New method for generating deletions and gene replacements in Escherichia coli.

We describe a method for generating gene replacements and deletions in Escherichia coli. The technique is simple and rapid and can be applied to most genes, even those that are essential. What makes this method unique and particularly effective is the use of a temperature-sensitive pSC101 replicon to facilitate the gene replacement. The method proceeds by homologous recombination between a gene on the chromosome and homologous sequences carried on a plasmid temperature sensitive for DNA replication. Thus, after transformation of the plasmid into an appropriate host, it is possible to select for integration of the plasmid into the chromosome at 44 degrees C. Subsequent growth of these cointegrates at 30 degrees C leads to a second recombination event, resulting in their resolution. Depending on where the second recombination event takes place, the chromosome will either have undergone a gene replacement or retain the original copy of the gene. The procedure can also be used to effect the transfer of an allele from a plasmid to the chromosome or to rescue a chromosomal allele onto a plasmid. Since the resolved plasmid can be maintained by selection, this technique can be used to generate deletions of essential genes.     

Detection of differential gene copy number using denaturing high performance liquid chromatography

Genomic rearrangements leading to deletion or duplication of gene(s) resulting in alterations in gene copy number underlie the molecular lesion in several genetic disorders. Methods currently used to determine gene copy number including real time PCR, southern hybridization, fluorescence in situ hybridization, densitometric scanning of PCR product etc. have certain disadvantages and are also expensive and time consuming. Herein, we describe a simple and rapid method to assess gene copy number using denaturing high performance liquid chromatography (dHPLC). We used X chromosome genes as model to compare the gene copy numbers present on this chromosome in males and females. DNA from these samples were amplified by biplex PCR using primer pairs specific for X chromosome genes only (target gene) and for genes present on both X and Y chromosomes (internal control). Amplified products were analyzed using HPLC under non-denaturing conditions. The ratio of peak areas (target gene/internal control) of the amplified products was approximately twice in female samples than male samples (p < 0.001) demonstrating that the differential gene copy number can be easily detected using this method. This method can potentially be used for diagnostic purpose where the need is to distinguish samples based on the differential gene copy numbers.     

Introduction of single-copy sequences into the chromosome of Escherichia coli: application to gene and operon fusions.

We have developed a general method for the introduction of any cloned sequence into the chromosome of Escherichia coli. This method employs an Hfr strain which carries a fragment of bla (the pBR322 gene imparting ampicillin resistance) between lacI and lacZ. Plasmid-borne inserts which are flanked by sequences from bla and lacZ can be introduced at this locus by homologous recombination. The isolation of recombinants is enhanced by selection for transfer of an integrated copy of the plasmid during conjugation. Once introduced into the chromosome, the inserted sequences can be transferred to other strains by conventional methods such as P1 transduction or conjugation. This method is suitable for the transfer of any cloned sequence to the chromosome and is particularly well suited to the construction of chromosomal gene and operon fusions with lacZ.     

Markerless gene replacement in Escherichia coli stimulated by a double-strand break in the chromosome.

A simple and efficient gene replacement method, based on the recombination and repair activities of the cell, was developed. The method permits the targeted construction of markerless deletions, insertions and point mutations in the Escherichia coli chromosome. A suicide plasmid, carrying the mutant allele and the recognition site of meganuclease I- Sce I, is inserted into the genome by homologous recombination between the mutant and the wild-type (wt) alleles. Resolution of this cointegrate by intramolecular recombination of the allele pair results in either a mutant or a wt chromosome which can be distinguished by allele-specific PCR screening. The resolution process is stimulated by introducing a unique double-strand break (DSB) into the chromosome at the I- Sce I site. Cleavage by the nuclease not only enhances the frequency of resolution by two to three orders of magnitude, but also selects for the resolved products. The DSB-stimulated gene replacement method can be used in recombination-proficient E.coli cells, does not require specific growth conditions, and is potentially applicable in other microorganisms. Use of the method was demonstrated by constructing a 17-bp and a 62-kb deletion in the MG1655 chromosome. Cleavage of the chromosome induces the SOS response but does not lead to an increased mutation rate.     

Chromosome-scale genetic mapping using a set of 16 conditionally stable Saccharomyces cerevisiae chromosomes

We have created a resource to rapidly map genetic traits to specific chromosomes in yeast. This mapping is done using a set of 16 yeast strains each containing a different chromosome with a conditionally functional centromere. Conditional centromere function is achieved by integration of a GAL1 promoter in cis to centromere sequences. We show that the 16 yeast chromosomes can be individually lost in diploid strains, which become hemizygous for the destabilized chromosome. Interestingly, most 2n - 1 strains endoduplicate and become 2n. We also demonstrate how chromosome loss in this set of strains can be used to map both recessive and dominant markers to specific chromosomes. In addition, we show that this method can be used to rapidly validate gene assignments from screens of strain libraries such as the yeast gene disruption collection.     

电子显微镜分离小鼠染色体的研究

本实验对小白鼠的骨髓细胞,制成电镜染色体样品,探索了利用电子显微镜所产生的高度聚焦的电子束,将目标染色体或梁色体处段与其他染色体或染色体片段分离,切割开的过程,检验了电子束分离,切割染色体的可行性和有效性,开发出了一套较为成熟的电子束分离,切割染色体的新技术或方法,使之成为染色体及基因研究的有效手段。     

A mini-Mu transposon-based method for multiple DNA fragment integration into bacterial genomes

A method for construction of bacterial strains with multiple DNA inserted into their chromosomes has been developed based on the mini-Mu transposon and FLP/FRT recombination. Exogenous DNA can be integrated by Mu transposition with an FRT cassette containing selection marker and conditional replicative origin (R6Kγori). Subsequently, with the introduction of a helper plasmid bearing gene of FLP recombinase, drug-resistant selection marker is excised from the chromosome. Cells cured of the helper plasmid can undergo the next cycle of transposition and excision of selection marker. Each cycle can add further foreign gene(s) to the chromosome. As an example, resistance genes of chloramphenicol, tetracycline, and gentamicin were successively integrated into the chromosome of Escherichia coli BW25113 by three cycles of insertion and excision as described above. This method proved to be simple and time-saving, which could be applicable to a variety of microorganisms.     

A targeted gene knockout in Drosophila

We previously described a method for targeted homologous recombination at the yellow gene of Drosophila melanogaster. Because only a single gene was targeted, further work was required to show whether the method could be extended to become generally useful for gene modification in Drosophila. We have now used this method to produce a knockout of the autosomal pugilist gene by homologous recombination between the endogenous locus and a 2.5-kb DNA fragment. This was accomplished solely by tracking the altered genetic linkage of an arbitrary marker gene as the targeting DNA moved from chromosome X or 2 to chromosome 3. The results indicate that this method of homologous recombination is likely to be generally useful for Drosophila gene targeting.     

A Novel Statistical Approach for Jointly Analyzing RNA-Seq Data from F1 Reciprocal Crosses and Inbred Lines

RNA sequencing (RNA-seq) not only measures total gene expression but may also measure allele-specific gene expression in diploid individuals. RNA-seq data collected from F₁ reciprocal crosses in mice can powerfully dissect strain and parent-of-origin effects on allelic imbalance of gene expression. In this article, we develop a novel statistical approach to analyze RNA-seq data from F₁ and inbred strains. Method development was motivated by a study of F₁ reciprocal crosses derived from highly divergent mouse strains, to which we apply the proposed method. Our method jointly models the total number of reads and the number of allele-specific reads of each gene, which significantly boosts power for detecting strain and particularly parent-of-origin effects. The method deals with the overdispersion problem commonly observed in read counts and can flexibly adjust for the effects of covariates such as sex and read depth. The X chromosome in mouse presents particular challenges. As in other mammals, X chromosome inactivation silences one of the two X chromosomes in each female cell, although the choice of which chromosome to be silenced can be highly skewed by alleles at the X-linked X-controlling element (Xce) and stochastic effects. Our model accounts for these chromosome-wide effects on an individual level, allowing proper analysis of chromosome X expression. Furthermore, we propose a genomic control procedure to properly control type I error for RNA-seq studies. A number of these methodological improvements can also be applied to RNA-seq data from other species as well as other types of next-generation sequencing data sets. Finally, we show through simulations that increasing the number of samples is more beneficial than increasing the library size for mapping both the strain and parent-of-origin effects. Unless sample recruiting is too expensive to conduct, we recommend sequencing more samples with lower coverage.     

Reciprocal chromosome painting shows that genomic rearrangement between rat and mouse proceeds ten times faster than between humans and cats.

Reciprocal chromosome painting between mouse and rat using complete chromosome probe sets of both species permitted us to assign the chromosomal homology between these rodents. The comparative gene mapping data and chromosome painting have a better than 90% correspondence. The reciprocal painting results graphically show that mouse and rat have strikingly different karyotypes. At least 14 translocations have occurred in the 10-20 million years of evolution that separates these two species. The evolutionary rate of chromosome translocations between these two rodents appears to be up to 10 times greater than that found between humans and cats, or between humans and chimpanzees, where over the last 5-6 million years just one translocation has occurred. Outgroup comparison shows that the mouse genome has incorporated at least three times the amount of interchromosomal rearrangements compared to the rat genome. The utility of chromosome painting was also illustrated by the assignment of two new chromosome homologies between rat and mouse unsuspected by gene mapping: between mouse 11 and rat 20 and between mouse 17 and rat 6. We conclude that reciprocal chromosome painting is a powerful method, which can be used with confidence to chart the genome and predict the chromosome location of genes. Reciprocal painting combined with gene mapping data will allow the construction of large-scale comparative chromosome maps between placental mammals and perhaps other animals.     

Construction of an ∼2 Mb contig in the region around 80 cM of Arabidopsis thaliana chromosome 2

A method for construction of bacterial artificial chromosome (BAC) contigs from a yeast artifical chromosome (YAC) physical map is described. An ∼2 Mb contig, consisting of two large BAC contigs linked by a small YAC, has been assembled in the region around 80 cM of Arabidopsis thaliana chromosome 2. Clones from this contig will facilitate gene isolation in the region and can be used directly as substrates for DNA sequencing.     

Integration of the delta-endotoxin gene of Bacillus thuringiensis into the chromosome of root-colonizing strains of pseudomonads using Tn5

The delta-endotoxin gene (tox) from Bacillus thuringiensis subsp. kurstaki HD-1 was cloned into Tn5 and the resulting Tn5-tox element transposed from a vector plasmid into the chromosome of six corn-root-colonizing strains of Pseudomonas fluorescens and Agrobacterium radiobacter. Chromosomal integration of the tox gene maximized stability and minimized the potential for horizontal transfer of the tox gene to other bacterial species. Expression of the tox gene was demonstrated by Western blot analysis and by toxicity against larvae of the tobacco hornworm (Manduca sexta). The method described illustrates how a given gene can be stably integrated into the chromosome of diverse bacterial species.     

A Mapping Method for SACCHAROMYCES CEREVISIAE Using rad52-Induced Chromosome Loss

Saccharomyces cerevisiae diploids homozygous for the rad52-1 mutation have previously been shown to lose chromosomes mitotically. Spontaneous events and events following low levels of X-ray or methyl methanesulfonate treatment result in monosomic diploids, whereas higher levels of treatment result in near haploidization. This rad52-1-dependent chromosome loss has been used to develop a new mapping method which can be used to assign a previously unmapped gene to a chromosome. Chromosome loss mapping can be done in either of two ways: if a diploid, homozygous for rad52-1 but heterozygous for a variety of other recessive markers, is constructed with an unmapped recessive mutation in coupling with known chromosomal markers, chromosome loss will result in the coordinate expression of the mutation and other recessive markers on the same chromosome; if, however, the diploid is constructed with the unmapped mutation in repulsion to chromosomal markers, then even haploidization will never result in the coordinate expression of the unmapped mutation and other markers on the same homologous chromosome pair--This mapping method and subsequent tetrad analyses have been used to locate hom6 on chromosome X, ade4 on chromosome XIII and cdc31 on chromosome XV and to demonstrate that met5, previously assigned to chromosome V, actually maps to chromosome X; the met- marker on chromosome V has been shown to be met6. GAL80 and SUP5, previously assigned to an unmapped fragment, have now been mapped to the right arm of chromosome XIII.     

Creation of a clone panel of fox x Chinese hamster somatic cell hybrids and chromosome mapping of genes for LDHA, LDHB, GPI, ESD, G6PD, HPRT, alpha-GALA in the silver fox

A clone panel of fox-hamster somatic cell hybrids which can be used for fox gene mapping was set up. Analysis of patterns of chromosome-enzyme segregation made it possible to assign gene GPI to chromosome 1, LDHA to chromosome 11, LDHB to chromosome 8, ESD to chromosome 6 and G6PD, HPRT, alpha-GALA to chromosome X.     

Human alpha-globin gene expression following chromosomal dependent gene transfer into mouse erythroleukemia cells.

We have used the genetic marker, adenine phosphoribosyl transferase (APRT), an enzyme known to be on human chromosome 16, to establish a method for the transfer of human α-globin genes into mouse erythroleukemia cells. Mouse erythroleukemia cells devoid of detectable levels of APRT were fused with fractions of human marrow enriched in human erythroid cells. The hybrid cells arising from this fusion were isolated in medium supplemented with aminopterin and thymidine, and used adenine as the sole purine source. This population of hybrid cells was dominated by cells (80%) in which human chromosome 16 was present. Human chromosomes 4, 5 and 6 were also found in these cells. The hybrid cells were then placed in medium supplemented with diaminopurine (DAP), which is lethal for cells containing APRT. Greater than 95% of the DAP-selected hybrid cells lacked human chromosome 16. Cytoplasmic RNA was extracted from the two hybrid cell populations and assayed by molecular hybridization for sequences coding for human α-globin. Carboxymethyl cellulose chromatography was used to study the level of synthesis of human a-globin in the hybrids. The original hybrid cell, which contained a high frequency of human chromosome 16, also contained high levels of human a-globin mRNA and human α-globin chains. Hybrid cells counter-selected in DAP and thus lacking human chromosome 16 were devoid of detectable levels of human APRT, human α-globin mRNA and human α-globin chains. This work shows that transfer of human chromosome 16 into the MEL cell is possible using a chromosomedependent, APRT-mediated method of gene transfer. Using this system in which expression of the human α-globin gene occurs, we were also able to confirm our earlier assignment of the human α-globin gene to human chromosome 16. This system may be of further use in identifying genetic elements governing expression of the human α-globin gene which can be carried with human chromosome 16 as it is donated to the mouse erythroleukemia cell by donor cells of different epigenotypes.     

Assignment of genes to the human X chromosome by the two-dimensional electrophoretic analysis of total cell proteins from rodent-human somatic cell hybrids.

The technique of two-dimensional (2-D) gel electrophoresis was sued to identify five human X-linked gene products in crude cell extracts of mouse-human and Chinese hamster-human somatic cell hybrids. The human origin of these five polypeptides was demonstrated by their comigration with human fibroblast proteins and their failure to comigrate with polypeptides in extracts from the mouse or hamster parental cells. All five polypeptides were present in extracts of rodent-human hybrids that contained a human X chromosome, but were not found in extracts of cells that lacked a human X chromosome. Chromosome analysis of the hybrid clones revealed that the human X chromosome is both necessary and sufficient for the expression of the five polypeptides, designated pX-24, pX-27, pX-37, pX-40, and pX-56. pX-56 can be identified as the human X-linked enzyme glucose-6-phosphate dehydrogenase (G6PD) (E.C.1.1.1.49), while polypeptides pX-24, pX-27, pX-37 and pX-40 have molecular properties unlike those of known human X-linked gene products. pX-24 appears to be a membrane-bound protein that maps to the distal portion of the long arm of the human X chromosome, while pX-27, pX-37, and pX-40 are soluble proteins that map to the proximal long arm or to the short arm of the human X chromosome. 2-D gel electrophoretic analysis of extracts from somatic cell hybrids provides a general method for identifying polypeptides in crude cell extracts coded for by any specific chromosome and can be used to study primary gene products not previously amenable to genetic analysis.     

Carrier detection of deletions in female relatives of X-linked disorders by non-isotopic in situ hybridisation.

Recent studies suggest that a non-isotopic in situ hybridisation (NISH) approach can be successfully employed to investigate the carrier status of female relatives in families of selected patients with Duchenne muscular dystrophy (DMD) or Hunter syndrome, whose diseases are due to a specific X chromosome deletion. Whilst the majority of metaphase spreads from normal females show specific hybridisation signals on both X chromosomes when tested with either dystrophin or Hunter gene-derived probes, only one X chromosome in each metaphase spread will show the relevant hybridisation complex in female carriers of deletions involving the dystrophin or Hunter gene. Thus, the NISH method can be a valuable diagnostic tool for the detection of the carrier status of female relatives of patients with X chromosome deletions.     

Simultaneous quantitative and allele-specific expression analysis with real competitive PCR

Background  

For a diploid organism such as human, the two alleles of a particular gene can be expressed at different levels due to X chromosome inactivation, gene imprinting, different local promoter activity, or mRNA stability. Recently, imbalanced allelic expression was found to be common in human and can follow Mendelian inheritance. Here we present a method that employs real competitive PCR for allele-specific expression analysis.     

In situ localization of the evolutionary conserved Cpy/Cty gene in the subfamily Chironominae (Chironomidae, Diptera): establishment of chromosomal homologies

The homologous sites on the salivary gland chromosomes of 13 species from three genera: Chironomus, Glyptotendipes, Kiefferulus have been mapped by means of fluorescent in situ hybridization using the evolutionary conserved gene Cpy/Cty (clone Cla1.1). In all species of genus Chironomus and genus Kiefferulus , the Cty/Cpy gene is located on arm F of chromosome EF. The relocation of the gene among the species of genus Chironomus can be done by simple or complex homozygous inversions which occurred during the divergent evolution of the chromosome of the species. In the genus Glyptotendipes , the Cty/Cpy gene was localized in arm E of chromosome EF. Since the banding patterns of salivary gland chromosomes between genus Chironomus and genus Glyptotendipes cannot be compared directly, in situ hybridization with clone of conservative gene was performed to be established some homologous chromosomes. The results obtained indicate that the chromosome arm F of Chironomus and chromosome arm E of Glyptotendipes may be homologous.     

Lactococcal plasmid pWV01 as an integration vector for lactococci.

A Bacillus subtilis strain was constructed that contained the repA gene of the lactococcal plasmid pWVO1 in its chromosome. This strain was used to construct the pWVO1-based integration vector pINT1, which lacked the repA gene. The 3.6-kb plasmid pINT1 was not able to replicate in Lactococcus lactis MG1363 but integrated into the chromosome via a Campbell-like mechanism when a lactococcal chromosomal DNA fragment was incorporated in the plasmid. Transformants were obtained that carried between one and four plasmid copies, in stable tandem arrangement on the chromosome. The results indicate that pWVO1 can be used for the development of a Campbell-like integration system fully derived of lactococcal DNA, with which stable multiple copies of any gene of interest can be generated in the lactococcal chromosome.