Your search keyword '"Nina Alperovich"' showing total 11 results

1. Single-cell measurement of plasmid copy number and promoter activity

Author

Daniel A. Anderson, Bin Shao, Nina Alperovich, Christopher A. Voigt, Jayan Rammohan, and David L. Ross

Subjects

0301 basic medicine, DNA Copy Number Variations, Transcription, Genetic, Science, Population, Cell, General Physics and Astronomy, Computational biology, Biology, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Plasmid, Transcription (biology), medicine, Escherichia coli, RNA, Messenger, education, Promoter Regions, Genetic, Synthetic biology, Regulation of gene expression, education.field_of_study, Multidisciplinary, Bacteria, RNA, Promoter, General Chemistry, Gene Expression Regulation, Bacterial, biology.organism_classification, 030104 developmental biology, medicine.anatomical_structure, Transcription, 030217 neurology & neurosurgery, Plasmids

Abstract

Accurate measurements of promoter activities are crucial for predictably building genetic systems. Here we report a method to simultaneously count plasmid DNA, RNA transcripts, and protein expression in single living bacteria. From these data, the activity of a promoter in units of RNAP/s can be inferred. This work facilitates the reporting of promoters in absolute units, the variability in their activity across a population, and their quantitative toll on cellular resources, all of which provide critical insights for cellular engineering., A quantitative assessment of promoter function can improve the precision of cellular engineering. Here the authors develop a method to simultaneously count plasmid DNA, RNA transcripts and protein expression in single living bacteria.

Published

2021

2. The genotype-phenotype landscape of an allosteric protein

Author

Nathan D. Olson, Sasha F. Levy, Eugenia F. Romantseva, Abe Pressman, Peter D. Tonner, David J. Ross, Olga Vasilyeva, Drew S. Tack, and Nina Alperovich

Subjects

Mechanism (biology), In silico, Allosteric regulation, Computational biology, Lac repressor, Biology, Phenotype, DNA sequencing, Function (biology), Genotype phenotype

Abstract

Allostery is a fundamental biophysical mechanism that underlies cellular sensing, signaling, and metabolism. Quantitative methods to characterize the genotype-phenotype relationships for allosteric proteins would provide data needed to improve engineering of biological systems, to uncover the role of allosteric mis-regulation in disease, and to develop allosterically targeted drugs1. Here we report the large-scale measurement of the genotype-phenotype landscape for an allosteric protein: the lac repressor from Escherichia coli, LacI. Using a method that combines long-read and short-read DNA sequencing, we quantitatively determine the dose-response curves for nearly 105 variants of the LacI sensor. With the resulting data, we train a deep neural network (DNN) capable of predicting the dose-response curves for additional LacI genotypes in silico. We then map the impact of amino acid substitutions on the allosteric function of LacI. Additionally, we demonstrate engineering of allosteric function with unprecedented accuracy by identifying LacI variants from the measured landscape with quantitatively specified dose-response curves. Finally, we discover sensors with previously unreported band-stop dose-response curves. Overall, our results provide the first high-coverage, quantitative view of genotype-phenotype relationships for an allosteric protein, revealing a surprising diversity of phenotypes and showing that each phenotype is accessible via multiple distinct genotypes.

Published

2020

3. Assembly of plasmids for LacI genotype-phenotype landscape measurement v1

Author

not provided Drew S Tack, Nina Alperovich, not provided Olga Vasilyeva, and David Ross

Subjects

Genetics, Plasmid, Biology, Lac repressor, Genotype phenotype

Abstract

Here, we describe protocols for assembly of two different plasmids used for the measurement of the genotype-phenotype landscape of the LacI protein in E. coli: a Library Plasmid (pTY1, Figure 1a) used for the landscape measurement of the sensor library, and a Verification Plasmid (pVER, Figure 1b) used to verify the function of approximately 120 sensors from the library chosen to test the accuracy of the landscape measurement and to demonstrate the range of sensor function. We also describe the protocol used for the creation of the LacI sensor library in E. coli.

Published

2020

4. Cloning, Assembly, and Modification of the Primary Human Cytomegalovirus Isolate Toledo by Yeast-Based Transformation-Associated Recombination

Author

Sanjay Vashee, Timothy B. Stockwell, Nina Alperovich, Evgeniya A. Denisova, Daniel G. Gibson, Kyle C. Cady, Kristofer Miller, Krishna Kannan, Daniel Malouli, Lindsey B. Crawford, Alexander A. Voorhies, Eric Bruening, Patrizia Caposio, Klaus Fruh, Michael J. Imperiale, Eain Murphy, and Richard Stanton

Subjects

0301 basic medicine, Molecular Biology and Physiology, Sequence analysis, viruses, 030106 microbiology, lcsh:QR1-502, cloning, Saccharomyces cerevisiae, Biology, Origin of replication, Microbiology, Genome, Genetic recombination, lcsh:Microbiology, 03 medical and health sciences, Synthetic biology, chemistry.chemical_compound, Molecular Biology, cytomegalovirus, Genetics, Cloning, Bacterial artificial chromosome, genetic recombination, QR1-502, 030104 developmental biology, chemistry, DNA, Research Article

Abstract

The genomes of large DNA viruses, such as human cytomegalovirus (HCMV), are difficult to manipulate using current genetic tools, and at this time, it is not possible to obtain, molecular clones of CMV without extensive tissue culture. To overcome these limitations, we used synthetic biology tools to capture genomic fragments from viral DNA and assemble full-length genomes in yeast. Using an early passage of the HCMV isolate Toledo containing a mixture of wild-type and tissue culture-adapted virus. we directly cloned the majority sequence and recreated the minority sequence by simultaneous modification of multiple genomic regions. Thus, our novel approach provides a paradigm to not only efficiently engineer HCMV and other large DNA viruses on a genome-wide scale but also facilitates the cloning and genetic manipulation of primary isolates and provides a pathway to generating entirely synthetic genomes., Genetic engineering of cytomegalovirus (CMV) currently relies on generating a bacterial artificial chromosome (BAC) by introducing a bacterial origin of replication into the viral genome using in vivo recombination in virally infected tissue culture cells. However, this process is inefficient, results in adaptive mutations, and involves deletion of viral genes to avoid oversized genomes when inserting the BAC cassette. Moreover, BAC technology does not permit the simultaneous manipulation of multiple genome loci and cannot be used to construct synthetic genomes. To overcome these limitations, we adapted synthetic biology tools to clone CMV genomes in Saccharomyces cerevisiae. Using an early passage of the human CMV isolate Toledo, we first applied transformation-associated recombination (TAR) to clone 16 overlapping fragments covering the entire Toledo genome in Saccharomyces cerevisiae. Then, we assembled these fragments by TAR in a stepwise process until the entire genome was reconstituted in yeast. Since next-generation sequence analysis revealed that the low-passage-number isolate represented a mixture of parental and fibroblast-adapted genomes, we selectively modified individual DNA fragments of fibroblast-adapted Toledo (Toledo-F) and again used TAR assembly to recreate parental Toledo (Toledo-P). Linear, full-length HCMV genomes were transfected into human fibroblasts to recover virus. Unlike Toledo-F, Toledo-P displayed characteristics of primary isolates, including broad cellular tropism in vitro and the ability to establish latency and reactivation in humanized mice. Our novel strategy thus enables de novo cloning of CMV genomes, more-efficient genome-wide engineering, and the generation of viral genomes that are partially or completely derived from synthetic DNA. IMPORTANCE The genomes of large DNA viruses, such as human cytomegalovirus (HCMV), are difficult to manipulate using current genetic tools, and at this time, it is not possible to obtain, molecular clones of CMV without extensive tissue culture. To overcome these limitations, we used synthetic biology tools to capture genomic fragments from viral DNA and assemble full-length genomes in yeast. Using an early passage of the HCMV isolate Toledo containing a mixture of wild-type and tissue culture-adapted virus. we directly cloned the majority sequence and recreated the minority sequence by simultaneous modification of multiple genomic regions. Thus, our novel approach provides a paradigm to not only efficiently engineer HCMV and other large DNA viruses on a genome-wide scale but also facilitates the cloning and genetic manipulation of primary isolates and provides a pathway to generating entirely synthetic genomes.

Published

2017

5. Genome-wide engineering of an infectious clone of herpes simplex virus type 1 using synthetic genomics assembly methods

Author

Michael G. Montague, Peter Grzesik, Sanjana Prasad, Lauren M. Oldfield, Sanjay Vashee, Robert Friedman, Claudia D. Najera, Nina Alperovich, Diya Sabrina Chandra, Vladimir N. Noskov, Derek MacMath, Alexander A. Voorhies, and Prashant Desai

Subjects

0301 basic medicine, Comparative genomics, Genetics, Multidisciplinary, viruses, Genomics, DNA virus, Biology, ENCODE, Genome, Virus, Oncolytic virus, Genome engineering, 03 medical and health sciences, 030104 developmental biology

Abstract

Here, we present a transformational approach to genome engineering of herpes simplex virus type 1 (HSV-1), which has a large DNA genome, using synthetic genomics tools. We believe this method will enable more rapid and complex modifications of HSV-1 and other large DNA viruses than previous technologies, facilitating many useful applications. Yeast transformation-associated recombination was used to clone 11 fragments comprising the HSV-1 strain KOS 152 kb genome. Using overlapping sequences between the adjacent pieces, we assembled the fragments into a complete virus genome in yeast, transferred it into an Escherichia coli host, and reconstituted infectious virus following transfection into mammalian cells. The virus derived from this yeast-assembled genome, KOSYA, replicated with kinetics similar to wild-type virus. We demonstrated the utility of this modular assembly technology by making numerous modifications to a single gene, making changes to two genes at the same time and, finally, generating individual and combinatorial deletions to a set of five conserved genes that encode virion structural proteins. While the ability to perform genome-wide editing through assembly methods in large DNA virus genomes raises dual-use concerns, we believe the incremental risks are outweighed by potential benefits. These include enhanced functional studies, generation of oncolytic virus vectors, development of delivery platforms of genes for vaccines or therapy, as well as more rapid development of countermeasures against potential biothreats.

Published

2017

6. Cloning whole bacterial genomes in yeast

Author

Hamilton O. Smith, Monzia Moodie, Mikkel A. Algire, Daniel G. Gibson, Sanjay Vashee, Quang Phan, Nacyra Assad-Garcia, John I. Glass, Clyde A. Hutchison, Ray-Yuan Chuang, Gwynedd A. Benders, Carole Lartigue, J. Craig Venter, Chuck Merryman, Vladimir N. Noskov, Nina Alperovich, Evgeniya A. Denisova, William Carrera, and The J. Craig Venter Institute, 9704 Medical Center Drive, Rockville, Maryland 20850, USA

Subjects

[SDV]Life Sciences [q-bio], Saccharomyces cerevisiae, Genetic Vectors, Molecular Sequence Data, Mycoplasma genitalium, Bacterial genome size, Genome, 03 medical and health sciences, chemistry.chemical_compound, Plasmid, Mycoplasma, Genetics, Cloning, Molecular, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, Cloning, Recombination, Genetic, 0303 health sciences, biology, Base Sequence, 030306 microbiology, Mycoplasma mycoides, biology.organism_classification, Diploidy, Yeast, 3. Good health, Mycoplasma pneumoniae, chemistry, Synthetic Biology and Chemistry, DNA, Genome, Bacterial

Abstract

Most microbes have not been cultured, and many of those that are cultivatable are difficult, dangerous or expensive to propagate or are genetically intractable. Routine cloning of large genome fractions or whole genomes from these organisms would significantly enhance their discovery and genetic and functional characterization. Here we report the cloning of whole bacterial genomes in the yeast Saccharomyces cerevisiae as single-DNA molecules. We cloned the genomes of Mycoplasma genitalium (0.6 Mb), M. pneumoniae (0.8 Mb) and M. mycoides subspecies capri (1.1 Mb) as yeast circular centromeric plasmids. These genomes appear to be stably maintained in a host that has efficient, well-established methods for DNA manipulation.

Published

2010

7. Essential genes of a minimal bacterium

Author

John I. Glass, Clyde A. Hutchison, J. Craig Venter, Shibu Yooseph, Hamilton O. Smith, Nina Alperovich, Nacyra Assad-Garcia, Mahir Maruf, and Matthew R. Lewis

Subjects

Genetics, Mutation, Genes, Essential, Multidisciplinary, biology, Molecular Sequence Data, Mutant, Mycoplasma genitalium, Biological Sciences, medicine.disease_cause, biology.organism_classification, ENCODE, Genome, Genes, Bacterial, medicine, Minimal genome, Transposon mutagenesis, Gene, Genome, Bacterial

Abstract

Mycoplasma genitalium has the smallest genome of any organism that can be grown in pure culture. It has a minimal metabolism and little genomic redundancy. Consequently, its genome is expected to be a close approximation to the minimal set of genes needed to sustain bacterial life. Using global transposon mutagenesis, we isolated and characterized gene disruption mutants for 100 different nonessential protein-coding genes. None of the 43 RNA-coding genes were disrupted. Herein, we identify 382 of the 482 M. genitalium protein-coding genes as essential, plus five sets of disrupted genes that encode proteins with potentially redundant essential functions, such as phosphate transport. Genes encoding proteins of unknown function constitute 28% of the essential protein-coding genes set. Disruption of some genes accelerated M. genitalium growth.

Published

2006

8. Synthetic Generation of Influenza Vaccine Viruses for Rapid Response to Pandemics

Author

Brian M. Dattilo, David E. Wentworth, Sarthak Mane, Stephan Becker, Pirada Suphaphiphat, Chuck Merryman, Terika Spencer, Heidi Trusheim, Daniel G. Gibson, Vivien G. Dugan, Anthony Yee, Markus Eickmann, Raul Gomila, Ivna De Souza, J. Craig Venter, Mikhail Matrosovich, Armen Donabedian, Jennifer Uhlendorff, Casey Judge, Philip R. Dormitzer, Mikkel A. Algire, David M. Brown, Mario Barro, Liqun Han, Peter W. Mason, Gene A. Palmer, Bin Zhou, Rino Rappuoli, Annette Ferrari, John I. Glass, Thomas Strecker, Yingxia Wen, Jayshree Zaveri, Nina Alperovich, Giuseppe Palladino, Evgeniya A. Denisova, Stewart Craig, and Timothy B. Stockwell

Subjects

Synthetic vaccine, biology, Influenza vaccine, Hemagglutinin (influenza), General Medicine, medicine.disease_cause, Virology, Virus, Microbiology, Pandemic, biology.protein, Influenza A virus, medicine, Electronic data, Neuraminidase

Abstract

During the 2009 H1N1 influenza pandemic, vaccines for the virus became available in large quantities only after human infections peaked. To accelerate vaccine availability for future pandemics, we developed a synthetic approach that very rapidly generated vaccine viruses from sequence data. Beginning with hemagglutinin (HA) and neuraminidase (NA) gene sequences, we combined an enzymatic, cell-free gene assembly technique with enzymatic error correction to allow rapid, accurate gene synthesis. We then used these synthetic HA and NA genes to transfect Madin-Darby canine kidney (MDCK) cells that were qualified for vaccine manufacture with viral RNA expression constructs encoding HA and NA and plasmid DNAs encoding viral backbone genes. Viruses for use in vaccines were rescued from these MDCK cells. We performed this rescue with improved vaccine virus backbones, increasing the yield of the essential vaccine antigen, HA. Generation of synthetic vaccine seeds, together with more efficient vaccine release assays, would accelerate responses to influenza pandemics through a system of instantaneous electronic data exchange followed by real-time, geographically dispersed vaccine production.

Published

2013

9. Creating Bacterial Strains from Genomes That Have Been Cloned and Engineered in Yeast

Author

Nina Alperovich, Vladimir N. Noskov, John I. Glass, Evgeniya A. Denisova, Chuck Merryman, Daniel G. Gibson, Sanjay Vashee, Carole Lartigue, Li Ma, Hamilton O. Smith, Mikkel A. Algire, Gwynedd A. Benders, David W. Thomas, Clyde A. Hutchison, Nacyra Assad-Garcia, J. Craig Venter, Ray-Yuan Chuang, and The J. Craig Venter Institute, 9704 Medical Center Drive, Rockville, Maryland 20850, USA

Subjects

Yeast artificial chromosome, [SDV]Life Sciences [q-bio], Centromere, Bacterial genome size, Saccharomyces cerevisiae, Genome, Mycoplasma capricolum, Microbiology, 03 medical and health sciences, Synthetic biology, Plasmid, Cloning, Molecular, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, Sequence Deletion, Genetics, 0303 health sciences, Multidisciplinary, biology, 030306 microbiology, Gene Transfer Techniques, Mycoplasma mycoides, DNA Restriction Enzymes, Sequence Analysis, DNA, DNA Methylation, biology.organism_classification, Yeast, Transformation, Bacterial, Deoxyribonucleases, Type III Site-Specific, Genetic Engineering, Genome, Bacterial, Plasmids

Abstract

Character Transplant When engineering bacteria, it can be advantageous to propagate the genomes in yeast. However, to be truly useful, one must be able to transplant the bacterial chromosome from yeast back into a recipient bacterial cell. But because yeast does not contain restriction-modification systems, such transplantation poses problems not encountered in transplantation from one bacterial cell to another. Bacterial genomes isolated after growth in yeast are likely to be susceptible to the restriction-modification system(s) of the recipient cell, as well as their own. Lartigue et al. (p. 1693 , published online 20 August) describe multiple steps, including in vitro DNA methylation, developed to overcome such barriers. A Mycoplasma mycoides large-colony genome was propagated in yeast as a centromeric plasmid, engineered via yeast genetic systems, and, after specific methylation, transplanted into M. capricolum to produce a bacterial cell with the genotype and phenotype of the altered M. mycoides large-colony genome.

Published

2009

10. Genome transplantation in bacteria: changing one species to another

Author

John I. Glass, J. Craig Venter, Rembert Pieper, Carole Lartigue, Prashanth P. Parmar, Nina Alperovich, Clyde A. Hutchison, Hamilton O. Smith, and The J. Craig Venter Institute, 9704 Medical Center Drive, Rockville, Maryland 20850, USA

Subjects

DNA, Bacterial, Genotype, Proteome, [SDV]Life Sciences [q-bio], Molecular Sequence Data, medicine.disease_cause, Genome, Mycoplasma capricolum, Polyethylene Glycols, 03 medical and health sciences, Mycoplasma, medicine, Amino Acid Sequence, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, Genetics, Recombination, Genetic, 0303 health sciences, Multidisciplinary, biology, 030306 microbiology, Acetate Kinase, Chromosome, Mycoplasma mycoides, Sequence Analysis, DNA, biology.organism_classification, Molecular biology, Transplantation, genomic DNA, Phenotype, Naked DNA, Transformation, Bacterial, Genome, Bacterial

Abstract

As a step toward propagation of synthetic genomes, we completely replaced the genome of a bacterial cell with one from another species by transplanting a whole genome as naked DNA. Intact genomic DNA from Mycoplasma mycoides large colony (LC), virtually free of protein, was transplanted into Mycoplasma capricolum cells by polyethylene glycol–mediated transformation. Cells selected for tetracycline resistance, carried by the M. mycoides LC chromosome, contain the complete donor genome and are free of detectable recipient genomic sequences. These cells that result from genome transplantation are phenotypically identical to the M. mycoides LC donor strain as judged by several criteria.

Published

2007

11. Simultaneous non-contiguous deletions using large synthetic DNA and site-specific recombinases

Author

Chuck Merryman, Jayshree Zaveri, Radha Krishnakumar, Nina Alperovich, John I. Glass, Daniel H. Haft, Daniel G. Gibson, and Carissa Grose

Subjects

Genetics, Recombination, Genetic, Genome evolution, Integrases, Genome project, DNA, Genomics, Biology, Genome, Genome engineering, Synthetic biology, Recombinase, Escherichia coli, Methods Online, Genomic library, Synthetic Biology, Cre-Lox recombination, Chromosome Deletion, Genetic Engineering, Genome, Bacterial

Abstract

Toward achieving rapid and large scale genome modification directly in a target organism, we have developed a new genome engineering strategy that uses a combination of bioinformatics aided design, large synthetic DNA and site-specific recombinases. Using Cre recombinase we swapped a target 126-kb segment of the Escherichia coli genome with a 72-kb synthetic DNA cassette, thereby effectively eliminating over 54 kb of genomic DNA from three non-contiguous regions in a single recombination event. We observed complete replacement of the native sequence with the modified synthetic sequence through the action of the Cre recombinase and no competition from homologous recombination. Because of the versatility and high-efficiency of the Cre-lox system, this method can be used in any organism where this system is functional as well as adapted to use with other highly precise genome engineering systems. Compared to present-day iterative approaches in genome engineering, we anticipate this method will greatly speed up the creation of reduced, modularized and optimized genomes through the integration of deletion analyses data, transcriptomics, synthetic biology and site-specific recombination.

Published

2014