Modification of the n-3 HUFA biosynthetic pathway by transgenesis in a marine teleost, nibe croaker.

Marine fishes are generally unable to produce sufficient quantities of eicosapentaenoic acid (EPA; 20:5n-3) and docosahexaenoic acid (DHA; 22:6n-3) for their normal growth and survival, as the key fatty acid-metabolizing enzymes in the EPA and DHA biosynthetic pathway are limited. It is therefore necessary to supplement cultured marine fish species diets with fish oils in order to supply EPA and DHA. Given that freshwater fishes are capable of synthesizing both EPA and DHA, they presumably express all of the enzymes required for this biosynthetic pathway. Thus, we hypothesize that transgenic marine species carrying these fatty acid-metabolizing enzymes could be reared without the dietary supplementation of fish oil. As the first step toward this goal, we used marine fish, nibe croaker to produce a transgenic line carrying the elongase gene isolated from masu salmon. Fatty acid analysis revealed that the liver EPA (20:5n-3) content in the transgenic fish was lower (3.3% vs. 7.7%). However, docosapentaenoic acid (22:5n-3) content in the transgenic fish was 2.28-fold (4.1% vs. 1.8%) higher than in non-transgenic fish. Further, tetracosapentaenoic acid (24:5n-3) was specifically detected in the transgenic fish. We therefore conclude that the development of transgenic fish lines with these fatty acid-metabolizing enzymes could be a powerful tool for manipulating fatty acid metabolic pathways in fish.

Origin of high fidelity in target-sequence recognition by PNA-Ce(IV)/EDTA combinations as site-selective DNA cutters.

Double-duplex invasion of pseudocomplementary peptide nucleic acid (pcPNA) is one of the most important strategies for recognizing a specific site in double-stranded DNA (Proc. Natl. Acad. Sci. U.S.A. 1999, 96, 11804-11808). This strategy has recently been used to develop artificial restriction DNA cutters (ARCUTs) for site-selective scission of double-stranded DNA, in which a hot spot formed by double-duplex invasion of PNA was hydrolyzed by Ce(IV)/EDTA (Nat. Protoc. 2008, 3, 655-662). The present paper shows how and where the target sequence in double-stranded DNA is recognized by the PNA-Ce(IV)/EDTA combinations for site-selective scission. The mismatch-recognizing activities in both the invasion process and the whole scission process are evaluated. When both pcPNA additives are completely complementary to each strand of the DNA, site-selective scission is the most efficient, as expected. Upon exchange of one DNA base pair at the invasion site with another base pair, which introduces mismatches between the pcPNAs and the DNA, the site-selective scission by the ARCUT is notably diminished. Mismatches in (or near) the central double-invasion region are especially fatal, showing that Watson-Crick pairings of the DNA bases in this region with the pcPNA strands are essential for precise recognition of the target sequence. Both gel-shift assays and melting temperature measurements on the double-duplex invasion process have confirmed that the fidelity in this process primarily governs the fidelity of the DNA scission. According to these systematic analyses, the typical ARCUT involving two 15-mer pcPNAs precisely recognizes 14-16 base pairs in substrate DNA. This remarkable fidelity is accomplished at rather high salt concentrations that are similar to the values in cells.

Artificial restriction DNA cutter for site-selective scission of double-stranded DNA with tunable scission site and specificity.

The artificial restriction DNA cutter (ARCUT) method to cut double-stranded DNA at designated sites has been developed. The strategy at the base of this approach, which does not rely on restriction enzymes, is comprised of two stages: (i) two strands of pseudo-complementary peptide nucleic acid (pcPNA) anneal with DNA to form 'hot spots' for scission, and (ii) the Ce(IV)/EDTA complex acts as catalytic molecular scissors. The scission fragments, obtained by hydrolyzing target phosphodiester linkages, can be connected with foreign DNA using DNA ligase. The location of the scission site and the site-specificity are almost freely tunable, and there is no limitation to the size of DNA substrate. This protocol, which does not include the synthesis of pcPNA strands, takes approximately 10 d to complete. The synthesis and purification of the pcPNA, which are covered by a related protocol by the same authors, takes an additional 7 d, but pcPNA can also be ordered from custom synthesis companies if necessary.

Chemical modification of Ce(IV)/EDTA-based artificial restriction DNA cutter for versatile manipulation of double-stranded DNA.

A monophosphate group was attached to the terminus of pseudo-complementary peptide nucleic acid (pcPNA), and two of thus modified pcPNAs were combined with Ce(IV)/EDTA for site-selective hydrolysis of double-stranded DNA. The site-selective DNA scission was notably accelerated by this chemical modification of pcPNAs. These second-generation artificial restriction DNA cutters (ARCUTs) differentiated the target sequence so strictly that no scission occurred even when only one DNA base-pair was altered to another. By using two of the activated ARCUTs simultaneously, DNA substrate was selectively cut at two predetermined sites, and the desired fragment was clipped and cloned. The DNA scission by ARCUT was also successful even when the target site was methylated by methyltransferase and protected from the corresponding restriction enzyme. Furthermore, potentiality of ARCUT for manipulation of huge DNA has been substantiated by site-selective scission of genomic DNA of Escherichia coli (composed of 4,600,000 bp) at the target site. All these results indicate promising applications of ARCUTs for versatile purposes.

Highly efficient strand invasion by peptide nucleic acid bearing optically pure lysine residues in its backbone.

Chiral PNA monomers (PNA = peptide nucleic acid), in which nucleobases are attached to N-(aminoethyl)-D-lysine, were introduced to PNAs bearing pseudo-complementary nucleobases (2,6-diaminopurine and 2-thiouracil). When these highly cationic PNAs targeted double-stranded DNA, they invaded there much more efficiently than conventional pseudo-complementary PNAs composed of achiral PNA monomers. Although introduction of N-(aminoethyl)-D-lysine backbone was effective for promotion of strand invasion, L-isomer never promote it. Simple incorporation of lysine groups to the termini of PNA was also ineffective, indicating that introduction of positive charges into PNA backbone is important. Even highly G-C rich sequence, which conventional pseudo-complementary PNAs never invade, was successfully targeted based on this strategy.

Highly active artificial restriction enzyme composed of Ce(IV)/EDTA and PNA bearing phosphate group--relationship between the promotion by phosphate and the structure of invasion complex.

Recently, we developed artificial restriction DNA cutter (ARCUT) composed of pseudo-complementary peptide nucleic acid (pcPNA) and Ce(IV)/EDTA complex (EDTA = ethylenediamine-N,N,N',N'-tetraacetate). Here we promoted the site-selective hydrolysis by attaching phosphate groups to the pcPNAs. The promotion by the phosphates increased with decreasing length of the gap-like site. Furthermore, the scission was successful even when phosphate groups were introduced to 0 base-gap system.

Rapid site-selective hydrolysis of double-stranded DNA by use of Ce(IV)/EDTA and PNA bearing phosphate group.

In order to hydrolyze double-stranded DNA efficiently at the target site, two pseudo-complementary peptide nucleic acids (pcPNAs) bearing phosphate group were combined with Ce(IV)/EDTA complex (EDTA = ethylenediamine-N,N,N',N'-tetraacetate). The phosphate groups as metal-binding ligands were placed near the target site, and concentrated the Ce(IV) complex thereto. As the result, the site-selective hydrolysis was notably promoted, compared with the scission by the cutters involving unmodified pcPNAs.

Construction of chimera protein by using artificial restriction DNA cutter.

We have already developed artificial restriction DNA cutter (ARCUT), which can hydrolyze double-stranded DNA site-selectively, by using Ce(IV)/EDTA in combination with two pseudo-complementary peptide nucleic acids (pcPNAs). Here, ARCUT was used to prepare a chimera protein. The gene for WW-domain containing oxidoreductase (WWOX) was clipped off by ARCUT just before its stop codon, and ligated with the gene for enhanced green fluorescent protein (EGFP). Conventional PCR for insertion of restriction enzyme site is never required.

Site-selective and hydrolytic two-strand scission of double-stranded DNA using Ce(IV)/EDTA and pseudo-complementary PNA.

By combining Ce(IV)/EDTA with two pseudo-complementary peptide nucleic acids (pcPNAs), both strands in double-stranded DNA were site-selectively hydrolyzed at the target site. Either plasmid DNA (4361 bp) or its linearized form was used as the substrate. When two pcPNAs invaded into the double-stranded DNA, only the designated portion in each of the two strands was free from Watson-Crick base pairing with the counterpart DNA or the pcPNA. Upon the treatment of this invasion complex with Ce(IV)/EDTA at 37 degrees C and pH 7.0, both of these single-stranded portions were selectively hydrolyzed at the designated site, resulting in the site-selective two-strand scission of the double-stranded DNA. Furthermore, the hydrolytic scission products were successfully connected with foreign double-stranded DNA by using ligase. The potential of these artificial systems for manipulation of huge DNA has been indicated.

Combination of S1 nuclease and PNA for site-selective hydrolysis of double-stranded DNA. Comparison with the site-selective hydrolysis using Ce(IV)/EDTA.

The potential of the combination of SI nuclease and pseudo-complementary PNA (pcPNA) for site-selective scission of double-stranded DNA has been investigated. Through strand invasion of two pcPNAs, single-stranded portions were formed in both strands of substrate DNA. In the initial stage of the enzymatic digestion, two scission fragments were obtained due to the hydrolysis at these two gap-like sites. On prolonged reactions, however, these products (as well as the substrate DNA) were further digested to smaller fragments. Under the conditions employed here, only Ce(IV)/EDTA is available for the preparation of desired fragments from double-stranded DNA.

Manipulation of double-stranded DNA by artificial restriction enzyme composed of Ce(IV)/EDTA and PNA.

Through the invasion of pseudo-complementary PNA (pePNA) to double-stranded DNA, gap-like structures were formed at predetermined sites in both strands of PBR322 plasmid DNA. These gap-like sites were selectively hydrolyzed by Ce(IV)/EDTA complex, and two designed fragments were obtained. Furthermore, the scission fragment by this artificial restriction enzyme was successfully ligated with foreign DNA.