Codon cassette mutagenesis: a general method to insert or replace individual codons by using universal mutagenic cassettes.

We describe codon cassette mutagenesis, a simple method of mutagenesis that uses universal mutagenic cassettes to deposit single codons at specific sites in double-stranded DNA. A target molecule is first constructed that contains a blunt, double-strand break at the site targeted for mutagenesis. A double-stranded mutagenic codon cassette is then inserted at the target site. Each mutagenic codon cassette contains a three base pair direct terminal repeat and two head-to-head recognition sequences for the restriction endonuclease Sapl, an enzyme that cleaves outside of its recognition sequence. The intermediate molecule containing the mutagenic cassette is then digested with Sapl, thereby removing most of the mutagenic cassette, leaving only a three base cohesive overhang that is ligated to generate the final insertion or substitution mutation. A general method for constructing blunt-end target molecules suitable for this approach is also described. Because the mutagenic cassette is excised during this procedure and alters the target only by introducing the desired mutation, the same cassette can be used to introduce a particular codon at all target sites. Each cassette can deposit two different codons, depending on the orientation in which it is inserted into the target molecule. Therefore, a series of eleven cassettes is sufficient to insert all possible amino acids at any constructed target site. Thus codon cassettes are 'off-the-shelf' reagents, and this methodology should be a particularly useful and inexpensive approach for subjecting multiple different positions in a protein sequence to saturation mutagenesis.     

Recognition sites of eukaryotic DNA topoisomerase I: DNA nucleotide sequencing analysis of topo I cleavage sites on SV40 DNA.

Eukaryotic DNA topoisomerase I introduces transient single-stranded breaks on double-stranded DNA and spontaneously breaks down single-stranded DNA. The cleavage sites on both single and double-stranded SV40 DNA have been determined by DNA sequencing. Consistent with other reports, the eukaryotic enzymes, in contrast to prokaryotic type I topoisomerases, links to the 3'-end of the cleaved DNA and generates a free 5'-hydroxyl end on the other half of the broken DNA strand. Both human and calf enzymes cleave SV40 DNA at the identical and specific sites. From 827 nucleotides sequenced, 68 cleavage sites were mapped. The majority of the cleavage sites were present on both double and single-stranded DNA at exactly the same nucleotide positions, suggesting that the DNA sequence is essential for enzyme recognition. By analyzing all the cleavage sequences, certain nucleotides are found to be less favored at the cleavage sites. There is a high probability to exclude G from positions -4, -2, -1 and +1, T from position -3, and A from position -1. These five positions (-4 to +1 oriented in the 5' to 3' direction) around the cleavage sites must interact intimately with topo I and thus are essential for enzyme recognition. One topo I cleavage site which shows atypical cleavage sequence maps in the middle of a palindromic sequence near the origin of SV40 DNA replication. It occurs only on single-stranded SV40 DNA, suggesting that the DNA hairpin can alter the cleavage specificity. The strongest cleavage site maps near the origin of SV40 DNA replication at nucleotide 31-32 and has a pentanucleotide sequence of 5'-TGACT-3'.     

Co-transformation of gene expression cassettes via particle bombardment to generate safe transgenic plant without any unwanted DNA

The presence of resistant selectable marker genes and other added DNAs such as the vector backbone sequence in transgenic plant might be an unpredictable hazard to the ecosystem as well as to human health, which have affected the safe assessment of transgenic plants seriously. Using minimal gene expression cassette (containing the promoter, coding region, and terminator) without vector backbone sequence for particle bombardment is the new trend of plant genetic transformation. In the present paper, we co-transformed the selectable marker bar gene cassette and non-selected cecropinB gene cassette into rice (Oryza sativa L.) by particle bombardment, then eliminated the selectable marker bar gene in R₁ generation applying the hereditary segregation strategy and attained two safe transgenic plants only harboring cecropinB gene cassettes without any superfluous DNA. This is the fist report indicating that the combination of minimal gene cassettes transformation with the co-transformation and segregation strategy can generate selectable marker-free transgenic plants, which will promote the advancement in plant genetic engineering greatly.     

Universal restriction endonucleases: designing novel cleavage specificities by combining adapter oligodeoxynucleotide and enzyme moieties

Class IIS restriction endonucleases cleave double-stranded (ds) DNA at precise distances from their recognition sequences. A method is proposed which utilizes this separation between the recognition site and the cut site to allow a class IIS enzyme, e.g., FokI, to cleave practically any predetermined sequence by combining the enzyme with a properly designed oligodeoxynucleotide adapter. Such an adapter is constructed from the constant recognition site domain (a hairpin containing the ds sequence, e.g., GGATG CCTAC for FokI) and a variable, single-stranded (ss) domain complementary to the ss sequence to be cleaved (at 9 and 13 nucleotides on the paired strands from the recognition sequence in the example of FokI). The ss sequence designated to be cleaved could be provided by ss phage DNA (e.g., M13), gapped ds plasmids, or supercoiled ds plasmids that were alkali denatured and rapidly neutralized. Combination of all three components, namely the class IIS enzyme, the ss DNA target sequence, and the complementing adapter, would result in target DNA cleavage at the specific predetermined site. The target ss DNA could be converted to the precisely cleaved ds DNA by DNA polymerase, utilizing the adapter oligodeoxynucleotide as primer. This novel procedure represents the first example of changing enzyme specificity by synthetic design. A practically unlimited assortment of new restriction specificities could be produced. The method should have many specific and general applications when its numerous ramifications are exploited.     

Plasmid vectors for protein production, gene expression and molecular manipulations in Aspergillus niger

We constructed three sets of plasmids for use in Aspergillus niger. These plasmids were assembled using various combinations of a series of modular DNA cassettes that included a selectable marker, pyrG, derived from Aspergillus nidulans; two promoter regions for directing protein expression; a cassette derived from the AMA1 replicator sequence to support autonomous replication; and a reporter gene based on the A. niger lacA gene. One set included integrating and autonomously replicating plasmids for the expression of homologous and heterologous proteins. The second was a set of autonomously replicating plasmids, with a secreted beta-galactosidase encoding reporter gene, for studying gene regulation events. The third set included pyrG-derived gene-blaster cassettes suitable for genome manipulation by targeted gene replacement.     

pSAT RNA interference vectors: a modular series for multiple gene down-regulation in plants

RNA interference (RNAi) is a powerful tool for functional gene analysis, which has been successfully used to down-regulate the levels of specific target genes, enabling loss-of-function studies in living cells. Hairpin (hp) RNA expression cassettes are typically constructed on binary plasmids and delivered into plant cells by Agrobacterium-mediated genetic transformation. Realizing the importance of RNAi for basic plant research, various vectors have been developed for RNAi-mediated gene silencing, allowing the silencing of single target genes in plant cells. To further expand the collection of available tools for functional genomics in plant species, we constructed a set of modular vectors suitable for hpRNA expression under various constitutive promoters. Our system allows simple cloning of the target gene sequences into two distinct multicloning sites and its modular design provides a straightforward route for replacement of the expression cassette's regulatory elements. More importantly, our system was designed to facilitate the assembly of several hpRNA expression cassettes on a single plasmid, thereby enabling the simultaneous suppression of several target genes from a single vector. We tested the functionality of our new vector system by silencing overexpressed marker genes (green fluorescent protein, DsRed2, and nptII) in transgenic plants. Various combinations of hpRNA expression cassettes were assembled in binary plasmids; all showed strong down-regulation of the reporter genes in transgenic plants. Furthermore, assembly of all three hpRNA expression cassettes, combined with a fourth cassette for the expression of a selectable marker, resulted in down-regulation of all three different marker genes in transgenic plants. This vector system provides an important addition to the plant molecular biologist's toolbox, which will significantly facilitate the use of RNAi technology for analyses of multiple gene function in plant cells.     

Human immunodeficiency virus integrase protein requires a subterminal position of its viral DNA recognition sequence for efficient cleavage.

Retroviral integration requires cis-acting sequences at the termini of linear double-stranded viral DNA and a product of the retroviral pol gene, the integrase protein (IN). IN is required and sufficient for generation of recessed 3' termini of the viral DNA (the first step in proviral integration) and for integration of the recessed DNA species in vitro. Human immunodeficiency virus type 1 (HIV-1) IN, expressed in Escherichia coli, was purified to near homogeneity. The substrate sequence requirements for specific cleavage and integration of retroviral DNA were studied in a physical assay, using purified IN and short duplex oligonucleotides that correspond to the termini of HIV DNA. A few point mutations around the IN cleavage site substantially reduced cleavage; most other mutations did not have a drastic effect, suggesting that the sequence requirements are limited. The terminal 15 bp of the retroviral DNA were demonstrated to be sufficient for recognition by IN. Efficient specific cutting of the retroviral DNA by IN required that the cleavage site, the phosphodiester bond at the 3' side of a conserved CA-3' dinucleotide, be located two nucleotides away from the end of the viral DNA; however, low-efficiency cutting was observed when the cleavage site was located one, three, four, or five nucleotides away from the terminus of the double-stranded viral DNA. Increased cleavage by IN was detected when the nucleotides 3' of the CA-3' dinucleotide were present as single-stranded DNA. IN was found to have a strong preference for promoting integration into double-stranded rather than single-stranded DNA.     

Catalytic antisense RNAs produced by incorporating ribozyme cassettes into cDNA.

A simple strategy is described for the generation of catalytic hammerhead-type ribozymes (Rz) that can be used as highly specific endoribonucleases to cleave a particular target RNA. The technique requires that a cloned cDNA fragment is available which encodes at least a part of the target RNA. About 25 different restriction recognition sequences can be utilized to incorporate specifically designed DNA cassettes into the cDNA. Besides some nucleotides which are specific for a certain restriction site, the DNA cassettes contain a sequence corresponding to the catalytic domain of the hammerhead Rz and, optionally, selectable marker genes, that are removable. The resulting recombinant DNA constructs permit the in vitro and in vivo synthesis of novel 'catalytic antisense RNAs' or 'antisense Rz (Az)', which combine two features: (i) they bind like antisense RNA to their specific substrate RNA, and (ii) they cleave their target as hammerhead Rz do. The utility of the strategy to generate Rz was demonstrated experimentally by incorporating a synthetic SalI-specific DNA ribozyme (Rz) cassette into a unique SalI site of a cloned cDNA fragment of plum pox virus (PPV), which is a single-stranded positive sense plant RNA virus, belonging to the group of potyviruses. The resulting Az constructs delivered Az that were directed against the PPV (+) or (-) RNA, respectively, which cleaved their corresponding target RNAs in the expected manner. Besides the synthetic Rz cassette, a comparable SalI-specific Rz cassette, that had been prepared from a specifically designed plasmid and that contained the tet gene inserted into the sequence of the catalytic domain of the Rz, was also incorporated into the SalI site of the PPV cDNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

An MboII/FokI trimming plasmid allowing consecutive cycles of precise 1- to 12-base-pair deletions in cloned DNA

A novel trimming plasmid has been designed which allows, in a preprogrammed fashion, the precise deletion of up to 12 bp per cleavage cycle, from one end of a cloned fragment. The plasmid, which carries the dhfr gene, contains unique recognition sites for two class-IIS restriction enzymes, MboII and FokI, which are arranged in the form of a cassette, so that consecutive cleavages with these endonucleases, followed by blunting with mung bean nuclease (MB), will precisely delete 12 bp of adjacent cloned DNA. When either MboII or FokI is used alone (followed by MB), 1 or 4 bp are removed, respectively. The final step in the trimming cycle is religation of the plasmid with T4 ligase. After required number of cycles, plasmids were transformed into Escherichia coli C600, and transformants selected by resistance to trimethoprim. Since the MboII/FokI cassette remains intact during these operations, one can repeat the cycle, consisting of cleaving, MB blunting and religation, several times, each time removing up to 12 bp from the cloned target DNA. Examples are provided of one-, two- and three-cycle trimmings.     

Construction of a new universal vector for insertional mutagenesis by homologous recombination

We describe here the construction of a vector (pSSC-9) which can be used for the insertional mutagenesis of any gene for which genomic sequences have been cloned. This vector contains a neomycin-resistance-encoding gene (neo^R) which is driven by a modified thymidine kinase (tk) promoter for positive selection. Flanking neo^R are two tk genes driven by their own promoters for negative selection of nonhomologous insertions. The neo^R and tk cassettes are separated by four unique cloning sites on the right-hand side of the neo^R cassette and three unique sites on the left-hand side. The vector also includes two SfiI sites, one on each side of the tk cassettes, for the excision of the cloned genomic DNA fragments along with the selectable markers. Electroporation of pSSC-9 into mouse embryonic stem (ES) cells and cultured diploid mouse adrenal Y-1 cells conferred resistance to G418 and sensitivity to ganciclovir in both cell lines. These results illustrate the expression of the positive and negative selectable markers in two different cell lines and thus suggest that the vector could be used in ES cells, as well as in cultured somatic cells.     

High frequency vector-mediated transformation and gene replacement in Tetrahymena.

Recently, we developed a mass DNA-mediated transformation technique for the ciliated protozoan Tetrahymena thermophila that introduces transforming DNA by electroporation into conjugating cells. Other studies demonstrated that a neomycin resistance gene flanked by Tetrahymena H4-I gene regulatory sequences transformed Tetrahymena by homologous recombination within the H4-I locus when microinjected into the macronucleus. We describe the use of conjugant electrotransformation (CET) for gene replacement and for the development of new independently replicating vectors and a gene cassette that can be used as a selectable marker in gene knockout experiments. Using CET, the neomycin resistance gene flanked by H4-I sequences transformed Tetrahymena, resulting in the replacement of the H4-I gene or integrative recombination of the H4-I/neo/H4-I gene (but not vector sequences) in the 5' or 3' flanking region of the H4-I locus. Gene replacement was obtained with non-digested plasmid DNA but releasing the insert increased the frequency of replacement events about 6-fold. The efficiency of transformation by the H4-I/neo/H4-I selectable marker was unchanged when a single copy of the Tetrahymena rDNA replication origin was included on the transforming plasmid. However, the efficiency of transformation using CET increased greatly when a tandem repeat of the replication origin fragment was used. This high frequency of transformation enabled mapping of the region required for H4-I promoter function to within 333 bp upstream of the initiator ATG. Similarly approximately 300 bp of sequence downstream of the translation terminator TGA of the beta-tubulin 2 (BTU2) gene could substitute for the 3' region of the H4-I gene. This hybrid H4-I/neo/BTU2 gene did not transform Tetrahymena when subcloned on a plasmid lacking an origin of replication, but did transform at high frequency on a two origin plasmid. Thus, the H4-I/neo/BTU2 cassette is a selectable marker that can be used for gene knockout in Tetrahymena. As a first step toward constructing a vector suitable for cloning genes by complementation of mutations in Tetrahymena, we also demonstrated that the vector containing 2 origins and the H4-I/neo/BTU2 cassette can co-express a gene encoding a cycloheximide resistant ribosomal protein.     

FokI method of gene synthesis

An accurate, fast and simple method is presented for synthesis of a gene, or any DNA fragment with a defined sequence. The method is based on the observation that large (approx. 100 bp long) inserts can be cloned into a plasmid using a technique of oligodeoxynucleotide (oligo)-directed double-strand (ds) break repair. The procedure involves transformation of Escherichia coli with a denatured mixture of an insert-carrying oligo and linearized plasmid DNA [Mandecki, Proc. Natl. Acad. Sci. USA 83 (1986) 7177-7181]. The nucleotide (nt) sequences are inserted between two FokI restriction nuclease sites in one of four pUC-derived plasmids. Since FokI makes a staggered ds break at a DNA site 9 and 13 nt away from its recognition site, upon cleavage of the plasmid DNA with FokI, a restriction fragment is liberated that by design contains unique 4-nt-long 5'-protruding ends. The uniqueness of ends permits efficient and directed simultaneous ligation of several restriction fragments to form a gene. The method offers flexibility due to the modular-type assembly and does not require any restriction sites within the constructed gene. The sequence error rate is low: about one error per 4000 bp of DNA cloned. Synthetic DNA for only one DNA strand needs to be provided. The method was applied to the synthesis of a gene fragment encoding the N-terminal 143 amino acid residues of the human immunodeficiency virus transmembrane protein (p41).     

M.FokI methylates adenine in both strands of its asymmetric recognition sequence

M.FokI, a type-IIS modification enzyme from Flavobacterium okeanokoites, was purified, and its activity was characterized in vitro. The enzyme was found to be a DNA-adenine methyltransferase and to methylate both strands of the asymmetric FokI recognition sequence: (formula; see text) M.FokI does not methylate single-stranded DNA, nor does it methylate double-stranded DNA at sequences other than FokI sites.     

FokI requires two specific DNA sites for cleavage

FokI is a bipartite restriction endonuclease that recognizes a non-palindromic DNA sequence, and then makes double-stranded cuts outside of that sequence to leave a 5' overhang. Earlier kinetic and crystallographic studies suggested that FokI might function as a dimer. Here, we show, using dynamic light-scattering, gel-filtration and analytical ultracentrifugation, that FokI dimerizes only in the presence of divalent metal ions. Furthermore, analysis of the DNA-bound complex reveals that two copies of the recognition sequence are incorporated into the dimeric complex and that formation of this complex is essential for full activation of cleavage. These results have broad implications for the mechanism by which monomeric type II endonucleases achieve high fidelity.     

Structural analysis of the heterodimeric type IIS restriction endonuclease R.BspD6I acting as a complex between a monomeric site-specific nickase and a catalytic subunit

The heterodimeric restriction endonuclease R.BspD6I from Bacillus species D6 recognizes a pseudosymmetric sequence and cuts both DNA strands outside the recognition sequence. The large subunit, Nt.BspD6I, acts as a type IIS site-specific monomeric nicking endonuclease. The isolated small subunit, ss.BspD6I, does not bind DNA and is not catalytically active. We solved the crystal structures of Nt.BspD6I and ss.BspD6I at high resolution. Nt.BspD6I consists of three domains, two of which exhibit structural similarity to the recognition and cleavage domains of FokI. ss.BspD6I has a fold similar to that of the cleavage domain of Nt.BspD6I, each containing a PD-(D/E)XK motif and a histidine as an additional putative catalytic residue. In contrast to the DNA-bound FokI structure, in which the cleavage domain is rotated away from the DNA, the crystal structure of Nt.BspD6I shows the recognition and cleavage domains in favorable orientations for interactions with DNA. Docking models of complexes of Nt.BspD6I and R.BspD6I with cognate DNA were constructed on the basis of structural similarity to individual domains of FokI, R.BpuJI and HindIII. A three-helix bundle forming an interdomain linker in Nt.BspD6I acts as a rigid spacer adjusting the orientations of the spatially separated domains to match the distance between the recognition and cleavage sites accurately.     

Inhibition of the restriction endonuclease BanII using modified DNA substrates. Determination of phosphate residues critical for the formation of an active enzyme-DNA complex

The restriction endonuclease BanII catalyzes the cleavage of double-stranded DNA and recognizes the degenerate sequence 5'-GPuGCPyC-3'. The poly-linker of M13mp18 contains one such sequence, 5'-GAGCTC-3'. The three other possible sites recognized by the enzyme were prepared by site-directed muta-genesis. The substitution of phosphate groups by phosphorothioate residues at some positions within the various recognition sites had relatively little effect on the rate of cleavage of the DNA. However, when the DNA contained a phosphorothioate group at the site of cleavage the rate of linearization of the DNA was decreased by a factor of 9. Interestingly, DNA which contained an additional phosphorothioate internucleotidic linkage immediately 3'-outside the recognition site could not be linearized by the enzyme. The results indicate that an important contact between enzyme and substrate is perturbed by the presence of the sulfur atom at this position.     

The bacteriophage T4 insertion/substitution vector system. A method for introducing site-specific mutations into the virus chromosome

A bacteriophage T4 insertion/substitution vector system has been developed as a means of introducing in vitro generated mutations into the T4 chromosome. The insertion/substitution vector is a 2638-base pair plasmid containing the pBR322 origin of replication and ampicillin resistance determinant, a T4 gene 23 promoter/synthetic supF tRNA gene fusion, and a polylinker with eight unique restriction enzyme recognition sites. A T4 chromosomal "target" DNA sequence is cloned into this vector and mutated by standard recombinant DNA techniques. Escherichia coli cells containing this plasmid are then infected with T4 bacteriophage that carry amber mutations in two essential genes. The plasmid integrates into the T4 chromosome by recombination between the plasmid-borne T4 target sequence and its homologous chromosomal counterpart. The resulting phage, termed "integrants," are selectable by the supF-mediated suppression of their two amber mutations. Thus, although the integrants comprise 1-3% or less of the total phage progeny, growth on a nonsuppressing host permits their direct selection. The pure integrant phage can be either analyzed directly for a possible mutant phenotype or transferred to nonselective growth conditions. In the latter case, plasmid-free phage segregants rapidly accumulate due to homologous recombination between the duplicated target sequences surrounding the supF sequence in each integrant chromosome. A major fraction of these segregants will retain the in vitro generated mutation within their otherwise unchanged chromosomes and are isolated as stable mutant bacteriophage. The insertion/substitution vector system thereby allows any in vitro mutated gene to be readily substituted for its wild-type counterpart in the bacteriophage T4 genome.     

选择标记可去除的植物高效表达载体的构建

在常用的植物组成型表达载体pBI121的选择标记基因NPTII两侧插入同向的lox位点并用多克隆位点(MCS)取代了GUS基因序列,构建了NPTII基因可被去除的和可插入目的基因的通用植物表达载体pBI121-lox-MCS。替换pBI121-lox-MCS中驱动目的基因表达的35S启动子,可构建成一系列具有其他表达特性的植物表达载体,如本文描述的韧皮部特异表达载体pBdENP-lox-MCS。为方便地筛选去除选择标记基因的转基因植物,还构建了绿色荧光蛋白(GFP)表达框与NPTII表达框连锁的pBI121-gfp-lox-MCS载体。上述植物表达载体可广泛应用于培育选择标记可去除的转基因植物。     

An EM view of the FokI synaptic complex by single particle analysis

FokI is a type IIS restriction endonuclease that recognizes the 5'-GGATG-3' sequence and cleaves non-specifically at 9 and 13 base-pairs away on the top and bottom strands, respectively, to produce a 5' overhang. FokI is a bipartite endonuclease with separate recognition and cleavage domains. Because of its bipartite nature, FokI has received considerable interest in generating chimeric nucleases for use in biotechnology, and recently as possible therapeutic agents in gene therapy by initiating homologous gene recombination and repair. Here we show, using single-particle electron microscopic studies, that the FokI active complex prefers a single conformation in which the subunits are arranged in a doughnut shape complex with protein-protein and possibly protein-DNA interactions stabilizing the cleavage complex. Our electron microscopy (EM) model provides new insights into the activation mechanism of FokI and how non-specific cleavage is avoided.