Site-directed, recombination-mediated mutagenesis of a complex gene locus

Module-based construction of plasmids for chromosomal integration of the fission yeast Schizosaccharomyces pombe

Integration of an external gene into a fission yeast chromosome is useful to investigate the effect of the gene product. An easy way to knock-in a gene construct is use of an integration plasmid, which can be targeted and inserted to a chromosome through homologous recombination. Despite the advantage of integration, construction of integration plasmids is energy- and time-consuming, because there is no systematic library of integration plasmids with various promoters, fluorescent protein tags, terminators and selection markers; therefore, researchers are often forced to make appropriate ones through multiple rounds of cloning procedures. Here, we establish materials and methods to easily construct integration plasmids. We introduce a convenient cloning system based on Golden Gate DNA shuffling, which enables the connection of multiple DNA fragments at once: any kind of promoters and terminators, the gene of interest, in combination with any fluorescent protein tag genes and any selection markers. Each of those DNA fragments, called a ‘module’, can be tandemly ligated in the order we desire in a single reaction, which yields a circular plasmid in a one-step manner. The resulting plasmids can be integrated through standard methods for transformation. Thus, these materials and methods help easy construction of knock-in strains, and this will further increase the value of fission yeast as a model organism.

Rapid, efficient and precise allele replacement in the fission yeast Schizosaccharomyces pombe

Gene targeting provides a powerful tool to modify endogenous loci to contain specific mutations, insertions and deletions. Precise allele replacement, with no other chromosomal changes (e.g., insertion of selectable markers or heterologous promoters), maintains physiologically relevant context. Established methods for precise allele replacement in fission yeast employ two successive rounds of transformation and homologous recombination and require genotyping at each step. The relative efficiency of homologous recombination is low and a high rate of false positives during the second round of gene targeting further complicates matters. We report that pop-in, pop-out allele replacement circumvents these problems. We present data for 39 different allele replacements, involving simple and complex modifications at seven different target loci, that illustrate the power and utility of the approach. We also developed and validated a rapid, efficient process for precise allele replacement that requires only one round each of transformation and genotyping. We show that this process can be applied in population scale to an individual target locus, without genotyping, to identify clones with an altered phenotype (targeted forward genetics). It is therefore suitable for saturating, in situ, locus-specific mutation screens (e.g., of essential or non-essential genes and regulatory DNA elements) within normal chromosomal context.

Direct link between RACK1 function and localization at the ribosome in vivo

The receptor for activated C-kinase (RACK1), a conserved protein implicated in numerous signaling pathways, is a stoichiometric component of eukaryotic ribosomes located on the head of the 40S ribosomal subunit. To test the hypothesis that ribosome association is central to the function of RACK1 in vivo, we determined the 2.1-A crystal structure of RACK1 from Saccharomyces cerevisiae (Asc1p) and used it to design eight mutant versions of RACK1 to assess roles in ribosome binding and in vivo function. Conserved charged amino acids on one side of the beta-propeller structure were found to confer most of the 40S subunit binding affinity, whereas an adjacent conserved and structured loop had little effect on RACK1-ribosome association. Yeast mutations that confer moderate to strong defects in ribosome binding mimic some phenotypes of a RACK1 deletion strain, including increased sensitivity to drugs affecting cell wall biosynthesis and translation elongation. Furthermore, disruption of RACK1's position at the 40S ribosomal subunit results in the failure of the mRNA binding protein Scp160 to associate with actively translating ribosomes. These results provide the first direct evidence that RACK1 functions from the ribosome, implying a physical link between the eukaryotic ribosome and cell signaling pathways in vivo.

A two-step method for the introduction of single or multiple defined point mutations into the genome of Saccharomyces cerevisiae

The introduction of defined mutations into open reading frames (ORF) or non-translated regions of the genome is important to study of the structure-function relationship of amino acid residues in proteins or that of sequence motifs at the genome level. We describe a simple two-step method for the introduction of defined single or multiple point mutations into the genome of Saccharomyces cerevisiae. This method circumvents the need for plasmid-based mutagenesis and thus ensures homogenous expression of the gene of interest within the cell population. It is based on the introduction of a selectable marker downstream of the gene of interest. This marker is then amplified with a gene-specific primer that harbours the desired point mutation, creating a selectable marker-tagged mutant version of the gene of interest. The mutant fragment is then integrated into the genome of a wild-type strain through homologous recombination. Successive rounds of amplification of the mutant loci with primers that introduce additional point mutations upstream of existing mutations will generate multiple defined mutations within a single gene. As a proof of principle, we have employed this method to generate a temperature-sensitive mutant version of the plasma membrane ATPase, pma1-7, which bears two point mutations (Pro434Ala and Gly789Ser). Phenotypic analysis of a pma1-7 haploid strain indicates that this allele has the same characteristics as the original pma1-7 allele. It confers a temperature-sensitive growth phenotype and the newly synthesized Pma1-7 protein is unstable and rapidly degraded.

A human-mouse chimera of the alpha3alpha4alpha5(IV) collagen protomer rescues the renal phenotype in Col4a3-/- Alport mice

Collagen IV is a major structural component of basement membranes. In the glomerular basement membrane (GBM) of the kidney, the alpha3, alpha4, and alpha5(IV) collagen chains form a distinct network that is essential for the long-term stability of the glomerular filtration barrier, and is absent in most patients affected with Alport syndrome, a progressive inherited nephropathy associated with mutation in COL4A3, COL4A4, or COL4A5 genes. To investigate, in vivo, the regulation of the expression, assembly, and function of the alpha3alpha4alpha5(IV) protomer, we have generated a yeast artificial chromosome transgenic line of mice carrying the human COL4A3-COL4A4 locus. Transgenic mice expressed the human alpha3 and alpha4(IV) chains in a tissue-specific manner. In the kidney, when expressed onto a Col4a3(-/-) background, the human alpha3(IV) chain restored the expression of and co-assembled with the mouse alpha4 and alpha5(IV) chains specifically at sites where the human alpha3(IV) was expressed, demonstrating that the expression of all three chains is required for network assembly. The co-assembly of the human and mouse chains into a hybrid network in the GBM restores a functional GBM and rescues the Alport phenotype, providing further evidence that defective assembly of the alpha3-alpha4-alpha5(IV) protomer, caused by mutations in any of the three chains, is the pathogenic mechanism responsible for the disease. This line of mice, humanized for the alpha3(IV) collagen chain, will also provide a valuable model for studying the pathogenesis of Goodpasture syndrome, an autoimmune disease caused by antibodies against this chain.

Fluorescent histochemical techniques for analysis of intracellular signaling

Intracellular signaling relies on the orchestrated cooperation of signaling proteins and modules, their intracellular localization, and membrane trafficking. Recently, a repertoire of fluorescence-based techniques, which significantly increases our potential for detailed studies of the involved mechanisms, has been introduced. Microscopic techniques with increased resolution have been combined with improved techniques for detection of signaling proteins. Transfections of fluorescently tagged proteins have allowed in vivo microscopy of their trafficking and interactions with other proteins and intracellular structures. We present an overview of general signaling principles and a description of techniques based on fluorescent microscopy suited for studies of signaling mechanisms.

In vivo site-directed mutagenesis using oligonucleotides

Functional characterization of the genes of higher eukaryotes has been aided by their expression in model organisms and by analyzing site-specific changes in homologous genes in model systems such as the yeast Saccharomyces cerevisiae. Modifying sequences in yeast or other organisms such that no heterologous material is retained requires in vitro mutagenesis together with subcloning. PCR-based procedures that do not involve cloning are inefficient or require multistep reactions that increase the risk of additional mutations. An alternative approach, demonstrated in yeast, relies on transformation with an oligonucleotide, but the method is restricted to the generation of mutants with a selectable phenotype. Oligonucleotides, when combined with gap repair, have also been used to modify plasmids in yeast; however, this approach is limited by restriction-site availability. We have developed a mutagenesis approach in yeast based on transformation by unpurified oligonucleotides that allows the rapid creation of site-specific DNA mutations in vivo. A two-step, cloning-free process, referred to as delitto perfetto, generates products having only the desired mutation, such as a single or multiple base change, an insertion, a small or a large deletion, or even random mutations. The system provides for multiple rounds of mutation in a window up to 200 base pairs. The process is RAD52 dependent, is not constrained by the distribution of naturally occurring restriction sites, and requires minimal DNA sequencing. Because yeast is commonly used for random and selective cloning of genomic DNA from higher eukaryotes such as yeast artificial chromosomes, the delitto perfetto strategy also provides an efficient way to create precise changes in mammalian or other DNA sequences.

Structural and functional conservation at the boundaries of the chicken beta-globin domain

We show that the 3' boundary of the chicken beta-globin locus bears striking structural similarities to the 5' boundary. In erythroid cells a clear transition in DNase I sensitivity of chromatin at the 3' end of the locus is observed, the location of this transition is marked by a constitutive DNase I hypersensitive site (HS), and DNA spanning this site has the enhancer-blocking capacity of an insulator. This HS contains a binding site for the transcription factor CTCF. As in the case of the 5' insulator, the CTCF site is both necessary and sufficient for the enhancer-blocking activity of the 3' boundary. The position of this insulator is consistent with our proposal that it may function to maintain the distinct regulatory programs of the globin genes and their closely appended 3' neighbor, an odorant receptor gene. We conclude that both boundaries of the chicken beta-globin domain are capable of playing functionally similar roles and that the same protein is a necessary component of the molecular mechanism through which these boundaries are defined.

A sequence with homology to human HPFH-linked enhancer elements and to a family of G-protein linked membrane receptor genes is located downstream of the chicken beta-globin locus

We report 5805bp of novel sequence (GenBank/EMBL Accession No. AJ012570) from a region starting approx. 11.5kb downstream of the chicken beta-globin locus (map position approx. +30.8 to +36.6kb), which contains a 945bp open reading frame (map position approx. +33 to +33.9kb). This is predicted to encode a 315-residue protein containing seven hydrophobic helical regions and a 17 amino acid motif characteristic of the R7G family of G-protein coupled membrane-bound receptors. The open reading frame and some surrounding sequence also have significant homology with the breakpoint enhancer elements, which also contain open reading frames, implicated in the HPFH-1/2 and HPFH-6 deletional forms of the human syndrome, hereditary persistence of foetal haemoglobin (HPFH). The existence of similar sequences at similar distances downstream of the beta-globin genes in chickens and HPFH patients is intriguing.

Exploring gene function: use of yeast artificial chromosome transgenesis

Transgenesis is a very powerful tool in functional analysis of proteins and control of gene expression. One of the main drawbacks has been the low levels of expression, lack of tissue specificity, and inappropriate expression frequently observed for transgenes made with small plasmid-based constructs. The use of much larger DNA fragments cloned in yeast artificial clones (YACs), bacterial artificial clones, or P1-based artificial clones has been found to give much better levels of expression, generally very close to that of an endogenous gene, and tissue-specific expression matching that of the endogenous gene. In addition, the large DNA can easily be subtly modified by homologous recombination. This article describes the background and methods of YAC transgenesis.

The X-linked immunodeficiency defect in the mouse is corrected by expression of human Bruton's tyrosine kinase from a yeast artificial chromosome transgene

Mutations in the gene for Bruton's tyrosine kinase result in the B cell differentiation defects X-linked agammaglobulinemia in man and X-linked immunodeficiency in mice. Here we describe the generation of two yeast artificial chromosome (YAC)-transgenic mouse strains in which high-level expression of human Btk is provided by endogenous regulatory cis-acting elements that are present on a 340-kb transgene, Yc340-hBtk. The expression pattern of the transgenic human Btk was found to parallel that of the endogenous murine gene. When the Yc340-hBtk-transgenic mice were mated onto a Btk-deficient background, the xid B cell defects were fully corrected: conventional and CD5+ B-1 B cells were present in normal numbers, serum IgM and IgG3 levels as well as responses to T cell-independent type II antigens were in the normal ranges. In vivo competition experiments in Btk+/- female mice demonstrated that in the conventional B cell population the Yc340-hBtk transgene could fully compensate the absence of expression of endogenous murine Btk. We conclude that in the YAC-transgenic mice Btk is appropriately expressed in the context of native regulatory sequences.

Distal enhancer regulation by promoter derepression in topologically constrained DNA in vitro

Long-range promoter-enhancer interactions are a crucial regulatory feature of many eukaryotic genes yet little is known about the mechanisms involved. Using cloned chicken betaA-globin genes, either individually or within the natural chromosomal locus, enhancer-dependent transcription is achieved in vitro at a distance of 2 kb with developmentally staged erythroid extracts. This occurs by promoter derepression and is critically dependent upon DNA topology. In the presence of the enhancer, genes must exist in a supercoiled conformation to be actively transcribed, whereas relaxed or linear templates are inactive. Distal protein-protein interactions in vitro may be favored on supercoiled DNA because of topological constraints. In this system, enhancers act primarily to increase the probability of rapid and efficient transcription complex formation and initiation. Repressor and activator proteins binding within the promoter, including erythroid-specific GATA-1, mediate this process.

Production of transgenic mice with yeast artificial chromosomes

Techniques are now available that allow the transfer of intact yeast artificial chromosome (YAC) DNA into transgenic mice. Coupled with the ability to perform mutagenesis on YAC sequences by homologous recombination in yeast, they enable the analysis of large genes or multigenic loci in vivo. This system has been used to study the developmental regulation of the human beta-globin locus.

Expression of the chicken beta-globin gene cluster in mice: correct developmental expression and distributed control

To investigate the regulation of gene clusters, we introduced the entire chicken beta-globin cluster into mice. This 35-kb region includes the four globin genes (rho-beta H-beta A-epsilon), the four upstream hypersensitive sites, and the intergenic beta A/epsilon enhancer. The chicken globins are not arranged in order of developmental expression, which is unlike the case for the human beta-globin cluster, in which gene order plays a role in the regulation of globin expression. Mice carrying the chicken cluster expressed the transgenes with the same developmental patterns as seen in the chicken. Therefore, stage-specific erythroid transcriptional milieus existed before the divergence of birds and mammals and have been conserved since then. Mice bearing the complete cluster except for a deletion removing the beta A/epsilon enhancer displayed markedly reduced expression of the beta H, beta A, and epsilon genes with efficient (but variable) rho expression. Mice carrying the four genes and beta A/epsilon enhancer but without the upstream hypersensitive sites showed reduced expression of rho, beta H, and beta A, with variable expression of epsilon. We conclude that (i) all of the genes (except possibly rho) are under the control of both the upstream hypersensitive sites and the enhancer, (ii) the influence of the control elements can extend beyond the nearest active gene, (iii) a single element (the enhancer) can influence more than one gene in a single developmental stage, (iv) the enhancer can work bidirectionally, and (v) neither the upstream sites (as a group) nor the enhancer showed developmental stage specificity. Thus, the regulation of this cluster is achieved by interaction of two distinct control regions with each of the globin genes.

Regulated expression of the beta-globin gene locus in synthetic nuclei

Regulated gene expression within a complex chromosomal locus requires multiple nuclear processes. We have analyzed the transcriptional properties of the cloned chick beta-globin gene family when assembled into synthetic nuclei made by use of Xenopus egg extracts. Assembly in an erythroid protein environment correctly recapitulates tissue-specific chromatin structure and long-range promoter-enhancer interaction within the chromosomal locus, resulting in beta-globin gene activation. Nucleosome-repressed beta-globin templates can be transcriptionally activated by double-stranded DNA replication in the presence of staged erythroid proteins by remodeling of the chromatin structure within the promoter region and establishment of distal promoter-enhancer communication. The programmed transcriptional state of a gene, as encoded by its chromatin structure and long-range promoter-enhancer interactions, is stable to nuclear decondensation and DNA replication unless active remodeling occurs in the presence of specific DNA-binding proteins.

Primary sequence, evolution, and repetitive elements of the Gallus gallus (chicken) beta-globin cluster

The DNA sequence of the Gallus gallus (chicken) beta-globin cluster was completed and analyzed. This G + C-rich region is 23.7 kb in length and includes the rho-, beta H-, beta A-, and epsilon-globin genes, the enhancer found between the beta A and epsilon genes, and three upstream DNase I hypersensitive sites. The CpG dinucleotides are nonrandomly distributed, being present at an increased relative frequency near the promoters and upstream hypersensitive sites. The cluster has an unusually low TA dinucleotide frequency. The upstream hypersensitive sites (5'HS1, 5'HS2, and 5'HS3) contain DNA sequence motifs recognized by erythroid transcription factors. However, no significant sequence similarity was found among the upstream hypersensitive sites and the beta A/epsilon enhancer. The G. gallus upstream site sequences were not similar to the upstream sites of the mammalian globin clusters, probably due to the small size of the functional regions and large evolutionary distance between the classes. The avian cluster evolved by gene duplication from an ancestor beta-globin gene, first producing the epsilon and the rho/beta H/beta A ancestor genes, then the rho and the beta H/beta A ancestor genes, and finally the beta H- and beta A-globins. Four probable gene conversions can be documented: beta A to beta H, epsilon to beta H, and rho/epsilon (twice). The cluster shows a massive overrepresentation of a non-LTR retrotransposon, CR1, which accounts for 16% of the DNA. We suggest that the locus is a preferred site for CR1 insertion.

Transfer of yeast artificial chromosomes from yeast to mammalian cells

Human DNA can be cloned as yeast artificial chromosomes (YACs), each of which contains several hundred kilobases of human DNA. This DNA can be manipulated in the yeast host using homologous recombination and yeast selectable markers. In relatively few steps it is possible to make virtually any change in the cloned human DNA from single base pair changes to deletions and insertions. In order to study the function of the cloned DNA and the effects of the changes made in the yeast, the human DNA must be transferred back into mammalian cells. Recent experiments indicate that large genes can be transferred from the yeast host to mammalian cells in tissue culture and that the genes are transferred intact and are expressed. Using the same methods it may soon be possible to transfer YAC DNA into the mouse germ line so that the expression and function of genes cloned in YACs can be studied in developing and adult mammalian animals.

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.