Your search keyword '"Diana Eng"' showing total 7 results

1. Correction: Loss of Abdominal Muscle in Mutants Associated with Altered Axial Specification of Lateral Plate Mesoderm.

Author

Diana Eng, Hsiao-Yen Ma, Jun Xu, Hung-Ping Shih, Michael K. Gross, and Chrissa Kiouss

Subjects

Medicine, Science

Published

2012

2. Loss of abdominal muscle in Pitx2 mutants associated with altered axial specification of lateral plate mesoderm.

Author

Diana Eng, Hsiao-Yen Ma, Jun Xu, Hung-Ping Shih, Michael K Gross, and Chrissa Kioussi

Subjects

Medicine, Science

Abstract

Sequence specific transcription factors (SSTFs) combinatorially define cell types during development by forming recursively linked network kernels. Pitx2 expression begins during gastrulation, together with Hox genes, and becomes localized to the abdominal lateral plate mesoderm (LPM) before the onset of myogenesis in somites. The somatopleure of Pitx2 null embryos begins to grow abnormally outward before muscle regulatory factors (MRFs) or Pitx2 begin expression in the dermomyotome/myotome. Abdominal somites become deformed and stunted as they elongate into the mutant body wall, but maintain normal MRF expression domains. Subsequent loss of abdominal muscles is therefore not due to defects in specification, determination, or commitment of the myogenic lineage. Microarray analysis was used to identify SSTF families whose expression levels change in E10.5 interlimb body wall biopsies. All Hox9-11 paralogs had lower RNA levels in mutants, whereas genes expressed selectively in the hypaxial dermomyotome/myotome and sclerotome had higher RNA levels in mutants. In situ hybridization analyses indicate that Hox gene expression was reduced in parts of the LPM and intermediate mesoderm of mutants. Chromatin occupancy studies conducted on E10.5 interlimb body wall biopsies showed that Pitx2 protein occupied chromatin sites containing conserved bicoid core motifs in the vicinity of Hox 9-11 and MRF genes. Taken together, the data indicate that Pitx2 protein in LPM cells acts, presumably in combination with other SSTFs, to repress gene expression, that are normally expressed in physically adjoining cell types. Pitx2 thereby prevents cells in the interlimb LPM from adopting the stable network kernels that define sclerotomal, dermomyotomal, or myotomal mesenchymal cell types. This mechanism may be viewed either as lineage restriction or specification.

Published

2012

3. High-level production of amorpha-4,11-diene, a precursor of the antimalarial agent artemisinin, in Escherichia coli.

Author

Hiroko Tsuruta, Christopher J Paddon, Diana Eng, Jacob R Lenihan, Tizita Horning, Larry C Anthony, Rika Regentin, Jay D Keasling, Neil S Renninger, and Jack D Newman

Subjects

Medicine, Science

Abstract

BackgroundArtemisinin derivatives are the key active ingredients in Artemisinin combination therapies (ACTs), the most effective therapies available for treatment of malaria. Because the raw material is extracted from plants with long growing seasons, artemisinin is often in short supply, and fermentation would be an attractive alternative production method to supplement the plant source. Previous work showed that high levels of amorpha-4,11-diene, an artemisinin precursor, can be made in Escherichia coli using a heterologous mevalonate pathway derived from yeast (Saccharomyces cerevisiae), though the reconstructed mevalonate pathway was limited at a particular enzymatic step.Methodology/ principal findingsBy combining improvements in the heterologous mevalonate pathway with a superior fermentation process, commercially relevant titers were achieved in fed-batch fermentations. Yeast genes for HMG-CoA synthase and HMG-CoA reductase (the second and third enzymes in the pathway) were replaced with equivalent genes from Staphylococcus aureus, more than doubling production. Amorpha-4,11-diene titers were further increased by optimizing nitrogen delivery in the fermentation process. Successful cultivation of the improved strain under carbon and nitrogen restriction consistently yielded 90 g/L dry cell weight and an average titer of 27.4 g/L amorpha-4,11-diene.Conclusions/ significanceProduction of >25 g/L amorpha-4,11-diene by fermentation followed by chemical conversion to artemisinin may allow for development of a process to provide an alternative source of artemisinin to be incorporated into ACTs.

Published

2009

4. High-level semi-synthetic production of the potent antimalarial artemisinin

Author

Kirsten R. Benjamin, D. Dengrove, T. Treynor, Hanxiao Jiang, Darwin W. Reed, Karl Fisher, Douglas J. Pitera, S. Secrest, Kenneth W. Ellens, Patrick J. Westfall, M. Yu, Rika Regentin, T. Iqbal, A. Main, H. Tsuruta, Derek McPhee, Tizita Horning, R. Vazquez, S. Bajad, Ronald Henry, G. Dang, Keat H. Teoh, Jefferson C. Lievense, J. Galazzo, Scott Fickes, L. Kizer, Don Diola, Anna Tai, K. K. Reiling, B. Lieu, Patrick S. Covello, Lars F. Westblade, G. Dorin, Sara P. Gaucher, M. Fleck, Jacob R. Lenihan, M. Hepp, Michael D. Leavell, N. S. Renninger, Lishan Zhao, D. Melis, Diana Eng, Lan Xu, Jay D. Keasling, Christopher J. Paddon, Nathan A. Moss, T. Geistlinger, Jack D. Newman, Devin R Polichuk, and Yansheng Zhang

Subjects

expressed sequence tag, Artesunate, yeast, Artemisia annua, singlet oxygen, open reading frame, Semi synthetic, Synthetic biology, chemistry.chemical_compound, derivatization, oxidative stress, Malaria, Falciparum, Artemisinin, fermentation, photochemistry, Multidisciplinary, biology, stereochemistry, Artemisinins, enzyme activity, Genetic Engineering, drug potency, Biotechnology, medicine.drug, chemical reaction, esterification, Molecular Sequence Data, Plasmodium falciparum, malaria, biological production, Saccharomyces cerevisiae, Metabolic engineering, Antimalarials, parasitic diseases, medicine, protein expression, antimalarial agent, business.industry, extractive fermentation, biology.organism_classification, Combinatorial chemistry, disease treatment, Biosynthetic Pathways, artemisinin, chemistry, fed batch fermentation, Fermentation, business

Abstract

Saccharomyces cerevisiae is engineered to produce high concentrations of artemisinic acid, a precursor of the artemisinin used in combination therapies for malaria treatment; an efficient and practical chemical process to convert artemisinic acid to artemisinin is also developed. Artemisinin-based combination therapies are the treatment of choice for uncomplicated Plasmodium falciparum malaria, but the supply of plant-derived artemisinin can sometimes be unreliable, causing shortages and high prices. This manuscript describes a viable industrial process for the production of semisynthetic artemisinin, with the potential to help stabilize artemisinin supply. The process uses Saccharomyces cerevisiae yeast engineered to produce high yields of artemisinic acid, a precursor of artemisinin. The authors have also developed an efficient and scalable chemical process to convert artemisinic acid to artemisinin. In 2010 there were more than 200 million cases of malaria, and at least 655,000 deaths1. The World Health Organization has recommended artemisinin-based combination therapies (ACTs) for the treatment of uncomplicated malaria caused by the parasite Plasmodium falciparum. Artemisinin is a sesquiterpene endoperoxide with potent antimalarial properties, produced by the plant Artemisia annua. However, the supply of plant-derived artemisinin is unstable, resulting in shortages and price fluctuations, complicating production planning by ACT manufacturers2. A stable source of affordable artemisinin is required. Here we use synthetic biology to develop strains of Saccharomyces cerevisiae (baker’s yeast) for high-yielding biological production of artemisinic acid, a precursor of artemisinin. Previous attempts to produce commercially relevant concentrations of artemisinic acid were unsuccessful, allowing production of only 1.6 grams per litre of artemisinic acid3. Here we demonstrate the complete biosynthetic pathway, including the discovery of a plant dehydrogenase and a second cytochrome that provide an efficient biosynthetic route to artemisinic acid, with fermentation titres of 25 grams per litre of artemisinic acid. Furthermore, we have developed a practical, efficient and scalable chemical process for the conversion of artemisinic acid to artemisinin using a chemical source of singlet oxygen, thus avoiding the need for specialized photochemical equipment. The strains and processes described here form the basis of a viable industrial process for the production of semi-synthetic artemisinin to stabilize the supply of artemisinin for derivatization into active pharmaceutical ingredients (for example, artesunate) for incorporation into ACTs. Because all intellectual property rights have been provided free of charge, this technology has the potential to increase provision of first-line antimalarial treatments to the developing world at a reduced average annual price.

Published

2013

5. Production of amorphadiene in yeast, and its conversion to dihydroartemisinic acid, precursor to the antimalarial agent artemisinin

Author

David J. Melis, Michael D. Leavell, Chris J. Paddon, Diana Eng, Tizita Horning, Jack D. Newman, Neil Stephen Renninger, Jay D. Keasling, Jacob R. Lenihan, Patrick J. Westfall, Rika Regentin, Derek McPhee, Andrew Owens, Frank X. Woolard, Kirsten R. Benjamin, Scott Fickes, Don Diola, Douglas J. Pitera, and Hiroko Tsuruta

Subjects

Genotype, Genes, Fungal, Artemisia annua, Saccharomyces cerevisiae, Mevalonic acid, Biology, Sesquiterpene lactone, Antimalarials, chemistry.chemical_compound, parasitic diseases, medicine, Artemisinin, Codon, Polycyclic Sesquiterpenes, chemistry.chemical_classification, Multidisciplinary, Ethanol, Fungal genetics, Galactose, biology.organism_classification, Artemisinins, Metabolic pathway, Glucose, PNAS Plus, chemistry, Biochemistry, Batch Cell Culture Techniques, Fermentation, Mevalonate pathway, Sesquiterpenes, medicine.drug

Abstract

Malaria, caused by Plasmodium sp , results in almost one million deaths and over 200 million new infections annually. The World Health Organization has recommended that artemisinin-based combination therapies be used for treatment of malaria. Artemisinin is a sesquiterpene lactone isolated from the plant Artemisia annua . However, the supply and price of artemisinin fluctuate greatly, and an alternative production method would be valuable to increase availability. We describe progress toward the goal of developing a supply of semisynthetic artemisinin based on production of the artemisinin precursor amorpha-4,11-diene by fermentation from engineered Saccharomyces cerevisiae , and its chemical conversion to dihydroartemisinic acid, which can be subsequently converted to artemisinin. Previous efforts to produce artemisinin precursors used S. cerevisiae S288C overexpressing selected genes of the mevalonate pathway [Ro et al. (2006) Nature 440:940–943]. We have now overexpressed every enzyme of the mevalonate pathway to ERG20 in S. cerevisiae CEN.PK2, and compared production to CEN.PK2 engineered identically to the previously engineered S288C strain. Overexpressing every enzyme of the mevalonate pathway doubled artemisinic acid production, however, amorpha-4,11-diene production was 10-fold higher than artemisinic acid. We therefore focused on amorpha-4,11-diene production. Development of fermentation processes for the reengineered CEN.PK2 amorpha-4,11-diene strain led to production of > 40 g/L product. A chemical process was developed to convert amorpha-4,11-diene to dihydroartemisinic acid, which could subsequently be converted to artemisinin. The strains and procedures described represent a complete process for production of semisynthetic artemisinin.

Published

2012

6. High-level production of amorpha-4,11-diene, a precursor of the antimalarial agent artemisinin, in Escherichia coli

Author

Diana Eng, Tizita Horning, Christopher J. Paddon, Larry Cameron Anthony, Jacob R. Lenihan, Jack D. Newman, Jay D. Keasling, Neil Stephen Renninger, Rika Regentin, Hiroko Tsuruta, and Gregson, Aric

Subjects

Acetates, medicine.disease_cause, Biochemistry, chemistry.chemical_compound, Anti-Infective Agents, Biotechnology/Applied Microbiology, Antimalarial Agent, Malaria, Falciparum, Artemisinin, Child, Multidisciplinary, food and beverages, Artemisinins, Child, Preschool, Medicine, Biotechnology/Bioengineering, Mevalonate pathway, Sesquiterpenes, Research Article, Biotechnology, Infectious Diseases/Tropical and Travel-Associated Diseases, medicine.drug, Amorpha-4,11-diene, Falciparum, General Science & Technology, Science, Mevalonic Acid, Mevalonic acid, Saccharomyces cerevisiae, Biology, Antimalarials, Rare Diseases, Ammonia, Complementary and Integrative Health, Operon, parasitic diseases, medicine, Escherichia coli, Humans, Preschool, Polycyclic Sesquiterpenes, Infectious Diseases/Antimicrobials and Drug Resistance, Infectious Diseases/Protozoal Infections, Genetics and Genomics, Yeast, Malaria, Glucose, chemistry, Fermentation

Abstract

BackgroundArtemisinin derivatives are the key active ingredients in Artemisinin combination therapies (ACTs), the most effective therapies available for treatment of malaria. Because the raw material is extracted from plants with long growing seasons, artemisinin is often in short supply, and fermentation would be an attractive alternative production method to supplement the plant source. Previous work showed that high levels of amorpha-4,11-diene, an artemisinin precursor, can be made in Escherichia coli using a heterologous mevalonate pathway derived from yeast (Saccharomyces cerevisiae), though the reconstructed mevalonate pathway was limited at a particular enzymatic step.Methodology/ principal findingsBy combining improvements in the heterologous mevalonate pathway with a superior fermentation process, commercially relevant titers were achieved in fed-batch fermentations. Yeast genes for HMG-CoA synthase and HMG-CoA reductase (the second and third enzymes in the pathway) were replaced with equivalent genes from Staphylococcus aureus, more than doubling production. Amorpha-4,11-diene titers were further increased by optimizing nitrogen delivery in the fermentation process. Successful cultivation of the improved strain under carbon and nitrogen restriction consistently yielded 90 g/L dry cell weight and an average titer of 27.4 g/L amorpha-4,11-diene.Conclusions/ significanceProduction of >25 g/L amorpha-4,11-diene by fermentation followed by chemical conversion to artemisinin may allow for development of a process to provide an alternative source of artemisinin to be incorporated into ACTs.

Published

2009

7. Induction of multiple pleiotropic drug resistance genes in yeast engineered to produce an increased level of anti-malarial drug precursor, artemisinic acid

Author

Chris J. Paddon, Mario Ouellet, Jack D. Newman, Helcio Burd, Jay D. Keasling, Diana Eng, Dae-Kyun Ro, and Eric M. Paradise

Subjects

Technology, Drug Resistance, ATP-binding cassette transporter, Artemisia annua, Plasmid, Gene Expression Regulation, Fungal, Prodrugs, Artemisinin, Oligonucleotide Array Sequence Analysis, Genetics, Fungal genetics, Biological Sciences, Artemisinins, Infectious Diseases, Fungal, Biochemistry, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Genetic Engineering, Sesquiterpenes, Multiple, medicine.drug, Research Article, Plasmids, Biotechnology, lcsh:Biotechnology, Saccharomyces cerevisiae, Biology, Genes, Plant, Antimalarials, Rare Diseases, Drug Resistance, Multiple, Fungal, lcsh:TP248.13-248.65, medicine, Animals, Point Mutation, Polycyclic Sesquiterpenes, Gene Expression Profiling, RNA, Fungal, Plant, biology.organism_classification, Yeast, Malaria, Vector-Borne Diseases, Oxidative Stress, Good Health and Well Being, Gene Expression Regulation, Genes, Fermentation, RNA, Antimicrobial Resistance

Abstract

Background Due to the global occurrence of multi-drug-resistant malarial parasites (Plasmodium falciparum), the anti-malarial drug most effective against malaria is artemisinin, a natural product (sesquiterpene lactone endoperoxide) extracted from sweet wormwood (Artemisia annua). However, artemisinin is in short supply and unaffordable to most malaria patients. Artemisinin can be semi-synthesized from its precursor artemisinic acid, which can be synthesized from simple sugars using microorganisms genetically engineered with genes from A. annua. In order to develop an industrially competent yeast strain, detailed analyses of microbial physiology and development of gene expression strategies are required. Results Three plant genes coding for amorphadiene synthase, amorphadiene oxidase (AMO or CYP71AV1), and cytochrome P450 reductase, which in concert divert carbon flux from farnesyl diphosphate to artemisinic acid, were expressed from a single plasmid. The artemisinic acid production in the engineered yeast reached 250 μg mL-1 in shake-flask cultures and 1 g L-1 in bio-reactors with the use of Leu2d selection marker and appropriate medium formulation. When plasmid stability was measured, the yeast strain synthesizing amorphadiene alone maintained the plasmid in 84% of the cells, whereas the yeast strain synthesizing artemisinic acid showed poor plasmid stability. Inactivation of AMO by a point-mutation restored the high plasmid stability, indicating that the low plasmid stability is not caused by production of the AMO protein but by artemisinic acid synthesis or accumulation. Semi-quantitative reverse-transcriptase (RT)-PCR and quantitative real time-PCR consistently showed that pleiotropic drug resistance (PDR) genes, belonging to the family of ATP-Binding Cassette (ABC) transporter, were massively induced in the yeast strain producing artemisinic acid, relative to the yeast strain producing the hydrocarbon amorphadiene alone. Global transcriptional analysis by yeast microarray further demonstrated that the induction of drug-resistant genes such as ABC transporters and major facilitator superfamily (MSF) genes is the primary cellular stress-response; in addition, oxidative and osmotic stress responses were observed in the engineered yeast. Conclusion The data presented here suggest that the engineered yeast producing artemisinic acid suffers oxidative and drug-associated stresses. The use of plant-derived transporters and optimizing AMO activity may improve the yield of artemisinic acid production in the engineered yeast.

Published

2008