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1. Exploring the mechanism of action of Rosa roxburghii Tratt quercetin in ameliorating type 2 diabetes in mice based on the intestinal microbiome and metabolomics

Author

Ziyi Zhao, Yuping Zhu, Lu Nie, Yisha Luo, Shuyi Qiu, and Tingyuan Ren

Subjects
Rosa roxburghii Tratt quercetin, Type 2 diabetes mellitus, Gut microbiome, Metabolomics, Nutrition. Foods and food supply, TX341-641
Abstract

The aim of this study was to evaluate the effect of Rosa roxburghii Tratt (RRT) quercetin on type 2 diabetes mellitus (T2DM). A high-sugar and high-fat diet combined with streptozotocin (STZ) was used to construct a mouse model of T2DM. In this study, level of blood glucose, lipid and inflammatory factors, surface area of the cecum wall, pH and free ammonia, histopathology, and the composition of the intestinal microbiota and metabolites were analyzed. After 28 days of intervention, RRT quercetin significantly (p

Published
2025
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2. Automation and Expansion of EMMA Assembly for Fast-Tracking Mammalian System Engineering

Author

Joshua S. James, Sally Jones, Andrea Martella, Yisha Luo, David I. Fisher, and Yizhi Cai

Subjects
Gene Editing, Mammals, Automation, Genetic Vectors, Biomedical Engineering, Animals, General Medicine, CRISPR-Cas Systems, Biochemistry, Genetics and Molecular Biology (miscellaneous), Gene Library, RNA, Guide, Kinetoplastida
Abstract

With applications from functional genomics to the production of therapeutic biologics, libraries of mammalian expression vectors have become a cornerstone of modern biological investigation and engineering. Multiple modular vector platforms facilitate the rapid design and assembly of vectors. However, such systems approach a technical bottleneck when a library of bespoke vectors is required. Utilizing the flexibility and robustness of the Extensible Mammalian Modular Assembly (EMMA) toolkit, we present an automated workflow for the library-scale design, assembly, and verification of mammalian expression vectors. Vector design is simplified using our EMMA computer-aided design tool (EMMA-CAD), while the precision and speed of acoustic droplet ejection technology are applied in vector assembly. Our pipeline facilitates significant reductions in both reagent usage and researcher hands-on time compared with manual assembly, as shown by system Q-metrics. To demonstrate automated EMMA performance, we compiled a library of 48 distinct plasmid vectors encoding either CRISPR interference or activation modalities. Characterization of the workflow parameters shows that high assembly efficiency is maintained across vectors of various sizes and design complexities. Our system also performs strongly compared with manual assembly efficiency benchmarks. Alongside our automated pipeline, we present a straightforward strategy for integrating gRNA and Cas modules into the EMMA platform, enabling the design and manufacture of valuable genome editing resources.

Published
2022
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3. EMMA-CAD: Design Automation for Synthetic Mammalian Constructs

Author

Yisha Luo, Joshua S. James, Sally Jones, Andrea Martella, and Yizhi Cai

Subjects
Mammals, Automation, Biomedical Engineering, Animals, Humans, Synthetic Biology, DNA, General Medicine, Biochemistry, Genetics and Molecular Biology (miscellaneous), Algorithms, Software
Abstract

Computational design tools are the cornerstone of synthetic biology and have underpinned its rapid development over the past two decades. As the field has matured, the scale of biological investigation has expanded dramatically, and researchers often must rely on computational tools to operate in the high-throughput investigational space. This is especially apparent in the modular design of DNA expression circuits, where complexity is accumulated rapidly. Alongside our automated pipeline for the high-throughput construction of Extensible Modular Mammalian Assembly (EMMA) expression vectors, we recognized the need for an integrated software solution for EMMA vector design. Here we present EMMA-CAD (https://emma.cailab.org), a powerful web-based computer-aided design tool for the rapid design of bespoke mammalian expression vectors. EMMA-CAD features a variety of functionalities, including a user-friendly design interface, automated connector selection underpinned by rigorous computer optimization algorithms, customization of part libraries, and personalized design spaces. Capable of translating vector assembly designs into human- and machine-readable protocols for vector construction, EMMA-CAD integrates seamlessly into our automated EMMA pipeline, hence completing an end-to-end design to production workflow.

Published
2022
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6. Design, Construction, and Functional Characterization of a tRNA Neochromosome in Yeast

Author

Daniel Schindler, Roy S.K. Walker, Shuangying Jiang, Aaron N. Brooks, Yun Wang, Carolin A. Müller, Charlotte Cockram, Yisha Luo, Alicia García, Daniel Schraivogel, Julien Mozziconacci, Benjamin A. Blount, Jitong Cai, Lois Ogunlana, Wei Liu, Katarina Jönsson, Dariusz Abramczyk, Eva Garcia-Ruiz, Tomasz W. Turowski, Reem Swidah, Tom Ellis, Francisco Antequera, Yue Shen, Conrad A. Nieduszynski, Romain Koszul, Junbiao Dai, Lars M. Steinmetz, Jef D. Boeke, and Yizhi Cai

Abstract

Here we report the design, construction and characterization of a tRNA neochromosome, a designer chromosome that functions as an additional, de novo counterpart to the native complement of Saccharomyces cerevisiae. Intending to address one of the central design principles of the Sc2.0 project, the ∼190 kb tRNA neochromosome houses all 275 relocated nuclear tRNA genes. To maximize stability, the design incorporated orthogonal genetic elements from non-S. cerevisiae yeast species. Furthermore, the presence of 283 rox recombination sites enable an orthogonal SCRaMbLE system capable of adjusting tRNA abundance. Following construction, we obtained evidence of a potent selective force once the neochromosome was introduced into yeast cells, manifesting as a spontaneous doubling in cell ploidy. Furthermore, tRNA sequencing, transcriptomics, proteomics, nucleosome mapping, replication profiling, FISH and Hi-C were undertaken to investigate questions of tRNA neochromosome behavior and function. Its construction demonstrates the remarkable tractability of the yeast model and opens up new opportunities to directly test hypotheses surrounding these essential non-coding RNAs.HighlightsDe novo design, construction and functional characterization of a neochromosome containing all 275 nuclear tRNA genes of Saccharomyces cerevisiae.Increasing the copy number of the 275 highly expressed tRNA genes causes cellular burden, which the host cell likely buffers either by selecting for partial tRNA neochromosome deletions or by increasing its ploidy.The tRNA neochromosome can be chemically extracted and transformed into new strain backgrounds, enabling its transplantation into multi-synthetic chromosome strains to finalize the Sc2.0 strain.Comprehensive functional characterization does not pinpoint a singular cause for the cellular burden caused by the tRNA neochromosome, but does reveal novel insights into its tRNA and structural chromosome biology.

Published
2022
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7. Dissecting aneuploidy phenotypes by constructing Sc2.0 chromosome VII and SCRaMbLEing synthetic disomic yeast

Author

Yue Shen, Feng Gao, Yun Wang, Yuerong Wang, Ju Zheng, Jianhui Gong, Jintao Zhang, Zhouqing Luo, Daniel Schindler, Yang Deng, Weichao Ding, Tao Lin, Reem Swidah, Hongcui Zhao, Shuangying Jiang, Cheng Zeng, Shihong Chen, Tai Chen, Yong Wang, Yisha Luo, Leslie Mitchell, Joel S. Bader, Guojie Zhang, Xia Shen, Jian Wang, Xian Fu, Junbiao Dai, Jef D. Boeke, Huanming Yang, Xun Xu, and Yizhi Cai

Abstract

Aneuploidy compromises genomic stability, often leading to embryo inviability, and is frequently associated with tumorigenesis and aging. Different aneuploid chromosome stoichiometries lead to distinct transcriptomic and phenotypic changes, making it helpful to study aneuploidy in tightly controlled genetic backgrounds. By deploying the engineered SCRaMbLE system to the newly synthesized Sc2.0 megabase chromosome VII (synVII), we constructed a synthetic disomic yeast and screened hundreds of SCRaMbLEd derivatives with diverse chromosomal rearrangements. Phenotypic characterization and multi-omics analysis revealed that fitness defects associated with aneuploidy could be restored by i) removing most of the chromosome content, or ii) modifying specific regions in the duplicated chromosome. These findings indicate that both chromosome copy number and chromosomal regions contribute to the aneuploidy-related phenotypes, and the synthetic yeast resource opens new paradigms in studying aneuploidy.In briefUse of SCRaMbLE and newly synthesized Mb-scale Sc2.0 chromosome VII enables insights into genotype/phenotype relationships associated with aneuploidyHighlightsDe novo design and synthesis of a Mb-scale synthetic yeast chromosome VII, carrying 11.8% sequence modifications and representing nearly 10% of the yeast genome.A disomic yeast (n + synVII) is constructed for dissecting the aneuploidy phenotypeSCRaMbLE enables systematic exploration of regions causing aneuploidy phenotypesChromosomal copy number and content both contribute to aneuploidy phenotypesA 20 Kb deletion on the right arm of synVII leads to fitness improvement linked to up-regulation of protein synthesis

Published
2022
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10. Multi-criteria spatial analysis for location selection of multi-purpose utility tunnels

Author

Amin Hammad, Tersoo K. Genger, and Yisha Luo

Subjects
Computer science, Analytic network process, 0211 other engineering and technologies, Analytic hierarchy process, TOPSIS, 02 engineering and technology, Building and Construction, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, Multiple-criteria decision analysis, computer.software_genre, 01 natural sciences, Set (abstract data type), Ranking, Data mining, Spatial analysis, computer, Selection (genetic algorithm), 021101 geological & geomatics engineering, 0105 earth and related environmental sciences
Abstract

Multi-purpose utility tunnels (MUTs) integrate all underground utilities in one accessible tunnel. MUTs reduce the need for excavations and their associated costs, as well as the resulting traffic congestion. Several MUTs have been implemented in different parts of the world. Their locations have either been politically influenced or selected to preserve heritage sites or to meet the conditions of a newly developed city. Nevertheless, selecting the location in an existing city under street segments is affected by several criteria that have different spatial characteristics. Combining these characteristics and managing the trade-offs that exist between them determine the ranking of alternative MUT locations. The use of subjective and objective weights in the decision-making process will offer different perspectives from the decision-maker's perspective and the data itself, respectively. This paper aims to analyze spatial data as an input in the multi-criteria decision-making (MCDM) process of the MUT location selection. The objectives are: (1) defining the criteria that influence the MUT location selection, (2) defining the required GIS datasets for quantifying the criteria as scores for each candidate street segment, (3) analyzing the impacts of the dependencies between the criteria by comparing the ranking results of two MCDM methods (i.e., Analytic Hierarchy Process (AHP) and Analytic Network Process (ANP)) combined with the Technique for Order Preference by the Similarity to Ideal Solution (TOPSIS), (4) analyzing the difference between using subjective weights or objective weights, and (5) developing a prototype system to integrate the MCDM methods in a GIS platform. A vector-based spatial analysis is conducted to identify the suitable locations for MUT construction based on 12 criteria representing physical condition information or affecting social costs. Two subjective MCDM methods (i.e., AHP and ANP) are used to generate each criterion's weights, and the ranking of alternatives is determined using TOPSIS. Another set of weights representing the objective weights are calculated for each criterion using the Shannon Entropy method. These weights are combined with TOPSIS to obtain an objective ranking of the alternatives. Based on the results from the different combinations (AHP + TOPSIS, ANP + TOPSIS, and ENTROPY + TOPSIS), the top alternative is always the same.

Published
2021
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11. Genetic Constructor: An Online DNA Design Platform

Author

Hille Tekotte, Cornelia Johanna Franziska Scheitz, Anais Moisy, Joseph Nathan Lachoff, Maxwell Bates, Florencio Mazzoldi, Duncan A. Meech, Rupal Khilari, Yisha Luo, Eli S. Groban, Deepak Chandran, and Valentin Zulkower

Subjects
0301 basic medicine, business.industry, Computer science, Biomedical Engineering, Cloud computing, DNA, General Medicine, Bioinformatics, computer.software_genre, Biochemistry, Genetics and Molecular Biology (miscellaneous), 03 medical and health sciences, Visual language, Synthetic biology, 030104 developmental biology, Software, Iterative refinement, Leverage (statistics), Plug-in, Architecture, Genetic Engineering, business, Software engineering, computer
Abstract

Genetic Constructor is a cloud Computer Aided Design (CAD) application developed to support synthetic biologists from design intent through DNA fabrication and experiment iteration. The platform allows users to design, manage, and navigate complex DNA constructs and libraries, using a new visual language that focuses on functional parts abstracted from sequence. Features like combinatorial libraries and automated primer design allow the user to separate design from construction by focusing on functional intent, and design constraints aid iterative refinement of designs. A plugin architecture enables contributions from scientists and coders to leverage existing powerful software and connect to DNA foundries. The software is easily accessible and platform agnostic, free for academics, and available in an open-source community edition. Genetic Constructor seeks to democratize DNA design, manufacture, and access to tools and services from the synthetic biology community.

Published
2017
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12. Deep functional analysis of synII, a 770-kilobase synthetic yeast chromosome

Author

Romain Koszul, Wei Liu, Leslie A. Mitchell, Zhouqing Luo, Hui Jiang, Jef D. Boeke, Adele L. Marston, Adrien Paul-Dubois-Taine, Zhao Hongcui, Yanqun Fan, Ze-Xiong Xie, Roy Walker, Yujia Wang, Yisha Luo, Sarah M. Richardson, Bo Wen, Conrad A. Nieduszynski, Jin Zi, Jian Wang, Tai Chen, Huanming Yang, Christopher E. French, Carolin A. Müller, Dariusz Abramczyk, Shihong Chen, Junbiao Dai, Yun Wang, Bonnie Alver, Giovanni Stracquadanio, Kun Yang, Bing-Zhi Li, Yue Shen, Jianhui Gong, Fengji Tan, Ying-Jin Yuan, Yizhi Cai, Baojin Zhou, Feng Gao, Xun Xu, Joel S. Bader, University of Edinburgh, Beijing Genomics Institute [Shenzhen] (BGI), James D. Watson Institute of Genome Sciences, Partenaires INRAE, BGI Qingdao, Sir William Dunn School of Pathology [Oxford], University of Oxford [Oxford], High Throughput Biology Center [Baltimore], Johns Hopkins University School of Medicine [Baltimore], Johns Hopkins University (JHU), New York University Langone Medical Center (NYU Langone Medical Center), NYU System (NYU), Tsinghua University [Beijing] (THU), Tianjin University (TJU), Régulation spatiale des Génomes - Spatial Regulation of Genomes, Institut Pasteur [Paris]-Centre National de la Recherche Scientifique (CNRS), University of Oxford, and Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS)

Subjects
0301 basic medicine, Genetics, Multidisciplinary, 030102 biochemistry & molecular biology, [SDV]Life Sciences [q-bio], Chromosomal rearrangement, Biology, Genome, Article, Chromosome segregation, 03 medical and health sciences, 030104 developmental biology, Protein-fragment complementation assay, URA3, Copy-number variation, Homologous recombination, Gene
Abstract

INTRODUCTION Although much effort has been devoted to studying yeast in the past few decades, our understanding of this model organism is still limited. Rapidly developing DNA synthesis techniques have made a “build-to-understand” approach feasible to reengineer on the genome scale. Here, we report on the completion of a 770-kilobase synthetic yeast chromosome II (synII). SynII was characterized using extensive Trans-Omics tests. Despite considerable sequence alterations, synII is virtually indistinguishable from wild type. However, an up-regulation of translational machinery was observed and can be reversed by restoring the transfer RNA (tRNA) gene copy number. RATIONALE Following the “design-build-test-debug” working loop, synII was successfully designed and constructed in vivo. Extensive Trans-Omics tests were conducted, including phenomics, transcriptomics, proteomics, metabolomics, chromosome segregation, and replication analyses. 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. RESULTS To efficiently construct megabase-long chromosomes, we developed an I- Sce I–mediated strategy, which enables parallel integration of synthetic chromosome arms and reduced the overall integration time by 50% for synII. An I- Sce I site is introduced for generating a double-strand break to promote targeted homologous recombination during mitotic growth. Despite hundreds of modifications introduced, there are still regions sharing substantial sequence similarity that might lead to undesirable meiotic recombinations when intercrossing the two semisynthetic chromosome arm strains. Induction of the I- Sce I–mediated double-strand break is otherwise lethal and thus introduced a strong selective pressure for targeted homologous recombination. Since our strategy is designed to generate a markerless synII and leave the URA3 marker on the wild-type chromosome, we observed a tenfold increase in URA3 -deficient colonies upon I- Sce I induction, meaning that our strategy can greatly bias the crossover events toward the designated regions. By incorporating comprehensive phenotyping approaches at multiple levels, we demonstrated that synII was capable of powering the growth of yeast indistinguishably from wild-type cells (see the figure), showing highly consistent biological processes comparable to the native strain. Meanwhile, we also noticed modest but potentially significant up-regulation of the translational machinery. The main alteration underlying this change in expression is the deletion of 13 tRNA genes. A growth defect was observed in one very specific condition—high temperature (37°C) in medium with glycerol as a carbon source—where colony size was reduced significantly. We targeted and debugged this defect by two distinct approaches. The first approach involved phenotype screening of all intermediate strains followed by a complementation assay with wild-type sequences in the synthetic strain. By doing so, we identified a modification resulting from PCRTag recoding in TSC10 , which is involved in regulation of the yeast high-osmolarity glycerol (HOG) response pathway. After replacement with wild-type TSC10 , the defect was greatly mitigated. The other approach, debugging by SCRaMbLE, showed rearrangements in regions containing HOG regulation genes. Both approaches indicated that the defect is related to HOG response dysregulation. Thus, the phenotypic defect can be pinpointed and debugged through multiple alternative routes in the complex cellular interactome network. CONCLUSION We have demonstrated that synII segregates, replicates, and functions in a highly similar fashion compared with its wild-type counterpart. Furthermore, we believe that the iterative “design-build-test-debug” cycle methodology, established here, will facilitate progression of the Sc2.0 project in the face of the increasing synthetic genome complexity. SynII characterization. ( A ) Cell cycle comparison between synII and BY4741 revealed by the percentage of cells with separated CEN2-GFP dots, metaphase spindles, and anaphase spindles. ( B ) Replication profiling of synII (red) and BY4741 (black) expressed as relative copy number by deep sequencing. ( C ) RNA sequencing analysis revealed that the significant up-regulation of translational machinery in synII is induced by the deletion of tRNA genes in synII.

Published
2017
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13. Synthesis, debugging, and effects of synthetic chromosome consolidation: synVI and beyond

Author

Zuojian Tang, Kang Dong, Roy Walker, J. Andrew Martin, Hongjiu Dai, Yizhi Cai, Jef D. Boeke, Zheng Kuang, Beatrix Ueberheide, Junbiao Dai, Adriana Heguy, Yanling Yang, Joel S. Bader, Leslie A. Mitchell, David Fenyö, Xuya Wang, Kun Yang, Yisha Luo, Yu Zhao, Ann Wang, Giovanni Stracquadanio, and Sarah M. Richardson

Subjects
0301 basic medicine, Genetics, Multidisciplinary, Protein subunit, Physical Chromosome Mapping, Chromosome, Biology, Proteomics, Genome, Phenotype, Synthetic genomics, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Transfer RNA, 030217 neurology & neurosurgery
Abstract

INTRODUCTION Total synthesis of designer chromosomes and genomes is a new paradigm for the study of genetics and biological systems. The Sc2.0 project is building a designer yeast genome from scratch to test and extend the limits of our biological knowledge. Here we describe the design, rapid assembly, and characterization of synthetic chromosome VI (synVI). Further, we investigate the phenotypic, transcriptomic, and proteomic consequences associated with consolidation of three synthetic chromosomes–synVI, synIII, and synIXR—into a single poly-synthetic strain. RATIONALE A host of Sc2.0 chromosomes, including synVI, have now been constructed in discrete strains. With debugging steps, where the number of bugs scales with chromosome length, all individual synthetic chromosomes have been shown to power yeast cells to near wild-type (WT) fitness. Testing the effects of Sc2.0 chromosome consolidation to uncover possible synthetic genetic interactions and/or perturbations of native cellular networks as the number of designer changes increases is the next major step for the Sc2.0 project. RESULTS SynVI was rapidly assembled using nine sequential steps of SwAP-In (switching auxotrophies progressively by integration), yielding a ~240-kb synthetic chromosome designed to Sc2.0 specifications. We observed partial silencing of the left- and rightmost genes on synVI, each newly positioned subtelomerically relative to their locations on native VI. This result suggests that consensus core X elements of Sc2.0 universal telomere caps are insufficient to fully buffer telomere position effects. The synVI strain displayed a growth defect characterized by an increased frequency of glycerol-negative colonies. The defect mapped to a synVI design feature in the essential PRE4 gene ( YFR050C ), encoding the β7 subunit of the 20 S proteasome. Recoding 10 codons near the 3′ end of the PRE4 open reading frame (ORF) caused a ~twofold reduction in Pre4 protein level without affecting RNA abundance. Reverting the codons to the WT sequence corrected both the Pre4 protein level and the phenotype. We hypothesize that the formation of a stem loop involving recoded codons underlies reduced Pre4 protein level. Sc2.0 chromosomes (synI to synXVI) are constructed individually in discrete strains and consolidated into poly-synthetic (poly-syn) strains by “endoreduplication intercross.” Consolidation of synVI with synthetic chromosomes III (synIII) and IXR (synIXR) yields a triple-synthetic (triple-syn) strain that is ~6% synthetic overall—with almost 70 kb deleted, including 20 tRNAs, and more than 12 kb recoded. Genome sequencing of double-synthetic (synIII synVI, synIII synIXR, synVI synIXR) and triple-syn (synIII synVI synIXR) cells indicates that suppressor mutations are not required to enable coexistence of Sc2.0 chromosomes. Phenotypic analysis revealed a slightly slower growth rate for the triple-syn strain only; the combined effect of tRNA deletions on different chromosomes might underlie this result. Transcriptome and proteome analyses indicate that cellular networks are largely unperturbed by the existence of multiple synthetic chromosomes in a single cell. However, a second bug on synVI was discovered through proteomic analysis and is associated with alteration of the HIS2 transcription start as a consequence of tRNA deletion and loxPsym site insertion. Despite extensive genetic alterations across 6% of the genome, no major global changes were detected in the poly-syn strain “omics” analyses. CONCLUSION Analyses of phenotypes, transcriptomics, and proteomics of synVI and poly-syn strains reveal, in general, WT cell properties and the existence of rare bugs resulting from genome editing. Deletion of subtelomeres can lead to gene silencing, recoding deep within an ORF can yield a translational defect, and deletion of elements such as tRNA genes can lead to a complex transcriptional output. These results underscore the complementarity of transcriptomics and proteomics to identify bugs, the consequences of designer changes in Sc2.0 chromosomes. The consolidation of Sc2.0 designer chromosomes into a single strain appears to be exceptionally well tolerated by yeast. A predictable exception to this is the deletion of tRNAs, which will be restored on a separate neochromosome to avoid synthetic lethal genetic interactions between deleted tRNA genes as additional synthetic chromosomes are introduced. Debugging synVI and characterization of poly-synthetic yeast cells. ( A ) The second Sc2.0 chromosome to be constructed, synVI, encodes a “bug” that causes a variable colony size, dubbed a “glycerol-negative growth-suppression defect.” ( B ) Synonymous changes in the essential PRE4 ORF lead to a reduced protein level, which underlies the growth defect. ( C ) The poly-synthetic strain synIII synVI synIXR directs growth of yeast cells to near WT fitness levels.

Published
2017
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14. 3D organization of synthetic and scrambled chromosomes

Author

Romain Koszul, Ying-Jin Yuan, Joel S. Bader, Yi Wu, Guillaume Mercy, Yisha Luo, Vittore F. Scolari, Yue Shen, Agnès Thierry, Yizhi Cai, Michael Shen, Ze-Xiong Xie, Roy Walker, Guanghou Zhao, Héloïse Muller, Kun Yang, Weimin Zhang, Zhouqing Luo, Jef D. Boeke, Junbiao Dai, Julien Mozziconacci, Huanming Yang, Leslie A. Mitchell, Université Pierre et Marie Curie - Paris 6 (UPMC), Régulation spatiale des Génomes - Spatial Regulation of Genomes, Institut Pasteur [Paris]-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Physique Théorique de la Matière Condensée (LPTMC), Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC), Johns Hopkins University (JHU), Tsinghua University [Beijing] (THU), Ministry of Education of China, University of Edinburgh, New York University Langone Medical Center (NYU Langone Medical Center), NYU System (NYU), Beijing Genomics Institute [Shenzhen] (BGI), Tianjin University (TJU), We thank A. Cournac, M. Marbouty, and L. Lazar-Stefanita for fruitful discussions and advice. This research was supported by funding to R.K. from the European Research Council (ERC) under the 7th Framework Program (FP7/2007-2013, ERC grant agreement 260822), Agence Nationale pour la Recherche (ANR) (MeioRec ANR-13-BSV6-0012-02), and ERASynBio and ANR (IESY ANR-14-SYNB-0001-03). H.M. and V.F.S are partly supported by Pasteur-Roux Fellowships. J.D. was funded by the National Science Foundation of China (31471254), Tsinghua University Initiative Scientific Research Program (2011Z02296), Ph.D. Programs Foundation of Ministry of Education of China (20110002120055), and the Chinese Ministry of Science and Technology (2012CB725201). Y.-J.Y. was supported by the Natural Science Foundation of China (21621004 and 21390203). Y.C. was funded by a Chancellor’s Fellowship from the University of Edinburgh, a startup fund from the Scottish Universities Life Sciences Alliance, and grants from the U.K. Biotechnology and Biological Sciences Research Council (BB/M005690/1, BB/M025640/1, and BB/M00029X/1). Y.S. was supported by a research grant from the Shenzhen Engineering Laboratory for Clinical Molecular Diagnostic Promotion [JZF no. (2016)884]. This work was supported in part by funding from the U.S. National Science Foundation (grants MCB-0718846 and MCB-1026068 to J.D.B. and J.S.B. and MCB-0546446 and MCB-1445545 to J.S.B.). J.D.B. and J.S.B. are founders and directors of Neochromosome. J.D.B. serves as a scientific advisor to Recombinetics and Sample6. These arrangements are reviewed and managed by the committees on conflict of interest at the New York University Langone Medical Center (J.D.B.) and Johns Hopkins University (J.S.B.). FASTQ files of the reads have been deposited in the Sequence Read Archive database under accession number SRP070421., ANR-13-BSV6-0012,MeioRec,Dynamique chromosomique et recombinaison au cours de la méiose(2013), ANR-14-SYNB-0001,IESY,Induced Evolution of Synthetic Yeast genomes(2014), European Project: 260822,EC:FP7:ERC,ERC-2010-StG_20091118,DICIG(2011), Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS), and Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS)

Subjects
0301 basic medicine, Yeast artificial chromosome, Genetics, Multidisciplinary, [SDV]Life Sciences [q-bio], Chromosome, Chromosomal rearrangement, Human artificial chromosome, Biology, Article, Chromosome conformation capture, 03 medical and health sciences, 030104 developmental biology, Evolutionary biology, Chromosome 19, Centromere, Chromosome 22
Abstract

INTRODUCTION The overall organization of budding yeast chromosomes is driven and regulated by four factors: (i) the tethering and clustering of centromeres at the spindle pole body; (ii) the loose tethering of telomeres at the nuclear envelope, where they form small, dynamic clusters; (iii) a single nucleolus in which the ribosomal DNA (rDNA) cluster is sequestered from other chromosomes; and (iv) chromosomal arm lengths. Hi-C, a genomic derivative of the chromosome conformation capture approach, quantifies the proximity of all DNA segments present in the nuclei of a cell population, unveiling the average multiscale organization of chromosomes in the nuclear space. We exploited Hi-C to investigate the trajectories of synthetic chromosomes within the Saccharomyces cerevisiae nucleus and compare them with their native counterparts. RATIONALE The Sc2.0 genome design specifies strong conservation of gene content and arrangement with respect to the native chromosomal sequence. However, synthetic chromosomes incorporate thousands of designer changes, notably the removal of transfer RNA genes and repeated sequences such as transposons and subtelomeric repeats to enhance stability. They also carry loxPsym sites, allowing for inducible genome SCRaMbLE (synthetic chromosome rearrangement and modification by loxP -mediated evolution) aimed at accelerating genomic plasticity. Whether these changes affect chromosome organization, DNA metabolism, and fitness is a critical question for completion of the Sc2.0 project. To address these questions, we used Hi-C to characterize the organization of synthetic chromosomes. RESULTS Comparison of synthetic chromosomes with native counterparts revealed no substantial changes, showing that the redesigned sequences, and especially the removal of repeated sequences, had little or no effect on average chromosome trajectories. Sc2.0 synthetic chromosomes have Hi-C contact maps with much smoother contact patterns than those of native chromosomes, especially in subtelomeric regions. This improved “mappability” results directly from the removal of repeated elements all along the length of the synthetic chromosomes. These observations highlight a conceptual advance enabled by bottom-up chromosome synthesis, which allows refinement of experimental systems to make complex questions easier to address. Despite the overall similarity, differences were observed in two instances. First, deletion of the HML and HMR silent mating-type cassettes on chromosome III led to a loss of their specific interaction. Second, repositioning the large array of rDNA repeats nearer to the centromere cluster forced substantial genome-wide conformational changes—for instance, inserting the array in the middle of the small right arm of chromosome III split the arm into two noninteracting regions. The nucleolus structure was then trapped in the middle between small and large chromosome arms, imposing a physical barrier between them. In addition to describing the Sc2.0 chromosome organization, we also used Hi-C to identify chromosomal rearrangements resulting from SCRaMbLE experiments. Inducible recombination between the hundreds of loxPsym sites introduced into Sc2.0 chromosomes enables combinatorial rearrangements of the genome structure. Hi-C contact maps of two SCRaMbLE strains carrying synIII and synIXR chromosomes revealed a variety of cis events, including simple deletions, inversions, and duplications, as well as translocations, the latter event representing a class of trans SCRaMbLE rearrangements not previously observed. CONCLUSION This large data set is a resource that will be exploited in future studies exploring the power of the SCRaMbLE system. By investigating the trajectories of Sc2.0 chromosomes in the nuclear space, this work paves the way for future studies addressing the influence of genome-wide engineering approaches on essential features of living systems. Synthetic chromosome organization. ( A ) Hi-C contact maps of synII and native (wild-type, WT) chromosome II. Red arrowheads point to filtered bins (white vectors) that are only present in the native chromosome map. kb, kilobases. ( B ) Three-dimensional (3D) representations of Hi-C maps of strains carrying rDNA either on synXII or native chromosome III. ( C ) Contact maps and 3D representations of synIXR (yellow) and synIII (pink) before (left) and after (right) SCRaMbLE . Translocation breakpoints are indicated by green and blue arrowheads.

Published
2017
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15. 'Perfect' designer chromosome V and behavior of a ring derivative

Author

Ning Zhi Liu, Wen Zheng Zhang, Qiu Hui Lin, Ting Liu, Jing Sheng Cheng, Mei Qing Fu, Kun Yang, Ming Zhu Ding, Ran Tao, J. Andrew Martin, Yue Shen, Xia Li, Jef D. Boeke, Guo Zhen Jiang, Zhi Chao Yu, Si Chen, Wan Su, Jin Gui Liu, Jian Jun Qiao, Yan Wang, Shi Yang Liu, Wen Qian Zhang, Su Wang, Hang Xu, Shi Lei Han, Wei Liu, Ken Chen, Yi Wu, Yue Liu, Ze-Xiong Xie, Juan Zhao, Yi Lin Liu, Roy Walker, Li Xiang Song, Ye Xuan Deng, Xuya Wang, Xia Wang, Rui Guo, Leslie A. Mitchell, Joel S. Bader, Ting Ting Zhang, Ming Hua Shen, Guang Rong Zhao, Xiao Tong Wei, Xiao Ran Xu, Bing-Zhi Li, Jun Qi Zhu, Ying-Jin Yuan, Hao Xing Du, Bo Xuan Zeng, Yi Ran Wang, Bin Jia, Zheng Kuang, Shi Lan Yang, Ting Li, Lan Meng Qu, Jia Qing Zhu, Kai Ren Tian, Ping Sheng Ma, Tian Qing Song, Xue Nan Li, Guang Xin Ye, Cheng Hu, Huanming Yang, Jia Fei Lv, Wei Zhang, Yisha Luo, Qi Feng, Zhu Jin, Zhen Ning Liu, Wen Qi Ding, Fang Zhai, Xin Qi, Jin Hua Zhang, Xiao Le Wu, Yizhi Cai, Meng Zhao, Xue Jiao Guo, Xue Bai, Jun Jun Dai, Meng Long Hu, Fei Fei Li, Si Yu Xin, Xiao Na Yang, En Xu Wang, Giovanni Stracquadanio, Hui Min Liu, Lin Ting Wang, Chun-Ting Zhang, Zheng Bao Xia, Da Shuai Li, Yun Wang, and Nan Jia

Subjects
0301 basic medicine, Yeast artificial chromosome, Genetics, Multidisciplinary, Research Support, Non-U.S. Gov't, Ring chromosome, Saccharomyces cerevisiae, Chromosome, 02 engineering and technology, Gene rearrangement, Biology, 021001 nanoscience & nanotechnology, biology.organism_classification, Genome, 03 medical and health sciences, 030104 developmental biology, Journal Article, Ploidy, 0210 nano-technology, Homologous recombination
Abstract

INTRODUCTION The Saccharomyces cerevisiae 2.0 project (Sc2.0) aims to modify the yeast genome with a series of densely spaced designer changes. Both a synthetic yeast chromosome arm (synIXR) and the entirely synthetic chromosome (synIII) function with high fitness in yeast. For designer genome synthesis projects, precise engineering of the physical sequence to match the specified design is important for the systematic evaluation of underlying design principles. Yeast can maintain nuclear chromosomes as rings, occurring by chance at repeated sequences, although the cyclized format is unfavorable in meiosis given the possibility of dicentric chromosome formation from meiotic recombination. Here, we describe the de novo synthesis of synthetic yeast chromosome V (synV) in the “Build-A-Genome China” course, perfectly matching the designer sequence and bearing loxPsym sites, distinguishable watermarks, and all the other features of the synthetic genome. We generated a ring synV derivative with user-specified cyclization coordinates and characterized its performance in mitosis and meiosis. RATIONALE Systematic evaluation of underlying Sc2.0 design principles requires that the final assembled synthetic genome perfectly match the designed sequence. Given the size of yeast chromosomes, synthetic chromosome construction is performed iteratively, and new mutations and unpredictable events may occur during synthesis; even a very small number of unintentional nucleotide changes across the genome could have substantial effects on phenotype. Therefore, precisely matching the physical sequence to the designed sequence is crucial for verification of the design principles in genome synthesis. Ring chromosomes can extend those design principles to provide a model for genomic rearrangement, ring chromosome evolution, and human ring chromosome disorders. RESULTS We chemically synthesized, assembled, and incorporated designer chromosome synV (536,024 base pairs) of S. cerevisiae according to Sc2.0 principles, based on the complete nucleotide sequence of native yeast chromosome V (576,874 base pairs). This work was performed as part of the “Build-A-Genome China” course in Tianjin University. We corrected all mutations found—including duplications, substitutions, and indels—in the initial synV strain by using integrative cotransformation of the precise desired changes and by means of a clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein 9 (Cas9)–based method. Altogether, 3331 corrected base pairs were required to match to the designed sequence. We generated a strain that exactly matches all designer sequence changes that displays high fitness under a variety of culture conditions. All corrections were verified with whole-genome sequencing; RNA sequencing revealed only minor changes in gene expression—most notably, decreases in expression of genes relocated near synthetic telomeres as a result of design. We constructed a functional circular synV (ring_synV) derivative in yeast by precisely joining both chromosome ends (telomeres) at specified coordinates. The ring chromosome showed restoration of subtelomeric gene expression levels. The ring_synV strain exhibited fitness comparable with that of the linear synV strain, revealed no change in sporulation frequency, but notably reduced spore viability. In meiosis, heterozygous or homozygous diploid ring_wtV and ring_synV chromosomes behaved similarly, exhibiting substantially higher frequency of the formation of zero-spore tetrads, a type that was not seen in the rod chromosome diploids. Rod synV chromosomes went through meiosis with high spore viability, despite no effort having been made to preserve meiotic competency in the design of synV. CONCLUSION The perfect designer-matched synthetic chromosome V provides strategies to edit sequence variants and correct unpredictable events, such as off-target integration of extra copies of synthetic DNA elsewhere in the genome. We also constructed a ring synthetic chromosome derivative and evaluated its fitness and stability in yeast. Both synV and synVI can be circularized and can power yeast cell growth without affecting fitness when gene content is maintained. These fitness and stability phenotypes of the ring synthetic chromosome in yeast provide a model system with which to probe the mechanism of human ring chromosome disorders. Synthesis, cyclization, and characterization of synV . ( A ) Synthetic chromosome V (synV, 536,024 base pairs) was designed in silico from native chromosome V (wtV, 576,874 base pairs), with extensive genotype modification designed to be phenotypically neutral. ( B ) CRISPR/Cas9 strategy for multiplex repair. ( C ) Colonies of wtV, synV, and ring_synV strains.

Published
2017
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16. Engineering the ribosomal DNA in a megabase synthetic chromosome

Author

Guanghou Zhao, Sha Hou, Yibo Xiao, Yiran Qin, Junkai Dong, Jianhui Gong, Leslie A. Mitchell, Guo-Qiang Chen, Tong Zhou, Junbiao Dai, Yi Wu, Yisha Luo, Shuangying Jiang, Yakun Guo, Bing-Zhi Li, Ann Wang, Joel S. Bader, Yue Shen, Kun Yang, Yun Wang, Lihui Wang, Erchao Cheng, Yizhi Cai, Jef D. Boeke, Yicong Lin, Tianyi Li, Meng Xu, Huanming Yang, Qingyu Wu, Ning Huang, Zhouqing Luo, Jing Huang, Jiaying Zhang, Li Zhao, Qin Qin, Weimin Zhang, Zheng Kuang, Xi He, Jiwei Lin, Sarah M. Richardson, Ying-Jin Yuan, Roy Walker, Qingwen Jiang, and Xinzhi Zou

Subjects
0301 basic medicine, Yeast artificial chromosome, Locus (genetics), Saccharomyces cerevisiae, Biology, Genome, DNA, Ribosomal, 03 medical and health sciences, 0302 clinical medicine, Chromosome 19, Journal Article, Ribosomal DNA, Gene, Chromosomes, Artificial, Yeast, Genetics, Cell Nucleus, Multidisciplinary, Research Support, Non-U.S. Gov't, Chromosome, 030104 developmental biology, Synthetic Biology, Genome, Fungal, Genetic Engineering, Transcriptome, Chromosome 22, 030217 neurology & neurosurgery
Abstract

INTRODUCTION It has long been an interesting question whether a living cell can be constructed from scratch in the lab, a goal that may not be realized anytime soon. Nonetheless, with advances in DNA synthesis technology, the complete genetic material of an organism can now be synthesized chemically. Hitherto, genomes of several organisms including viruses, phages, and bacteria have been designed and constructed. These synthetic genomes are able to direct all normal biological functions, capable of self-replication and production of offspring. Several years ago, a group of scientists worldwide formed an international consortium to reconstruct the genome of budding yeast, Saccharomyces cerevisiae . RATIONALE The synthetic yeast genome, designated Sc2.0, was designed according to a set of arbitrary rules, including the elimination of transposable elements and incorporation of specific DNA elements to facilitate further genome manipulation. Among the 16 S. cerevisiae chromosomes, chromosome XII is unique as one of the longest yeast chromosomes (~1 million base pairs) and additionally encodes the highly repetitive ribosomal DNA locus, which forms the well-organized nucleolus. We report on the design, construction, and characterization of chromosome XII, the physically largest chromosome in S. cerevisiae. RESULTS A 976,067–base pair linear chromosome, synXII, was designed based on the native chromosome XII sequence of S. cerevisiae , and chemically synthesized. SynXII was assembled using a two-step method involving, successive megachunk integration to produce six semisynthetic strains, followed by meiotic recombination–mediated assembly, yielding a full-length functional chromosome in S. cerevisiae. Minor growth defect “bugs” detected in synXII were caused by deletion of tRNA genes and were corrected 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. The same synthetic rDNA unit was also used to regenerate rDNA at three distinct chromosomal locations. The rDNA signature sequences of the internal transcribed spacer (ITS), often used to determine species identity by standard DNA barcoding procedures, were swapped to generate a Saccharomyces synXII strain that would be identified as S. bayanus. Remarkably, these substantial DNA changes had no detectable phenotypic consequences under various laboratory conditions. CONCLUSION The rDNA locus of synXII is highly plastic; not only can it be moved to other chromosomal loci, it can also be altered in its ITS region to masquerade as a distinct species as defined by DNA barcoding, used widely in taxonomy. The ability to perform “species morphing” reported here presumably reflects the degree of evolutionary flexibility by which these ITS regions change. However, this barcoding region is clearly not infinitely flexible, as only relatively modest intragenus base changes were tolerated. More severe intergenus differences in ITS sequence did not result in functional rDNAs, probably because of defects in rRNA processing. The ability to design, build, and debug a megabase-sized chromosome, together with the flexibility in rDNA locus position, speaks to the remarkable overall flexibility of the yeast genome. Hierarchical assembly and subsequent restructuring of synXII. SynXII was assembled in two steps: First, six semisynthetic synXII strains were built in which segments of native XII DNA were replaced with the corresponding designer sequences. Next, the semisynthetic strains were combined withmultiple rounds ofmating/sporulation, eventually generating a single strain encoding fulllength synXII.The rDNA repeats were removed, modified, and subsequently regenerated at distinct chromosomal locations for species morphing and genome restructuring.

Published
2016
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17. YeastFab: the design and construction of standard biological parts for metabolic engineering in Saccharomyces cerevisiae

Author

Yakun, Guo, Junkai, Dong, Tong, Zhou, Jamie, Auxillos, Tianyi, Li, Weimin, Zhang, Lihui, Wang, Yue, Shen, Yisha, Luo, Yijing, Zheng, Jiwei, Lin, Guo-Qiang, Chen, Qingyu, Wu, Yizhi, Cai, and Junbiao, Dai

Subjects
Metabolic Engineering, Transcription, Genetic, Methods Online, Saccharomyces cerevisiae, beta Carotene, Metabolic Networks and Pathways
Abstract

It is a routine task in metabolic engineering to introduce multicomponent pathways into a heterologous host for production of metabolites. However, this process sometimes may take weeks to months due to the lack of standardized genetic tools. Here, we present a method for the design and construction of biological parts based on the native genes and regulatory elements in Saccharomyces cerevisiae. We have developed highly efficient protocols (termed YeastFab Assembly) to synthesize these genetic elements as standardized biological parts, which can be used to assemble transcriptional units in a single-tube reaction. In addition, standardized characterization assays are developed using reporter constructs to calibrate the function of promoters. Furthermore, the assembled transcription units can be either assayed individually or applied to construct multi-gene metabolic pathways, which targets a genomic locus or a receiving plasmid effectively, through a simple in vitro reaction. Finally, using β-carotene biosynthesis pathway as an example, we demonstrate that our method allows us not only to construct and test a metabolic pathway in several days, but also to optimize the production through combinatorial assembly of a pathway using hundreds of regulatory biological parts.

Published
2015

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