity into the selection process at a postprocessing stage. As a result, we can now design custom oligos for any sequenced genome, just as the technology for on-site chip synthesis is becoming increasingly mature.     

Insertional mutagenesis using a synthetic lac operator

We have developed a novel cassette for generating insertion mutants in multi-copy bacterial plasmids. The cassette consists of synthetic oligodeoxyribonucleotides (oligos) which form a DNA duplex following reconstitution in vitro, due to sequence complementarity. It contains a 21-bp segment of the lac operator (lacZo), to provide a readily detectable phenotypic marker. Bacterial colonies harboring plasmids with insertions of this cassette are blue due to constitutive expression of the lac operon resulting from titration of lac repressor molecules by plasmid-borne lacZo sequences. Synthetic oligos containing a desire sequence may be added to the cassette by complementary ends for targeted insertion into plasmids. Sequencing of the resulting insertion mutants is facilitated by using oligos within the cassette as primers for bidirectional sequencing. This allows a complete characterization of each insertion in terms of location, structure of flanking sequences, and orientation of the inserted oligo. We have used this system to construct a series of mutants in early region 1a genes of human adenovirus type 5. For this purpose we designed a cassette which had all three possible translational reading frames open when inserted in one orientation, and all reading frames closed in the other orientation. The cassette also had BamHI restriction sites at each end which could be used to 'collapse' mutants, reducing the size of each insert to 6 bp.