Your search keyword '"Allison Hoynes-O'Connor"' showing total 10 results

1. Diurnal Regulation of Cellular Processes in the Cyanobacterium Synechocystis sp. Strain PCC 6803: Insights from Transcriptomic, Fluxomic, and Physiological Analyses

Author

Rajib Saha, Deng Liu, Allison Hoynes-O’Connor, Michelle Liberton, Jingjie Yu, Maitrayee Bhattacharyya-Pakrasi, Andrea Balassy, Fuzhong Zhang, Tae Seok Moon, Costas D. Maranas, and Himadri B. Pakrasi

Subjects

Microbiology, QR1-502

Abstract

ABSTRACT Synechocystis sp. strain PCC 6803 is the most widely studied model cyanobacterium, with a well-developed omics level knowledgebase. Like the lifestyles of other cyanobacteria, that of Synechocystis PCC 6803 is tuned to diurnal changes in light intensity. In this study, we analyzed the expression patterns of all of the genes of this cyanobacterium over two consecutive diurnal periods. Using stringent criteria, we determined that the transcript levels of nearly 40% of the genes in Synechocystis PCC 6803 show robust diurnal oscillating behavior, with a majority of the transcripts being upregulated during the early light period. Such transcripts corresponded to a wide array of cellular processes, such as light harvesting, photosynthetic light and dark reactions, and central carbon metabolism. In contrast, transcripts of membrane transporters for transition metals involved in the photosynthetic electron transport chain (e.g., iron, manganese, and copper) were significantly upregulated during the late dark period. Thus, the pattern of global gene expression led to the development of two distinct transcriptional networks of coregulated oscillatory genes. These networks help describe how Synechocystis PCC 6803 regulates its metabolism toward the end of the dark period in anticipation of efficient photosynthesis during the early light period. Furthermore, in silico flux prediction of important cellular processes and experimental measurements of cellular ATP, NADP(H), and glycogen levels showed how this diurnal behavior influences its metabolic characteristics. In particular, NADPH/NADP+ showed a strong correlation with the majority of the genes whose expression peaks in the light. We conclude that this ratio is a key endogenous determinant of the diurnal behavior of this cyanobacterium. IMPORTANCE Cyanobacteria are photosynthetic microbes that use energy from sunlight and CO2 as feedstock. Certain cyanobacterial strains are amenable to facile genetic manipulation, thus enabling synthetic biology and metabolic engineering applications. Such strains are being developed as a chassis for the sustainable production of food, feed, and fuel. To this end, a holistic knowledge of cyanobacterial physiology and its correlation with gene expression patterns under the diurnal cycle is warranted. In this report, a genomewide transcriptional analysis of Synechocystis PCC 6803, the most widely studied model cyanobacterium, sheds light on the global coordination of cellular processes during diurnal periods. Furthermore, we found that, in addition to light, the redox level of NADP(H) is an important endogenous regulator of diurnal entrainment of Synechocystis PCC 6803.

Published

2016

2. Enabling complex genetic circuits to respond to extrinsic environmental signals

Author

Allison Hoynes-O'Connor, Tae Seok Moon, John Philip Creamer, Tatenda Shopera, and Kristina Hinman

Subjects

Salmonella typhimurium, 0301 basic medicine, Computer science, Signal Processing, Computer-Assisted, Bioengineering, Nanotechnology, Construct (python library), NAND logic, Applied Microbiology and Biotechnology, Metabolic engineering, Set (abstract data type), Computers, Molecular, 03 medical and health sciences, 030104 developmental biology, Computer architecture, Escherichia coli, Type III Secretion Systems, Circuit architecture, Gene Regulatory Networks, Synthetic Biology, AND gate, Signal Transduction, Hardware_LOGICDESIGN, Biotechnology, Electronic circuit

Abstract

Genetic circuits have the potential to improve a broad range of metabolic engineering processes and address a variety of medical and environmental challenges. However, in order to engineer genetic circuits that can meet the needs of these real-world applications, genetic sensors that respond to relevant extrinsic and intrinsic signals must be implemented in complex genetic circuits. In this work, we construct the first AND and NAND gates that respond to temperature and pH, two signals that have relevance in a variety of real-world applications. A previously identified pH-responsive promoter and a temperature-responsive promoter were extracted from the E. coli genome, characterized, and modified to suit the needs of the genetic circuits. These promoters were combined with components of the type III secretion system in Salmonella typhimurium and used to construct a set of AND gates with up to 23-fold change. Next, an antisense RNA was integrated into the circuit architecture to invert the logic of the AND gate and generate a set of NAND gates with up to 1168-fold change. These circuits provide the first demonstration of complex pH- and temperature-responsive genetic circuits, and lay the groundwork for the use of similar circuits in real-world applications. Biotechnol. Bioeng. 2017;114: 1626-1631. © 2017 Wiley Periodicals, Inc.

Published

2017

3. Development of Design Rules for Reliable Antisense RNA Behavior in E. coli

Author

Allison Hoynes-O'Connor and Tae Seok Moon

Subjects

0301 basic medicine, Orthogonality (programming), 030106 microbiology, Biomedical Engineering, Gene regulatory network, Computational biology, Host Factor 1 Protein, Biology, DNA Mismatch Repair, Biochemistry, Genetics and Molecular Biology (miscellaneous), 03 medical and health sciences, Synthetic biology, Escherichia coli, Gene Regulatory Networks, RNA, Antisense, RNA, Messenger, Genetics, Regulation of gene expression, Escherichia coli Proteins, Rational design, Reproducibility of Results, Gene Expression Regulation, Bacterial, General Medicine, Antisense RNA, Nucleic Acid Conformation, Thermodynamics, Synthetic Biology, Transcription Initiation Site, Carrier Proteins, Target binding, Plasmids

Abstract

A key driver of synthetic biology is the development of designable genetic parts with predictable behaviors that can be quickly implemented in complex genetic systems. However, the intrinsic complexity of gene regulation can make the rational design of genetic parts challenging. This challenge is apparent in the design of antisense RNA (asRNA) regulators. Though asRNAs are well-known regulators, the literature governing their design is conflicting and leaves the synthetic biology community without clear asRNA design rules. The goal of this study is to perform a comprehensive experimental characterization and statistical analysis of 121 unique asRNA regulators in order to resolve the conflicts that currently exist in the literature. asRNAs usually consist of two regions, the Hfq binding site and the target binding region (TBR). First, the behaviors of several high-performing Hfq binding sites were compared, in terms of their ability to improve repression efficiencies and their orthogonality. Next, a large-scale analysis of TBR design parameters identified asRNA length, the thermodynamics of asRNA-mRNA complex formation, and the percent of target mismatch as key parameters for TBR design. These parameters were used to develop simple asRNA design rules. Finally, these design rules were applied to construct both a simple and a complex genetic circuit containing different asRNAs, and predictable behavior was observed in both circuits. The results presented in this study will drive synthetic biology forward by providing useful design guidelines for the construction of asRNA regulators with predictable behaviors.

Published

2016

4. Programmable genetic circuits for pathway engineering

Author

Tae Seok Moon and Allison Hoynes-O'Connor

Subjects

business.industry, In silico, Biomedical Engineering, Gene regulatory network, Bioengineering, Biology, Programmable circuits, Biotechnology, Metabolic engineering, Synthetic biology, Gene Expression Regulation, Metabolic Engineering, Gene Targeting, CRISPR, Gene Regulatory Networks, Synthetic Biology, Biochemical engineering, business, Metabolic Networks and Pathways, Electronic circuit, Pathway engineering

Abstract

Synthetic biology has the potential to provide decisive advances in genetic control of metabolic pathways. However, there are several challenges that synthetic biologists must overcome before this vision becomes a reality. First, a library of diverse and well-characterized sensors, such as metabolite-sensing or condition-sensing promoters, must be constructed. Second, robust programmable circuits that link input conditions with a specific gene regulation response must be developed. Finally, multi-gene targeting strategies must be integrated with metabolically relevant sensors and complex, robust logic. Achievements in each of these areas, which employ the CRISPR/Cas system, in silico modeling, and dynamic sensor-regulators, among other tools, provide a strong basis for future research. Overall, the future for synthetic biology approaches in metabolic engineering holds immense promise.

Published

2015

5. De novodesign of heat-repressible RNA thermosensors inE. coli

Author

Kristina Hinman, Tae Seok Moon, Lukas Kirchner, and Allison Hoynes-O'Connor

Subjects

Genetics, Regulation of gene expression, Untranslated region, Hot Temperature, Transcription, Genetic, RNase P, RNA, Gene Expression Regulation, Bacterial, Biology, Cell biology, Ribosomal binding site, Synthetic biology, Protein Biosynthesis, Endoribonucleases, Gene expression, Escherichia coli, Protein biosynthesis, Synthetic Biology and Bioengineering

Abstract

RNA-based temperature sensing is common in bacteria that live in fluctuating environments. Most naturally-occurring RNA thermosensors are heat-inducible, have long sequences, and function by sequestering the ribosome binding site in a hairpin structure at lower temperatures. Here, we demonstrate the de novo design of short, heat-repressible RNA thermosensors. These thermosensors contain a cleavage site for RNase E, an enzyme native to Escherichia coli and many other organisms, in the 5′ untranslated region of the target gene. At low temperatures, the cleavage site is sequestered in a stem–loop, and gene expression is unobstructed. At high temperatures, the stem–loop unfolds, allowing for mRNA degradation and turning off expression. We demonstrated that these thermosensors respond specifically to temperature and provided experimental support for the central role of RNase E in the mechanism. We also demonstrated the modularity of these RNA thermosensors by constructing a three-input composite circuit that utilizes transcriptional, post-transcriptional, and post-translational regulation. A thorough analysis of the 24 thermosensors allowed for the development of design guidelines for systematic construction of similar thermosensors in future applications. These short, modular RNA thermosensors can be applied to the construction of complex genetic circuits, facilitating rational reprogramming of cellular processes for synthetic biology applications.

Published

2015

6. Diurnal Regulation of Cellular Processes in the Cyanobacterium Synechocystis sp. Strain PCC 6803: Insights from Transcriptomic, Fluxomic, and Physiological Analyses

Author

Costas D. Maranas, Himadri B. Pakrasi, Michelle Liberton, Allison Hoynes-O'Connor, Andrea Balassy, Tae Seok Moon, Jingjie Yu, Deng Liu, Fuzhong Zhang, Maitrayee Bhattacharyya-Pakrasi, and Rajib Saha

Subjects

0301 basic medicine, Cyanobacteria, 030106 microbiology, Photosynthesis, Microbiology, Metabolic engineering, 03 medical and health sciences, Diurnal cycle, Virology, Metabolic flux analysis, Gene Regulatory Networks, 2. Zero hunger, Regulation of gene expression, biology, Chemistry, Gene Expression Profiling, Synechocystis, Gene Expression Regulation, Bacterial, biology.organism_classification, Metabolic Flux Analysis, QR1-502, Circadian Rhythm, Cell biology, Light intensity, Metabolic Networks and Pathways, Research Article

Abstract

Synechocystis sp. strain PCC 6803 is the most widely studied model cyanobacterium, with a well-developed omics level knowledgebase. Like the lifestyles of other cyanobacteria, that of Synechocystis PCC 6803 is tuned to diurnal changes in light intensity. In this study, we analyzed the expression patterns of all of the genes of this cyanobacterium over two consecutive diurnal periods. Using stringent criteria, we determined that the transcript levels of nearly 40% of the genes in Synechocystis PCC 6803 show robust diurnal oscillating behavior, with a majority of the transcripts being upregulated during the early light period. Such transcripts corresponded to a wide array of cellular processes, such as light harvesting, photosynthetic light and dark reactions, and central carbon metabolism. In contrast, transcripts of membrane transporters for transition metals involved in the photosynthetic electron transport chain (e.g., iron, manganese, and copper) were significantly upregulated during the late dark period. Thus, the pattern of global gene expression led to the development of two distinct transcriptional networks of coregulated oscillatory genes. These networks help describe how Synechocystis PCC 6803 regulates its metabolism toward the end of the dark period in anticipation of efficient photosynthesis during the early light period. Furthermore, in silico flux prediction of important cellular processes and experimental measurements of cellular ATP, NADP(H), and glycogen levels showed how this diurnal behavior influences its metabolic characteristics. In particular, NADPH/NADP+ showed a strong correlation with the majority of the genes whose expression peaks in the light. We conclude that this ratio is a key endogenous determinant of the diurnal behavior of this cyanobacterium., IMPORTANCE Cyanobacteria are photosynthetic microbes that use energy from sunlight and CO2 as feedstock. Certain cyanobacterial strains are amenable to facile genetic manipulation, thus enabling synthetic biology and metabolic engineering applications. Such strains are being developed as a chassis for the sustainable production of food, feed, and fuel. To this end, a holistic knowledge of cyanobacterial physiology and its correlation with gene expression patterns under the diurnal cycle is warranted. In this report, a genomewide transcriptional analysis of Synechocystis PCC 6803, the most widely studied model cyanobacterium, sheds light on the global coordination of cellular processes during diurnal periods. Furthermore, we found that, in addition to light, the redox level of NADP(H) is an important endogenous regulator of diurnal entrainment of Synechocystis PCC 6803.

Published

2016

7. Non-tenera Contamination and the Economic Impact of SHELL Genetic Testing in the Malaysian Independent Oil Palm Industry

Author

Anthony D. Favello, Jared M. Ordway, Allison Hoynes-O’Connor, Ngoot C. Ting, Meilina Ong Abdullah, Mohamad Arif Abdul Manaf, Abdul J. Murad, Nathan D. Lakey, Mohd Amin Ab Halim, Shabani Bahrain, Rajinder Singh, Muhammad A. Budiman, Amelia Y. Nguyen, Michael T. Leininger, Clyde R. Brown, Hemangi G. Chaudhari, Leslie Cheng-Li Ooi, Alex C. S. Kuek, Jayanthi Nagappan, Shivam A. Shah, Melissa Beil, Nan Jiang, Norazah Azizi, Eng-Ti Leslie Low, Rajanaidu Nookiah, Kuang-Lim Chan, Andrew Van Brunt, Ravigadevi Sambanthamurthi, Yuen-May Choo, Wahid Omar, and Steven W. Smith

Subjects

0106 biological sciences, 0301 basic medicine, Heterosis, Plant Science, Elaeis guineensis, oil palm, 01 natural sciences, genetic testing, Crop, 03 medical and health sciences, Yield (wine), Tenera, Original Research, Hybrid, biology, business.industry, food and beverages, Sowing, tenera, fruit form, biology.organism_classification, Biotechnology, Horticulture, 030104 developmental biology, shell, business, Palm, 010606 plant biology & botany

Abstract

Oil palm (Elaeis guineensis) is the most productive oil bearing crop worldwide. It has three fruit forms, namely dura (thick-shelled), pisifera (shell-less) and tenera (thin-shelled), which are controlled by the SHELL gene. The fruit forms exhibit monogenic co-dominant inheritance, where tenera is a hybrid obtained by crossing maternal dura and paternal pisifera palms. Commercial palm oil production is based on planting thin-shelled tenera palms, which typically yield 30% more oil than dura palms, while pisifera palms are female-sterile and have little to no palm oil yield. It is clear that tenera hybrids produce more oil than either parent due to single gene heterosis. The unintentional planting of dura or pisifera palms reduces overall yield and impacts land utilization that would otherwise be devoted to more productive tenera palms. Here, we identify three additional novel mutant alleles of the SHELL gene, which encode a type II MADS-box transcription factor, and determine oil yield via control of shell fruit form phenotype in a manner similar to two previously identified mutant SHELL alleles. Assays encompassing all five mutations account for all dura and pisifera palms analyzed. By assaying for these variants in 10,224 mature palms or seedlings, we report the first large scale accurate genotype-based determination of the fruit forms in independent oil palm planting sites and in the nurseries that supply them throughout Malaysia. The measured non-tenera contamination rate (10.9% overall on a weighted average basis) underscores the importance of SHELL genetic testing of seedlings prior to planting in production fields. By eliminating non-tenera contamination, comprehensive SHELL genetic testing can improve sustainability by increasing yield on existing planted lands. In addition, economic modeling demonstrates that SHELL gene testing will confer substantial annual economic gains to the oil palm industry, to Malaysian gross national income and to Malaysian government tax receipts.

Published

2016

8. Programmable control of bacterial gene expression with the combined CRISPR and antisense RNA system

Author

Young Je Lee, Tae Seok Moon, Matthew C. Leong, and Allison Hoynes-O'Connor

Subjects

0106 biological sciences, 0301 basic medicine, Streptococcus pyogenes, Green Fluorescent Proteins, Computational biology, Biology, 01 natural sciences, 03 medical and health sciences, Genes, Reporter, 010608 biotechnology, Gene expression, Genetics, Escherichia coli, CRISPR, Clustered Regularly Interspaced Short Palindromic Repeats, RNA, Antisense, Guide RNA, CRISPR interference, Cas9, fungi, RNA, Nucleic Acid Hybridization, Gene Expression Regulation, Bacterial, Antisense RNA, RNA silencing, 030104 developmental biology, Drug Design, Gene Targeting, Synthetic Biology and Bioengineering, Plasmids, RNA, Guide, Kinetoplastida

Abstract

A central goal of synthetic biology is to implement diverse cellular functions by predictably controlling gene expression. Though research has focused more on protein regulators than RNA regulators, recent advances in our understanding of RNA folding and functions have motivated the use of RNA regulators. RNA regulators provide an advantage because they are easier to design and engineer than protein regulators, potentially have a lower burden on the cell and are highly orthogonal. Here, we combine the CRISPR system from Streptococcus pyogenes and synthetic antisense RNAs (asRNAs) in Escherichia coli strains to repress or derepress a target gene in a programmable manner. Specifically, we demonstrate for the first time that the gene target repressed by the CRISPR system can be derepressed by expressing an asRNA that sequesters a small guide RNA (sgRNA). Furthermore, we demonstrate that tunable levels of derepression can be achieved (up to 95%) by designing asRNAs that target different regions of a sgRNA and by altering the hybridization free energy of the sgRNA-asRNA complex. This new system, which we call the combined CRISPR and asRNA system, can be used to reversibly repress or derepress multiple target genes simultaneously, allowing for rational reprogramming of cellular functions.

Published

2016

9. Bridging the gap between systems biology and synthetic biology

Author

Fuzhong Zhang, Allison Hoynes-O'Connor, and Di Liu

Subjects

Microbiology (medical), Computer science, Modelling biological systems, Systems biology, Systems Biology, lcsh:QR1-502, Genomics, Computational biology, Proteomics, Microbiology, lcsh:Microbiology, Bridging (programming), Systems medicine, Mini Review Article, Synthetic biology, Metabolic Engineering, Synthetic Biology, cell factory, Biochemical engineering, microbial engineering, Organism

Abstract

Systems biology is an inter-disciplinary science that studies the complex interactions and the collective behavior of a cell or an organism. Synthetic biology, as a technological subject, combines biological science and engineering, allowing the design and manipulation of a system for certain applications. Both systems and synthetic biology have played important roles in the recent development of microbial platforms for energy, materials, and environmental applications. More importantly, systems biology provides the knowledge necessary for the development of synthetic biology tools, which in turn facilitates the manipulation and understanding of complex biological systems. Thus, the combination of systems and synthetic biology has huge potential for studying and engineering microbes, especially to perform advanced tasks, such as producing biofuels. Although there have been very few studies in integrating systems and synthetic biology, existing examples have demonstrated great power in extending microbiological capabilities. This review focuses on recent efforts in microbiological genomics, transcriptomics, proteomics, and metabolomics, aiming to fill the gap between systems and synthetic biology.

Published

2013

10. Microbial production of isoprenoids enabled by synthetic biology

Author

Allison Hoynes-O'Connor, Cheryl M. Immethun, Andrea Balassy, and Tae Seok Moon

Subjects

Microbiology (medical), Research groups, isoprenoids, business.industry, Mini Review, lcsh:QR1-502, Biology, Microbiology, Terpenoid, lcsh:Microbiology, Biotechnology, Metabolic engineering, Synthetic biology, Metabolic Engineering, Synthetic Biology, Biochemical engineering, microbial biosynthesis, business, health industry

Abstract

Microorganisms transform inexpensive carbon sources into highly functionalized compounds without toxic by-product generation or significant energy consumption. By redesigning the natural biosynthetic pathways in an industrially suited host, microbial cell factories can produce complex compounds for a variety of industries. Isoprenoids include many medically important compounds such as antioxidants and anticancer and antimalarial drugs, all of which have been produced microbially. While a biosynthetic pathway could be simply transferred to the production host, the titers would become economically feasible when it is rationally designed, built, and optimized through synthetic biology tools. These tools have been implemented by a number of research groups, with new tools pledging further improvements in yields and expansion to new medically relevant compounds. This review focuses on the microbial production of isoprenoids for the health industry and the advancements though synthetic biology.

Published

2013