Engineering the ribosomal DNA in a megabase synthetic chromosome.

We designed and synthesized a 976,067-base pair linear chromosome, synXII, based on native chromosome XII in Saccharomyces cerevisiae SynXII was assembled using a two-step method, specified by successive megachunk integration and meiotic recombination-mediated assembly, producing a functional chromosome in S. cerevisiae. Minor growth defect "bugs" detected in synXII, caused by deletion of tRNA genes, were rescued by introducing an ectopic copy of a single tRNA gene. The ribosomal gene cluster (rDNA) on synXII was left intact during the assembly process and subsequently replaced by a modified rDNA unit used to regenerate rDNA at three distinct chromosomal locations. The signature sequences within rDNA, which can be used to determine species identity, were swapped to generate a Saccharomyces synXII strain that would be identified as Saccharomyces bayanus by standard DNA barcoding procedures.

3D organization of synthetic and scrambled chromosomes.

Although the design of the synthetic yeast genome Sc2.0 is highly conservative with respect to gene content, the deletion of several classes of repeated sequences and the introduction of thousands of designer changes may affect genome organization and potentially alter cellular functions. We report here the Hi-C-determined three-dimensional (3D) conformations of Sc2.0 chromosomes. The absence of repeats leads to a smoother contact pattern and more precisely tractable chromosome conformations, and the large-scale genomic organization is globally unaffected by the presence of synthetic chromosome(s). Two exceptions are synIII, which lacks the silent mating-type cassettes, and synXII, specifically when the ribosomal DNA is moved to another chromosome. We also exploit the contact maps to detect rearrangements induced in SCRaMbLE (synthetic chromosome rearrangement and modification by loxP-mediated evolution) strains.

"Perfect" designer chromosome V and behavior of a ring derivative.

Perfect matching of an assembled physical sequence to a specified designed sequence is crucial to verify design principles in genome synthesis. We designed and de novo synthesized 536,024-base pair chromosome synV in the "Build-A-Genome China" course. We corrected an initial isolate of synV to perfectly match the designed sequence using integrative cotransformation and clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein 9 (Cas9)-mediated editing in 22 steps; synV strains exhibit high fitness under a variety of culture conditions, compared with that of wild-type V strains. A ring synV derivative was constructed, which is fully functional in Saccharomyces cerevisiae under all conditions tested and exhibits lower spore viability during meiosis. Ring synV chromosome can extends Sc2.0 design principles and provides a model with which to study genomic rearrangement, ring chromosome evolution, and human ring chromosome disorders.

Bug mapping and fitness testing of chemically synthesized chromosome X.

Debugging a genome sequence is imperative for successfully building a synthetic genome. As part of the effort to build a designer eukaryotic genome, yeast synthetic chromosome X (synX), designed as 707,459 base pairs, was synthesized chemically. SynX exhibited good fitness under a wide variety of conditions. A highly efficient mapping strategy called pooled PCRTag mapping (PoPM), which can be generalized to any watermarked synthetic chromosome, was developed to identify genetic alterations that affect cell fitness ("bugs"). A series of bugs were corrected that included a large region bearing complex amplifications, a growth defect mapping to a recoded sequence in FIP1, and a loxPsym site affecting promoter function of ATP2 PoPM is a powerful tool for synthetic yeast genome debugging and an efficient strategy for phenotype-genotype mapping.

Synthesis, debugging, and effects of synthetic chromosome consolidation: synVI and beyond.

We describe design, rapid assembly, and characterization of synthetic yeast Sc2.0 chromosome VI (synVI). A mitochondrial defect in the synVI strain mapped to synonymous coding changes within PRE4 (YFR050C), encoding an essential proteasome subunit; Sc2.0 coding changes reduced Pre4 protein accumulation by half. Completing Sc2.0 specifies consolidation of 16 synthetic chromosomes into a single strain. We investigated phenotypic, transcriptional, and proteomewide consequences of Sc2.0 chromosome consolidation in poly-synthetic strains. Another "bug" was discovered through proteomic analysis, associated with alteration of the HIS2 transcription start due to transfer RNA deletion and loxPsym site insertion. Despite extensive genetic alterations across 6% of the genome, no major global changes were detected in the poly-synthetic strain "omics" analyses. This work sets the stage for completion of a designer, synthetic eukaryotic genome.

Deep functional analysis of synII, a 770-kilobase synthetic yeast chromosome.

Here, we report the successful design, construction, and characterization of a 770-kilobase synthetic yeast chromosome II (synII). Our study incorporates characterization at multiple levels-including phenomics, transcriptomics, proteomics, chromosome segregation, and replication analysis-to provide a thorough and comprehensive analysis of a synthetic chromosome. Our Trans-Omics analyses reveal a modest but potentially relevant pervasive up-regulation of translational machinery observed in synII, mainly caused by the deletion of 13 transfer RNAs. By both complementation assays and SCRaMbLE (synthetic chromosome rearrangement and modification by loxP-mediated evolution), we targeted and debugged the origin of a growth defect at 37°C in glycerol medium, which is related to misregulation of the high-osmolarity glycerol response. Despite the subtle differences, the synII strain shows highly consistent biological processes comparable to the native strain.

Design of a synthetic yeast genome.

We describe complete design of a synthetic eukaryotic genome, Sc2.0, a highly modified Saccharomyces cerevisiae genome reduced in size by nearly 8%, with 1.1 megabases of the synthetic genome deleted, inserted, or altered. Sc2.0 chromosome design was implemented with BioStudio, an open-source framework developed for eukaryotic genome design, which coordinates design modifications from nucleotide to genome scales and enforces version control to systematically track edits. To achieve complete Sc2.0 genome synthesis, individual synthetic chromosomes built by Sc2.0 Consortium teams around the world will be consolidated into a single strain by "endoreduplication intercross." Chemically synthesized genomes like Sc2.0 are fully customizable and allow experimentalists to ask otherwise intractable questions about chromosome structure, function, and evolution with a bottom-up design strategy.

From selective full-length genes isolation by TAR cloning in yeast to their expression from HAC vectors in human cells.

Transformation-associated recombination (TAR) cloning allows selective isolation of full-length genes and genomic loci as large circular Yeast Artificial Chromosomes (YACs) in yeast. The method has a broad application for structural and functional genomics, long-range haplotyping, characterization of chromosomal rearrangements, and evolutionary studies. In this paper, we describe a basic protocol for gene isolation by TAR as well as a method to convert TAR isolates into Bacterial Artificial Chromosomes (BACs) using a retrofitting vector. The retrofitting vector contains a 3' HPRT-loxP cassette to allow subsequent gene loading into a unique loxP site of the HAC-based (Human Artificial Chromosome) gene delivery vector. The benefit of combining the TAR gene cloning technology with the HAC gene delivery system for gene expression studies is discussed.

Assembly of large, high G+C bacterial DNA fragments in yeast.

The ability to assemble large pieces of prokaryotic DNA by yeast recombination has great application in synthetic biology, but cloning large pieces of high G+C prokaryotic DNA in yeast can be challenging. Additional considerations in cloning large pieces of high G+C DNA in yeast may be related to toxic genes, to the size of the DNA, or to the absence of yeast origins of replication within the sequence. As an example of our ability to clone high G+C DNA in yeast, we chose to work with Synechococcus elongatus PCC 7942, which has an average G+C content of 55%. We determined that no regions of the chromosome are toxic to yeast and that S. elongatus DNA fragments over ~200 kb are not stably maintained. DNA constructs with a total size under 200 kb could be readily assembled, even with 62 kb of overlapping sequence between pieces. Addition of yeast origins of replication throughout allowed us to increase the total size of DNA that could be assembled to at least 454 kb. Thus, cloning strategies utilizing yeast recombination with large, high G+C prokaryotic sequences should include yeast origins of replication as a part of the design process.

Isolation of circular yeast artificial chromosomes for synthetic biology and functional genomics studies.

Circular yeast artificial chromosomes (YACs) provide significant advantages for cloning and manipulating large segments of genomic DNA in Saccharomyces cerevisiae. However, it has been difficult to exploit these advantages, because circular YACs are difficult to isolate and purify. Here we describe a method for purification of large circular YACs that is more reliable compared with previously described protocols. This method has been used to purify YACs up to 600 kb in size. The purified YAC DNA is suitable for restriction enzyme digestion, DNA sequencing and functional studies. For example, YACs carrying full-size genes can be purified from yeast and used for transfection into mammalian cells or for the construction of a synthetic genome that can be used to produce a synthetic cell. This method for isolating high-quality YAC DNA in microgram quantities should be valuable for functional and synthetic genomic studies. The entire protocol takes ∼3 d to complete.

Estandarización de un protocolo sencillo para la extracción de ADN genómico de levaduras / Standardising a simple protocol for extracting yeast from genomic DNA

Se estandarizó un protocolo rápido, sencillo y de bajo costo para la extracción de ADN genómico de levaduras a partir de lisis de la pared celular mediante tratamiento enzimático y precipitación por alcoholes. El empleo de la enzima Beta-glucoronidasa en reemplazo de la enzima Zimolasa, permitió obtener ADN en alta concentración (124,9±30,2 ng/λl) y de buena calidad (A260/A280 nm =1,86±0,1), ideal para su uso en estudios de biología molecular. Además, se adicionó un paso de incubación del ADN obtenido a 100° C para inactivar ADNasas. La calidad del ADN obtenido fue evaluada por medio de la amplificación de la región ITS1-5.8S-ITS2, presentando bandas definidas y cuantificables (entre 380 y 880 pb) ideales para estudios de identificación molecular y filogenia.

A quick, simple and low-cost protocol for extracting genomic DNA from yeast by cell wall lysis involving enzymatic treatment and alcoholic precipitation was standardised. Higher DNA yields (124.9±30.2 ng/λl) were obtained by using beta-glucuronidase instead of zymolyase; these had very high quality (A260/A280 nm = 1.86±0.1) and would be suitable for use in molecular biology assays. Moreover, a DNAse inactivation step was also introduced by incubation at 100 °C to further ensure DNA stability. DNA quality was assayed by PCR amplification of the ITS1-5.8S-ITS2 region, revealing defined, quantifiable 380 to 880 bp bands. These results show that the protocol is ideal for molecular identification and phylogenetic studies.

Structure of the genes for porcine endometrial secreted and membrane folate binding proteins.

The endometrium of the pig produces two types of folate binding proteins (FBP) which, based on their sequences, are likely to be membrane (m) and secreted (s) forms. A clone containing both a gene coding for the sFBP cDNA and a gene coding for the mFBP was isolated from a yeast artificial chromosome (YAC) library. Each gene was subcloned and sequenced. The gene for sFBP spanned 4.4 kbp and included 5 exons. The mFBP gene spanned 7.0 kbp and also contained 5 exons. Structures of the genes were very similar for the last three exons, and this similarity was shared with other known FBP/folate receptor (FR) gene sequences. Unexpectedly, portions of introns 3 and 4 of both genes were highly homologous, suggesting the possibility that sequences within these introns served some as yet unknown function. In contrast, the structures of the 5' exons differed between the two genes and other known FBP/FR genes. Comparison of putative promoter regions for the two genes with promoter regions for human FBP/FR genes revealed significant sequence homology between sFBP and human gammaFBP and between mFBP and human alphaFR. These regions of homology may play a role in control of transcription of each gene.

Physical mapping and promoter structure of the murine cAMP-specific phosphodiesterase pde4a gene.

The Pde4a gene is a mammalian homolog of the dunce learning and memory gene of Drosophila melanogaster and encodes cAMP-specific phosphodiesterases, targets for drugs with antidepressant and anti-inflammatory actions in humans. We have analyzed the intron/exon and promoter structure of the murine Pde4a gene. Pde4a encodes at least two different transcripts, each generated by alternative mRNA splicing and the use of alternative promoters. The majority of Pde4a exons are tightly clustered at the 3' end of the gene. The 5' region of the gene contains at least one widely separated exon, which encodes the 5' end of a distinct mRNA transcript and contains a separate promoter and transcriptional start site. Analysis of YAC clones determined that the Pde4a gene maps to the 4-cM region of Chromosome (Chr) 9, close to Ldlr and Epor, in a region syntenic to human PDE4A.

Macrophage specific overexpression of the human macrophage scavenger receptor in transgenic mice, using a 180-kb yeast artificial chromosome, leads to enhanced foam cell formation of isolated peritoneal macrophages.

Macrophage scavenger receptors class A (MSR) are thought to play an important role in atherogenesis by mediating the unrestricted uptake of modified lipoproteins by macrophages in the vessel wall leading to foam cell formation. To investigate the in vivo role of the MSR in this process, a transgenic mouse model expressing both isoforms of the human MSR was generated. A 180-kb yeast artificial chromosome (YAC) containing the human MSR gene (MSR1) with 60- and 40-kb flanking sequence at the 5' and 3' end, respectively, was obtained by reducing the size of a 1050-kb YAC by homologous recombination. This 180-kb YAC was microinjected into mouse oocytes. In the resulting transgenic mice, high levels of mRNA for both type I and type II human MSR1 were detected in peritoneal macrophages and trace levels in other organs, known to contain macrophage-derived cells. Using an antibody against the human MSR, the Kupffer cells in the liver were shown to contain the MSR protein. In vivo clearance of acetyl-LDL was not changed in the MSR1-transgenic mice. However, in vitro studies using peritoneal macrophages from the transgenic mice showed a two-fold increased degradation of acetyl-LDL and cholesterolester accumulation concomitant with a four-fold increase in foam cell formation, as compared to wild-type macrophages. Thus, macrophage specific overexpression of the MSR may lead to increased foam cell formation, which is one of the initial and crucial steps in atherogenesis.

Genetic manipulation of kinetoplastida.

During the 1980s, many kinetoplastid genes were cloned and their function inferred from homology with genes from other organisms, location of the corresponding proteins or expression in heterologous systems. Up until 1990, before the availability of DNA transfection methodology, we could not analyze the function of kinetoplastid genes within the organisms themselves. Since then, it has become possible to create and complement mutants, to overexpress foreign proteins in the parasites, to knock out genes and even to switch off essential functions. However, these methods are not equally applicable in all parasites. Here, Christine Clayton highlights the differences and similarities between the most commonly used model organisms, and assesses the relative advantages of different approaches and parasites for different types of investigation.

[Isolating the ends of yeast artificial chromosome by inverse polymerase chain reaction].

OBJECTIVE: To establish a highly efficient method for isolating yeast artificial chromosome(YAC) ends. METHODS: Based on the sequence of TAC vector, the frequent cutting enzymes were used to cleave within the vector and the genomic insert to generate relatively small fragments,which were ligated and subsequently amplified using vector primers that are in inverse orientation. The PCR products were purified and sequenced. RESULTS 8 YAC termini were isolated from YAC 776E2,964C5,11D8 and 8D1. CONCLUSION: The results suggest that inverse PCR be an efficient method for isolating YAC termini.

Cloning and comparative mapping of the DiGeorge syndrome critical region in the mouse.

Chromosome deletions leading to the hemizygous loss of groups of contiguous genes are a major cause of human congenital defects. In some syndromes haploinsufficiency of a single gene causes the majority of the syndromal features, whereas other diseases are thought to be the consequences of a combined haploinsufficiency. In the case of the DiGeorge and velocardiofacial syndromes, caused by deletions within 22q11, the genetic analyses have so far failed to implicate a single gene. By virtue of FISH analysis and the creation of a BAC/P1 genomic clone contig we have mapped 19 murine homologues of genes and nine EST groups from the region deleted in DiGeorge syndrome and found them to be linked on mouse chromosome 16. Rearrangements during the divergence of mouse and human have led to differing gene orders in the two species, with implications for the most appropriate means of mimicking particular human deletions. The map confirms and extends previous analyses and the contig resources toward the generation of targeted deletions in the mouse.

Cytogenetic localization of genetic markers on porcine chromosome 7q.

Four microsatellite markers (S0078, SWR1210, SW732, and SW304) taken from the linkage map of porcine chromosome 7 were assigned to the cytogenetic map of pig chromosome 7 by fluorescence in situ hybridization (FISH) analysis of selected yeast artificial chromosomes (YACs). These four new polymorphic cytogenetic markers provide additional anchor points for integrating the linkage and cytogenetic maps of chromosomal region 7q.

Myostatin maps to porcine chromosome 15 by linkage and physical analyses.

Myostatin belongs to the transforming growth factor-beta superfamily, and is expressed specifically in developing and mature skeletal muscle. Myostatin appears to act as a negative regulator of muscle development, since mice with targeted disruption of this gene display a large increase in muscle mass. In this study, the porcine myostatin gene was mapped to chromosome 15q2.3 by fluorescence in situ hybridization. Myostatin was also positioned within the chromosome 15 linkage group using both a polymorphism located in the second intron and an associated microsatellite. The development of highly polymorphic markers associated with myostatin will support population studies to identify alleles of this gene that affects muscle mass and/or fat deposition in swine.