Your search keyword '"Andrew D. Hanson"' showing total 312 results

1. Comparative Genomic and Genetic Evidence on a Role for the OarX Protein in Thiamin Salvage

Author

Edmar R. Oliveira-Filho, Dmitry A. Rodionov, and Andrew D. Hanson

Subjects

Chemistry, QD1-999

Published

2024

2. Strangers in a foreign land: ‘Yeastizing’ plant enzymes

Author

Kristen Van Gelder, Steffen N. Lindner, Andrew D. Hanson, and Juannan Zhou

Subjects

Biotechnology, TP248.13-248.65

Abstract

Abstract Expressing plant metabolic pathways in microbial platforms is an efficient, cost‐effective solution for producing many desired plant compounds. As eukaryotic organisms, yeasts are often the preferred platform. However, expression of plant enzymes in a yeast frequently leads to failure because the enzymes are poorly adapted to the foreign yeast cellular environment. Here, we first summarize the current engineering approaches for optimizing performance of plant enzymes in yeast. A critical limitation of these approaches is that they are labour‐intensive and must be customized for each individual enzyme, which significantly hinders the establishment of plant pathways in cellular factories. In response to this challenge, we propose the development of a cost‐effective computational pipeline to redesign plant enzymes for better adaptation to the yeast cellular milieu. This proposition is underpinned by compelling evidence that plant and yeast enzymes exhibit distinct sequence features that are generalizable across enzyme families. Consequently, we introduce a data‐driven machine learning framework designed to extract ‘yeastizing’ rules from natural protein sequence variations, which can be broadly applied to all enzymes. Additionally, we discuss the potential to integrate the machine learning model into a full design‐build‐test cycle.

Published

2024

3. Transitioning Away from Fossil Fuels Will Drive Repositioning of Horticulture

Author

Danielle D. Treadwell, Lincoln Zotarelli, Peter J. Dittmar, Jeffrey G. Williamson, Marcio F.R. Resende Jr., Ana D. Martin-Ryals, Carlos Messina, Christopher C. Gunter, Andrew D. Hanson, and Simon P. Michaux

Subjects

diesel, electric power, fossil fuels, fruits, green energy, nitrogen fertilizer, refrigeration, transportation, vegetables, Plant culture, SB1-1110

Abstract

Like everything for the past 2 centuries, agriculture has depended increasingly on fossil fuel energy. Pressures to shift to renewable energy and changes in the fossil fuel industry are set to massively alter the energy landscape over the next 30 years. Two near-certainties are increased overall prices and/or decreased stability of energy supplies. The impacts of these upheavals on specialty crop production and consumption are unknowable in detail but the grand lines of what will likely change can be foreseen. This foresight can guide the research, extension, and teaching needed to successfully navigate a future very unlike the recent past. Major variables that will influence outcomes include energy use in fertilizer manufacture, in farm operations, and in haulage to centers of consumption. Taking six increasingly popular fruit and vegetable crops and the top two horticultural production states as examples, here we use simple proxies for the energy requirements (in gigajoules per ton of produce) of fertilizer, farm operations, and truck transport from Florida or California to New York to compare the relative sizes of these requirements. Trucking from California is the largest energy requirement in all cases, and three times larger than from Florida. As these energy requirements themselves are all fairly fixed, but in future will likely rise in price and/or be subject to interruptions and shortages, this pilot study points to two commonsense inferences: First, that fruit and vegetable production and consumption are set to reposition to more local/regional and seasonal patterns due to increasing expenses associated with fuel, and second, that coast-to-coast produce shipment by truck will become increasingly expensive and difficult.

Published

2024

4. Metabolite Damage and Damage Control in a Minimal Genome

Author

Drago Haas, Antje M. Thamm, Jiayi Sun, Lili Huang, Lijie Sun, Guillaume A. W. Beaudoin, Kim S. Wise, Claudia Lerma-Ortiz, Steven D. Bruner, Marian Breuer, Zaida Luthey-Schulten, Jiusheng Lin, Mark A. Wilson, Greg Brown, Alexander F. Yakunin, Inna Kurilyak, Jacob Folz, Oliver Fiehn, John I. Glass, Andrew D. Hanson, Christopher S. Henry, and Valérie de Crécy-Lagard

Subjects

comparative genomics, metabolite repair, metabolomics, minimal genome, hydrolase, Microbiology, QR1-502

Abstract

ABSTRACT Analysis of the genes retained in the minimized Mycoplasma JCVI-Syn3A genome established that systems that repair or preempt metabolite damage are essential to life. Several genes known to have such functions were identified and experimentally validated, including 5-formyltetrahydrofolate cycloligase, coenzyme A (CoA) disulfide reductase, and certain hydrolases. Furthermore, we discovered that an enigmatic YqeK hydrolase domain fused to NadD has a novel proofreading function in NAD synthesis and could double as a MutT-like sanitizing enzyme for the nucleotide pool. Finally, we combined metabolomics and cheminformatics approaches to extend the core metabolic map of JCVI-Syn3A to include promiscuous enzymatic reactions and spontaneous side reactions. This extension revealed that several key metabolite damage control systems remain to be identified in JCVI-Syn3A, such as that for methylglyoxal. IMPORTANCE Metabolite damage and repair mechanisms are being increasingly recognized. We present here compelling genetic and biochemical evidence for the universal importance of these mechanisms by demonstrating that stripping a genome down to its barest essentials leaves metabolite damage control systems in place. Furthermore, our metabolomic and cheminformatic results point to the existence of a network of metabolite damage and damage control reactions that extends far beyond the corners of it that have been characterized so far. In sum, there can be little room left to doubt that metabolite damage and the systems that counter it are mainstream metabolic processes that cannot be separated from life itself.

Published

2022

5. The Thiamin-Requiring 3 Mutation of Arabidopsis 5-Deoxyxylulose-Phosphate Synthase 1 Highlights How the Thiamin Economy Impacts the Methylerythritol 4-Phosphate Pathway

Author

Jaya Joshi, Manaki Mimura, Masaharu Suzuki, Shan Wu, Jesse F. Gregory, Andrew D. Hanson, and Donald R. McCarty

Subjects

thiamin, methylerythritol 4-phosphate pathway, 5-deoxyxylulose-phosphate synthase, thiamin requiring, retrograde signaling, biotic stress response, Plant culture, SB1-1110

Abstract

The thiamin-requiring mutants of Arabidopsis have a storied history as a foundational model for biochemical genetics in plants and have illuminated the central role of thiamin in metabolism. Recent integrative genetic and biochemical analyses of thiamin biosynthesis and utilization imply that leaf metabolism normally operates close to thiamin-limiting conditions. Thus, the mechanisms that allocate thiamin-diphosphate (ThDP) cofactor among the diverse thiamin-dependent enzymes localized in plastids, mitochondria, peroxisomes, and the cytosol comprise an intricate thiamin economy. Here, we show that the classical thiamin-requiring 3 (th3) mutant is a point mutation in plastid localized 5-deoxyxylulose synthase 1 (DXS1), a key regulated enzyme in the methylerythritol 4-phosphate (MEP) isoprene biosynthesis pathway. Substitution of a lysine for a highly conserved glutamate residue (E323) located at the subunit interface of the homodimeric enzyme conditions a hypomorphic phenotype that can be rescued by supplying low concentrations of thiamin in the medium. Analysis of leaf thiamin vitamers showed that supplementing the medium with thiamin increased total ThDP content in both wild type and th3 mutant plants, supporting a hypothesis that the mutant DXS1 enzyme has a reduced affinity for the ThDP cofactor. An unexpected upregulation of a suite of biotic-stress-response genes associated with accumulation of downstream MEP intermediate MEcPP suggests that th3 causes mis-regulation of DXS1 activity in thiamin-supplemented plants. Overall, these results highlight that the central role of ThDP availability in regulation of DXS1 activity and flux through the MEP pathway.

Published

2021

6. Salvage of the 5-deoxyribose byproduct of radical SAM enzymes

Author

Guillaume A. W. Beaudoin, Qiang Li, Jacob Folz, Oliver Fiehn, Justin L. Goodsell, Alexander Angerhofer, Steven D. Bruner, and Andrew D. Hanson

Subjects

Science

Abstract

5-Deoxyribose is formed from 5′-deoxyadenosine, a toxic byproduct of radical S-adenosylmethionine enzymes. Here, the authors identify and biochemically characterize a bacterial salvage pathway for 5-deoxyribose, consisting of three enzymes, and solve the crystal structure of the key aldolase.

Published

2018

7. A Core Metabolome Response of Maize Leaves Subjected to Long-Duration Abiotic Stresses

Author

Jaya Joshi, Ghulam Hasnain, Taylor Logue, Madeline Lynch, Shan Wu, Jiahn-Chou Guan, Saleh Alseekh, Alisdair R. Fernie, Andrew D. Hanson, and Donald R. McCarty

Subjects

drought, salinity, heat stress, metabolomics, RNA-seq, Microbiology, QR1-502

Abstract

Abiotic stresses reduce crop growth and yield in part by disrupting metabolic homeostasis and triggering responses that change the metabolome. Experiments designed to understand the mechanisms underlying these metabolomic responses have usually not used agriculturally relevant stress regimes. We therefore subjected maize plants to drought, salt, or heat stresses that mimic field conditions and analyzed leaf responses at metabolome and transcriptome levels. Shared features of stress metabolomes included synthesis of raffinose, a compatible solute implicated in tolerance to dehydration. In addition, a marked accumulation of amino acids including proline, arginine, and γ-aminobutyrate combined with depletion of key glycolysis and tricarboxylic acid cycle intermediates indicated a shift in balance of carbon and nitrogen metabolism in stressed leaves. Involvement of the γ-aminobutyrate shunt in this process is consistent with its previously proposed role as a workaround for stress-induced thiamin-deficiency. Although convergent metabolome shifts were correlated with gene expression changes in affected pathways, patterns of differential gene regulation induced by the three stresses indicated distinct signaling mechanisms highlighting the plasticity of plant metabolic responses to abiotic stress.

Published

2021

8. Potential for Applying Continuous Directed Evolution to Plant Enzymes: An Exploratory Study

Author

Jorge D. García-García, Jaya Joshi, Jenelle A. Patterson, Lidimarie Trujillo-Rodriguez, Christopher R. Reisch, Alex A. Javanpour, Chang C. Liu, and Andrew D. Hanson

Subjects

protein engineering, synthetic biology, linear plasmids, error-prone polymerases, CRISPR/Cas9, directed evolution, Science

Abstract

Plant evolution has produced enzymes that may not be optimal for maximizing yield and quality in today’s agricultural environments and plant biotechnology applications. By improving enzyme performance, it should be possible to alleviate constraints on yield and quality currently imposed by kinetic properties or enzyme instability. Enzymes can be optimized more quickly than naturally possible by applying directed evolution, which entails mutating a target gene in vitro and screening or selecting the mutated gene products for the desired characteristics. Continuous directed evolution is a more efficient and scalable version that accomplishes the mutagenesis and selection steps simultaneously in vivo via error-prone replication of the target gene and coupling of the host cell’s growth rate to the target gene’s function. However, published continuous systems require custom plasmid assembly, and convenient multipurpose platforms are not available. We discuss two systems suitable for continuous directed evolution of enzymes, OrthoRep in Saccharomyces cerevisiae and EvolvR in Escherichia coli, and our pilot efforts to adapt each system for high-throughput plant enzyme engineering. To test our modified systems, we used the thiamin synthesis enzyme THI4, previously identified as a prime candidate for improvement. Our adapted OrthoRep system shows promise for efficient plant enzyme engineering.

Published

2020

9. In Vivo Rate of Formaldehyde Condensation with Tetrahydrofolate

Author

Hai He, Elad Noor, Perla A. Ramos-Parra, Liliana E. García-Valencia, Jenelle A. Patterson, Rocío I. Díaz de la Garza, Andrew D. Hanson, and Arren Bar-Even

Subjects

one-carbon metabolism, spontaneous reaction, auxotrophy, serine cycle, phenotypic phase plane, Microbiology, QR1-502

Abstract

Formaldehyde is a highly reactive compound that participates in multiple spontaneous reactions, but these are mostly deleterious and damage cellular components. In contrast, the spontaneous condensation of formaldehyde with tetrahydrofolate (THF) has been proposed to contribute to the assimilation of this intermediate during growth on C1 carbon sources such as methanol. However, the in vivo rate of this condensation reaction is unknown and its possible contribution to growth remains elusive. Here, we used microbial platforms to assess the rate of this condensation in the cellular environment. We constructed Escherichia coli strains lacking the enzymes that naturally produce 5,10-methylene-THF. These strains were able to grow on minimal medium only when equipped with a sarcosine (N-methyl-glycine) oxidation pathway that sustained a high cellular concentration of formaldehyde, which spontaneously reacts with THF to produce 5,10-methylene-THF. We used flux balance analysis to derive the rate of the spontaneous condensation from the observed growth rate. According to this, we calculated that a microorganism obtaining its entire biomass via the spontaneous condensation of formaldehyde with THF would have a doubling time of more than three weeks. Hence, this spontaneous reaction is unlikely to serve as an effective route for formaldehyde assimilation.

Published

2020

10. Corrigendum: Divisions of labor in the thiamin biosynthetic pathway among organs of maize

Author

Jiahn-Chou Guan, Ghulam Hasnain, Timothy J. Garrett, Christine D. Chase, Jesse Gregory, Andrew D. Hanson, and Donald R. McCarty

Subjects

thiamin biosynthesis, comparative transcriptomics, maize development, pollen development, meristem metabolism, Plant culture, SB1-1110

Published

2018

11. Divisions of labor in the thiamin biosynthetic pathway among organs of maize

Author

Jiahn-Chou Guan, Ghulam Hasnain, Timothy J. Garrett, Christine D. Chase, Jesse Gregory, Andrew D. Hanson, and Donald R. McCarty

Subjects

thiamin biosynthesis, comparative transcriptomics, maize development, pollen development, meristem metabolism, Plant culture, SB1-1110

Abstract

The B vitamin thiamin is essential for central metabolism in all cellular organisms including plants. While plants synthesize thiamin de novo, organs vary widely in their capacities for thiamin synthesis. We use a transcriptomics approach to appraise the distribution of de novo synthesis and thiamin salvage pathways among organs of maize. We identify at least six developmental contexts in which metabolically active, non-photosynthetic organs exhibit low expression of one or both branches of the de novo thiamin biosynthetic pathway indicating a dependence on inter-cellular transport of thiamin and/or thiamin precursors. Neither the thiazole (THI4) nor pyrimidine (THIC) branches of the pathway are expressed in developing pollen implying a dependence on import of thiamin from surrounding floral and inflorescence organs. Consistent with that hypothesis, organs of the male inflorescence and flowers are shown to have high relative expression of the thiamin biosynthetic pathway and comparatively high thiamin contents. By contrast, divergent patterns of THIC and THI4 expression occur in the shoot apical meristem, embyro sac, embryo, endosperm, and root-tips suggesting that these sink organs acquire significant amounts of thiamin via salvage pathways. In the root and shoot meristems, expression of THIC in the absence of THI4 indicates a capacity for thiamin synthesis via salvage of thiazole, whereas the opposite pattern obtains in embryo and endosperm implying that seed storage organs are poised for pyrimidine salvage. Finally, stable isotope labeling experiments set an upper limit on the rate of de novo thiamin biosynthesis in maize leaf explants. Overall, the observed patterns of thiamin biosynthetic gene expression mirror the strategies for thiamin acquisition that have evolved in bacteria.

Published

2014

12. Why cutting respiratory CO 2 loss from crops is possible, practicable, and prudential

Author

Jaya Joshi, Jeffrey S. Amthor, Donald R. McCarty, Carlos D. Messina, Mark A. Wilson, A. Harvey Millar, and Andrew D. Hanson

Published

2023

13. Continuous Directed Evolution of a Feedback-Resistant Arabidopsis Arogenate Dehydratase in Plantized Escherichia coli

Author

Bryan J. Leong and Andrew D. Hanson

Subjects

Biomedical Engineering, General Medicine, Biochemistry, Genetics and Molecular Biology (miscellaneous)

Published

2022

14. Focus on respiration

Author

Andrew D Hanson, A Harvey Millar, Zoran Nikoloski, and Danielle A Way

Subjects

Physiology, Genetics, Plant Science

Published

2023

15. The Moderately (D)efficient Enzyme: Catalysis-Related Damage In Vivo and Its Repair

Author

Mark A. Wilson, Bryan J. Leong, Ulschan Bathe, Christopher S. Henry, Paul E. Abraham, Andrew D. Hanson, and Donald R. McCarty

Subjects

Life span, In vivo, Cheminformatics, Rational design, Collateral damage, Computational biology, Biology, Directed evolution, Proteomics, Biochemistry, Structural Biochemistry

Abstract

Enzymes have in vivo life spans. Analysis of life spans, i.e., lifetime totals of catalytic turnovers, suggests that nonsurvivable collateral chemical damage from the very reactions that enzymes catalyze is a common but underdiagnosed cause of enzyme death. Analysis also implies that many enzymes are moderately deficient in that their active-site regions are not naturally as hardened against such collateral damage as they could be, leaving room for improvement by rational design or directed evolution. Enzyme life span might also be improved by engineering systems that repair otherwise fatal active-site damage, of which a handful are known and more are inferred to exist. Unfortunately, the data needed to design and execute such improvements are lacking: there are too few measurements of in vivo life span, and existing information about the extent, nature, and mechanisms of active-site damage and repair during normal enzyme operation is too scarce, anecdotal, and speculative to act on. Fortunately, advances in proteomics, metabolomics, cheminformatics, comparative genomics, and structural biochemistry now empower a systematic, data-driven approach for identifying, predicting, and validating instances of active-site damage and its repair. These capabilities would be practically useful in enzyme redesign and improvement of in-use stability and could change our thinking about which enzymes die young in vivo, and why.

Published

2021

16. Structure and function of aerotolerant, multiple-turnover THI4 thiazole synthases

Author

Steven D. Bruner, Bryan J. Leong, You Hu, Qiang Li, Jaya Joshi, Andrew D. Hanson, and Jorge D. García-García

Subjects

Plant Biology, comparative genomics, medicine.disease_cause, Biochemistry, thiamin, chemistry.chemical_compound, Structural Biology, Catalytic Domain, Thiamine, Research Articles, chemistry.chemical_classification, biology, Escherichia coli Proteins, Cobalt, Genomics, Complementation, Microorganisms, Genetically-Modified, Crystallization, Saccharomyces cerevisiae Proteins, Sulfide, Stereochemistry, Bioinformatics, Archaeal Proteins, Iron, suicide enzyme, chemistry.chemical_element, Saccharomyces cerevisiae, Sulfides, Microbiology, Cofactor, thiazole biosynthesis, Chemical Biology, medicine, Escherichia coli, Cysteine, Thiazole, Molecular Biology, Bacteria, Prokaryote, Cell Biology, biology.organism_classification, Sulfur, Archaea, Hyperthermophile, Oxygen, chemistry, biology.protein, Biocatalysis

Abstract

Plant and fungal THI4 thiazole synthases produce the thiamin thiazole moiety in aerobic conditions via a single-turnover suicide reaction that uses an active-site Cys residue as sulfur donor. Multipleturnover (i.e. catalytic) THI4s lacking an active-site Cys (non-Cys THI4s) that use sulfide as sulfur donor have been characterized – but only from archaeal methanogens that are anaerobic, O2-sensitive hyperthermophiles from sulfide-rich habitats. These THI4s prefer iron as cofactor. A survey of prokaryote genomes uncovered non-Cys THI4s in aerobic mesophiles from sulfide-poor habitats, suggesting that multiple-turnover THI4 operation is possible in aerobic, mild, low-sulfide conditions. This was confirmed by testing 23 representative non-Cys THI4s for complementation of an Escherichia coli ΔthiG thiazole auxotroph in aerobic conditions. Sixteen were clearly active, and more so when intracellular sulfide level was raised by supplying Cys, demonstrating catalytic function in the presence of O2 at mild temperatures and indicating use of sulfide or a sulfide metabolite as sulfur donor. Comparative genomic evidence linked non-Cys THI4s with proteins from families that bind, transport, or metabolize cobalt or other heavy metals. The crystal structure of the aerotolerant bacterial Thermovibrio ammonificans THI4 was determined to probe the molecular basis of aerotolerance. The structure suggested no large deviations compared to the structures of THI4s from O2-sensitive methanogens, but is consistent with an alternative catalytic metal. Together with complementation data, the use of cobalt rather than iron was supported. We conclude that catalytic THI4s can indeed operate aerobically and that the metal cofactor inserted is a likely natural determinant of aerotolerance.

Published

2021

17. Directed evolution of aerotolerance in sulfide-dependent thiazole synthases

Author

Kristen Van Gelder, Edmar R. Oliveira-Filho, Jorge Donato García-García, You Hu, Steven D. Bruner, and Andrew D. Hanson

Subjects

Biomedical Engineering, General Medicine, Biochemistry, Genetics and Molecular Biology (miscellaneous)

Abstract

Sulfide-dependent THI4 thiazole synthases could potentially be used to replace plant cysteine-dependent suicide THI4s, whose high protein turnover rates make thiamin synthesis exceptionally energy-expensive. However, sulfide-dependent THI4s are anaerobic or microoxic enzymes and hence unadapted to the aerobic conditions in plants; they are also slow enzymes (kcat-1). To improve aerotolerance and activity, we applied continuous directed evolution under aerobic conditions in the yeast OrthoRep system to two sulfide-dependent bacterial THI4s. Six beneficial single mutations were identified, of which five lie in the active-site cleft predicted by structural modeling and two recapitulate features of naturally aerotolerant THI4s. That single mutations gave substantial improvements suggests that further advance under selection will be possible by stacking mutations. This proof-of-concept study established that the performance of sulfide-dependent THI4s in aerobic conditions is evolvable and, more generally, that yeast OrthoRep provides a plant-like bridge to adapt nonplant enzymes to work better in plants.

Published

2022

18. Respiratory energy demands and scope for demand expansion and destruction

Author

Ulschan Bathe, Bryan J Leong, Kristen Van Gelder, Guillaume G Barbier, Christopher S Henry, Jeffrey S Amthor, and Andrew D Hanson

Subjects

Physiology, Genetics, Plant Science

Abstract

Nonphotosynthetic plant metabolic processes are powered by respiratory energy, a limited resource that metabolic engineers—like plants themselves—must manage prudently.

Published

2022

19. Plant Physiology Synthetic Biology initiative

Author

Andrew D Hanson and Yunde Zhao

Subjects

Physiology, Genetics, Synthetic Biology, Plant Science, Focus Issue on Evolution of Plant Structure and Function, Plant Physiological Phenomena

Published

2022

20. In vivo hypermutation and continuous evolution

Author

Rosana S. Molina, Gordon Rix, Amanuella A. Mengiste, Beatriz Álvarez, Daeje Seo, Haiqi Chen, Juan E. Hurtado, Qiong Zhang, Jorge Donato García-García, Zachary J. Heins, Patrick J. Almhjell, Frances H. Arnold, Ahmad S. Khalil, Andrew D. Hanson, John E. Dueber, David V. Schaffer, Fei Chen, Seokhee Kim, Luis Ángel Fernández, Matthew D. Shoulders, and Chang C. Liu

Subjects

General Medicine, Article, General Biochemistry, Genetics and Molecular Biology

Published

2022

21. Fluoroacetate distribution, response to fluoridation, and synthesis in juvenile Gastrolobium bilobum plants

Author

Bryan J. Leong, Jacob S. Folz, Ulschan Bathe, David G. Clark, Oliver Fiehn, and Andrew D. Hanson

Subjects

S-Adenosylmethionine, Fluoridation, Fluoroacetates, Ribose, Serine, Plant Science, General Medicine, Horticulture, Plants, Molecular Biology, Biochemistry

Abstract

Like angiosperms from several other families, the leguminous shrub Gastrolobium bilobum R.Br. produces and accumulates fluoroacetate, indicating that it performs the difficult chemistry needed to make a C-F bond. Bioinformatic analyses indicate that plants lack homologs of the only enzymes known to make a C-F bond, i.e., the Actinomycete flurorinases that form 5'-fluoro-5'-deoxyadenosine from S-adenosylmethionine and fluoride ion. To probe the origin of fluoroacetate in G. bilobum we first showed that fluoroacetate accumulates to millimolar levels in young leaves but not older leaves, stems or roots, that leaf fluoroacetate levels vary20-fold between individual plants and are not markedly raised by sodium fluoride treatment. Young leaves were fed adenosine

Published

2022

22. Metabolite Damage and Damage-Control in a Minimal Genome

Author

Steven D. Bruner, Jacob Folz, John I. Glass, I. Inna Kurilyak, D. Haas, Christopher S. Henry, Oliver Fiehn, Alexander F. Yakunin, Jiusheng Lin, Andrew D. Hanson, Kim S. Wise, J. Sun, V. de Crecy-Lagard, Marian Breuer, Antje M. K. Thamm, Zaida Luthey-Schulten, Mark A. Wilson, Claudia Lerma-Ortiz, Lili Huang, Greg Brown, Lijie Sun, and Guillaume A.W. Beaudoin

Subjects

chemistry.chemical_classification, chemistry.chemical_compound, Enzyme, Metabolomics, chemistry, Biochemistry, Metabolite, Hydrolase, Minimal genome, Genome, Gene, Function (biology)

Abstract

Analysis of the genes retained in the minimized Mycoplasma JCVI-Syn3A genome established that systems that repair or preempt metabolite damage are essential to life. Several genes with known metabolite damage repair or preemption functions were identified and experimentally validated, including 5-formyltetrahydrofolate cyclo-ligase, CoA disulfide reductase, and certain hydrolases. Furthermore, we discovered that an enigmatic YqeK hydrolase domain fused to NadD has a novel proofreading function in NAD synthesis and could double as a MutT-like sanitizing enzyme for the nucleotide pool. Finally, we combined metabolomics and cheminformatics approaches to extend the core metabolic map of JCVI-Syn3A to include promiscuous enzymatic reactions and spontaneous side reactions. This extension revealed that several key metabolite damage-control systems remain to be identified in JCVI-Syn3A, such as that for methylglyoxal.

Published

2021

23. Correction: Bioinformatic and experimental evidence for suicidal and catalytic plant THI4s

Author

Jaya Joshi, Guillaume A.W. Beaudoin, Jenelle A. Patterson, Jorge D. García-García, Catherine E. Belisle, Lan-Yen Chang, Lei Li, Owen Duncan, A. Harvey Millar, and Andrew D. Hanson

Subjects

Cell Biology, Molecular Biology, Biochemistry

Published

2022

24. The Moderately (D)efficient Enzyme: Catalysis-Related Damage

Author

Ulschan, Bathe, Bryan J, Leong, Donald R, McCarty, Christopher S, Henry, Paul E, Abraham, Mark A, Wilson, and Andrew D, Hanson

Subjects

Catalytic Domain, Systems Biology, Enzyme Stability, Biocatalysis, Article

Abstract

Enzymes have in vivo lifespans. Analysis of lifespans – lifetime totals of catalytic turnovers – suggests that non-survivable collateral chemical damage from the very reactions that enzymes catalyze is a common but underdiagnosed cause of enzyme death. Analysis also implies that many enzymes are moderately deficient in that their active-site regions are not naturally as hardened against such collateral damage as they could be, leaving room for improvement by rational design or directed evolution. Enzyme lifespan might also be improved by engineering systems that repair otherwise fatal active-site damage, of which a handful are known and more are inferred to exist. Unfortunately, the data needed to design and execute such improvements is lacking: there are too few measurements of in vivo lifespan, and existing information on the extent, nature, and mechanisms of active-site damage and repair during normal enzyme operation is too scarce, anecdotal, and speculative to act on. Fortunately, advances in proteomics, metabolomics, cheminformatics, comparative genomics, and structural biochemistry now empower a systematic, data-driven approach to identify, predict, and validate instances of active-site damage and its repair. These capabilities would be practically useful in enzyme redesign and improvement of in-use stability, and could change thinking about which enzymes die young in vivo, and why.

Published

2021

25. Using Continuous Directed Evolution to Improve Enzymes for Plant Applications

Author

Bryan J. Leong, Ulschan Bathe, Kristen Van Gelder, Andrew D. Hanson, Jorge D. García-García, Jaya Joshi, Steven D. Bruner, and Chang C. Liu

Subjects

chemistry.chemical_classification, biology, Physiology, Computer science, Scale (chemistry), fungi, Saccharomyces cerevisiae, food and beverages, Plant Science, Plant engineering, Computational biology, Directed evolution, biology.organism_classification, Enzymes, Plant Breeding, Enzyme, chemistry, Metabolic enzymes, Genetics, Directed Molecular Evolution, Function (biology), Plant Proteins

Abstract

Continuous directed evolution of enzymes and other proteins in microbial hosts is capable of outperforming classical directed evolution by executing hypermutation and selection concurrently in vivo, at scale, with minimal manual input. Provided that a target enzyme’s activity can be coupled to growth of the host cells, the activity can be improved simply by selecting for growth. Like all directed evolution, the continuous version requires no prior mechanistic knowledge of the target. Continuous directed evolution is thus a powerful new way to modify plant or non-plant enzymes for use in plant metabolic research and engineering. Here, we first describe the basic features of the Saccharomyces cerevisiae OrthoRep system for continuous directed evolution and compare it briefly with other systems. We then give a step-by-step account of three ways in which OrthoRep can be deployed to evolve primary metabolic enzymes, using a THI4 thiazole synthase as an example and illustrating the mutational outcomes obtained. We close by outlining applications of OrthoRep that serve growing demands (i) to change the characteristics of plant enzymes destined for return to plants, and (ii) to adapt (‘plantize’) enzymes from prokaryotes – especially exotic prokaryotes – to function well in mild, plant-like conditions.One-sentence summaryContinuous directed evolution using the yeast OrthoRep system is a powerful new way to improve enzymes for use in plant engineering as illustrated by ‘plantizing’ a bacterial thiamin synthesis enzyme..

Published

2021

26. The

Author

Jaya, Joshi, Manaki, Mimura, Masaharu, Suzuki, Shan, Wu, Jesse F, Gregory, Andrew D, Hanson, and Donald R, McCarty

Subjects

thiamin requiring, retrograde signaling, methylerythritol 4-phosphate pathway, 5-deoxyxylulose-phosphate synthase, food and beverages, biotic stress response, Plant Science, human activities, Original Research, thiamin

Abstract

The thiamin-requiring mutants of Arabidopsis have a storied history as a foundational model for biochemical genetics in plants and have illuminated the central role of thiamin in metabolism. Recent integrative genetic and biochemical analyses of thiamin biosynthesis and utilization imply that leaf metabolism normally operates close to thiamin-limiting conditions. Thus, the mechanisms that allocate thiamin-diphosphate (ThDP) cofactor among the diverse thiamin-dependent enzymes localized in plastids, mitochondria, peroxisomes, and the cytosol comprise an intricate thiamin economy. Here, we show that the classical thiamin-requiring 3 (th3) mutant is a point mutation in plastid localized 5-deoxyxylulose synthase 1 (DXS1), a key regulated enzyme in the methylerythritol 4-phosphate (MEP) isoprene biosynthesis pathway. Substitution of a lysine for a highly conserved glutamate residue (E323) located at the subunit interface of the homodimeric enzyme conditions a hypomorphic phenotype that can be rescued by supplying low concentrations of thiamin in the medium. Analysis of leaf thiamin vitamers showed that supplementing the medium with thiamin increased total ThDP content in both wild type and th3 mutant plants, supporting a hypothesis that the mutant DXS1 enzyme has a reduced affinity for the ThDP cofactor. An unexpected upregulation of a suite of biotic-stress-response genes associated with accumulation of downstream MEP intermediate MEcPP suggests that th3 causes mis-regulation of DXS1 activity in thiamin-supplemented plants. Overall, these results highlight that the central role of ThDP availability in regulation of DXS1 activity and flux through the MEP pathway.

Published

2021

27. Revolutionizing agriculture with synthetic biology

Author

Pablo I. Nikel, Claudia E. Vickers, Tobias J. Erb, Mark E. Cooper, A. Harvey Millar, Andrew D. Hanson, Kai P. Voss-Fels, and Eleanore T. Wurtzel

Subjects

0106 biological sciences, 0301 basic medicine, business.industry, Mindset, Plant Science, Environmental economics, Investment (macroeconomics), 01 natural sciences, Chemical production, 03 medical and health sciences, Synthetic biology, 030104 developmental biology, Agriculture, Business, Realization (systems), 010606 plant biology & botany

Abstract

Synthetic biology is here to stay and will transform agriculture if given the chance. The huge challenges facing food, fuel and chemical production make it vital to give synthetic biology that chance-notwithstanding the shifts in mindset, training and infrastructure investment this demands. Here, we assess opportunities for agricultural synthetic biology and ways to remove barriers to their realization.

Published

2019

28. Construction and applications of a B vitamin genetic resource for investigation of vitamin‐dependent metabolism in maize

Author

Manaki Mimura, Masaharu Suzuki, Donald R. McCarty, Shan Wu, Andrew D. Hanson, Saleh Alseekh, and Alisdair R. Fernie

Subjects

0106 biological sciences, 0301 basic medicine, Vitamin, Nitrogenous Group Transferases, Biotin deficiency, Plant Science, Biology, Zea mays, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Biotin, Gene Expression Regulation, Plant, Genetics, medicine, Allele, Gene, Alleles, Plant Proteins, 2. Zero hunger, Pyridoxine, Cell Biology, Vitamin biosynthesis, medicine.disease, Endosperm, Biosynthetic Pathways, Plant Leaves, B vitamins, Phenotype, 030104 developmental biology, chemistry, Mutation, Seeds, Vitamin B Complex, DNA Transposable Elements, Transcriptome, 010606 plant biology & botany, medicine.drug

Abstract

The B vitamins provide essential co-factors for central metabolism in all organisms. In plants, B vitamins have surprising emerging roles in development, stress tolerance and pathogen resistance. Hence, there is a paramount interest in understanding the regulation of vitamin biosynthesis as well as the consequences of vitamin deficiency in crop species. To facilitate genetic analysis of B vitamin biosynthesis and functions in maize, we have mined the UniformMu transposon resource to identify insertional mutations in vitamin pathway genes. A screen of 190 insertion lines for seed and seedling phenotypes identified mutations in biotin, pyridoxine and niacin biosynthetic pathways. Importantly, isolation of independent insertion alleles enabled genetic confirmation of genotype-to-phenotype associations. Because B vitamins are essential for survival, null mutations often have embryo lethal phenotypes that prevent elucidation of subtle, but physiologically important, metabolic consequences of sub-optimal (functional) vitamin status. To circumvent this barrier, we demonstrate a strategy for refined genetic manipulation of vitamin status based on construction of heterozygotes that combine strong and hypomorphic mutant alleles. Dosage analysis of pdx2 alleles in endosperm revealed that endosperm supplies pyridoxine to the developing embryo. Similarly, a hypomorphic bio1 allele enabled analysis of transcriptome and metabolome responses to incipient biotin deficiency in seedling leaves. We show that systemic pipecolic acid accumulation is an early metabolic response to sub-optimal biotin status highlighting an intriguing connection between biotin, lysine metabolism and systemic disease resistance signaling. Seed-stocks carrying insertions for vitamin pathway genes are available for free, public distribution via the Maize Genetics Cooperation Stock Center.

Published

2019

29. The metabolite repair enzyme Nit1 is a dual-targeted amidase that disposes of damaged glutathione in Arabidopsis

Author

Oliver Fiehn, Andrew D. Hanson, Steven D. Bruner, Robert T. Mullen, Thomas D. Niehaus, Michal Pyc, Danny C. Alexander, Jakob S. Folz, Brian S. MacTavish, and Jenelle A. Patterson

Subjects

0106 biological sciences, 0303 health sciences, biology, Chemistry, Translation (biology), Cell Biology, Glutathione, biology.organism_classification, 01 natural sciences, Biochemistry, Amidase, 03 medical and health sciences, chemistry.chemical_compound, Arabidopsis, Metabolome, Amidase activity, Molecular Biology, Gene, Cellular compartment, 030304 developmental biology, 010606 plant biology & botany

Abstract

The tripeptide glutathione (GSH) is implicated in various crucial physiological processes including redox buffering and protection against heavy metal toxicity. GSH is abundant in plants, with reported intracellular concentrations typically in the 1–10 mM range. Various aminotransferases can inadvertently transaminate the amino group of the γ-glutamyl moiety of GSH to produce deaminated glutathione (dGSH), a metabolite damage product. It was recently reported that an amidase known as Nit1 participates in dGSH breakdown in mammals and yeast. Plants have a hitherto uncharacterized homolog of the Nit1 amidase. We show that recombinant Arabidopsis Nit1 (At4g08790) has high and specific amidase activity towards dGSH. Ablating the Arabidopsis Nit1 gene causes a massive accumulation of dGSH and other marked changes to the metabolome. All plant Nit1 sequences examined had predicted plastidial targeting peptides with a potential second start codon whose use would eliminate the targeting peptide. In vitro transcription/translation assays show that both potential translation start codons in Arabidopsis Nit1 were used and confocal microscopy of Nit1–GFP fusions in plant cells confirmed both cytoplasmic and plastidial localization. Furthermore, we show that Arabidopsis enzymes present in leaf extracts convert GSH to dGSH at a rate of 2.8 pmol min−1 mg−1 in the presence of glyoxalate as an amino acceptor. Our data demonstrate that plants have a dGSH repair system that is directed to at least two cellular compartments via the use of alternative translation start sites.

Published

2019

30. Engineering Strategies to Boost Crop Productivity by Cutting Respiratory Carbon Loss

Author

Jeffrey S. Amthor, Mark Stitt, A. Harvey Millar, Lee J. Sweetlove, Stephen D. Tyerman, Andrew D. Hanson, and Arren Bar-Even

Subjects

Crops, Agricultural, 2. Zero hunger, 0106 biological sciences, 0301 basic medicine, Natural resource economics, food and beverages, Cell Biology, Plant Science, 15. Life on land, Biology, Respiratory activity, 01 natural sciences, Crop productivity, Carbon, 03 medical and health sciences, 030104 developmental biology, Perspective, Photosynthesis, Carbon loss, Respiratory system, 010606 plant biology & botany

Abstract

Roughly half the carbon that crop plants fix by photosynthesis is subsequently lost by respiration. Nonessential respiratory activity leading to unnecessary CO(2) release is unlikely to have been minimized by natural selection or crop breeding, and cutting this large loss could complement and reinforce the currently dominant yield-enhancement strategy of increasing carbon fixation. Until now, however, respiratory carbon losses have generally been overlooked by metabolic engineers and synthetic biologists because specific target genes have been elusive. We argue that recent advances are at last pinpointing individual enzyme and transporter genes that can be engineered to (1) slow unnecessary protein turnover, (2) replace, relocate, or reschedule metabolic activities, (3) suppress futile cycles, and (4) make ion transport more efficient, all of which can reduce respiratory costs. We identify a set of engineering strategies to reduce respiratory carbon loss that are now feasible and model how implementing these strategies singly or in tandem could lead to substantial gains in crop productivity.

Published

2019

31. Newly-discovered enzymes that function in metabolite damage-control

Author

Drago Haas, Valérie de Crécy-Lagard, and Andrew D. Hanson

Subjects

0301 basic medicine, Comparative genomics, chemistry.chemical_classification, Metabolite, Computational biology, Metabolism, Biology, Biochemistry, Enzymes, Analytical Chemistry, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Enzyme, chemistry, Proteome, Escherichia coli, Metabolome, Function (biology), Bacillus subtilis

Abstract

Enzymes of unknown function are estimated to make up around 25% of the sequenced proteome. In the past decade, over 20 conserved families have been shown to function in the metabolism of 'damaged' or abnormal metabolites that are wasteful and often toxic. These newly discovered damage-control enzymes either repair or inactivate the offending metabolites, or pre-empt their formation in the first place. Comparative genomics has been of prime importance in predicting the functions of damage-control enzymes and in guiding the biochemical and genetic tests required to validate these functions.

Published

2018

32. Quantification of N 6 ‐formylated lysine in bacterial protein digests using liquid chromatography/tandem mass spectrometry despite spontaneous formation and matrix effects

Author

Andrew D. Hanson, Oliver Fiehn, Jacob Folz, and Jenelle A. Patterson

Subjects

Chromatography, Chemistry, Electrospray ionization, 010401 analytical chemistry, Organic Chemistry, Lysine, Orbitrap, Tandem mass spectrometry, Mass spectrometry, complex mixtures, 01 natural sciences, 0104 chemical sciences, Analytical Chemistry, law.invention, Formylation, law, Liquid chromatography–mass spectrometry, Acetylation, bacteria, Spectroscopy

Abstract

RATIONALE N6-Formyl lysine is a well-known modification of histones and other proteins. It can also be formed as a damaged product from direct formylation of free lysine and accompanied by other lysine derivatives such as acetylated or methylated forms. In relation to the activity of cellular repair enzymes in protein turnover and to lysine metabolism, it is important to accurately quantify the overall ratio of modified lysine to free lysine. METHODS N6-Formyl lysine was quantified using liquid chromatography/tandem mass spectrometry (LC/MS/MS) with data collected in a non-targeted manner using positive mode electrospray ionization on a Q-Exactive HF+ Orbitrap mass spectrometer. Studies were performed with lysine and deuterated lysine spiked into protein digests and solvents to investigate the extent of spontaneous formation and matrix effects of formation of N6-formyl lysine. RESULTS We show that N6-formyl lysine, N2-formyl lysine, N6-acetyl lysine, and N2-acetyl lysine are all formed spontaneously during sample preparation and LC/MS/MS analysis, which complicates quantification of these metabolites in biological samples. N6-Formyl lysine was spontaneously formed and correlated to the concentration of lysine. In the sample matrix of protein digests, 0.03% of lysine was spontaneously converted into N6-formyl lysine, and 0.005% of lysine was converted into N6-formyl lysine in pure run solvent. CONCLUSIONS Spontaneous formation of N6-formyl lysine, N6-acetyl lysine, N2-formyl lysine, and N2-acetyl lysine needs to be subtracted from biologically formed lysine modifications when quantifying these epimetabolites in biological samples.

Published

2021

33. Author response for 'Quantification of N 6 ‐formylated lysine in bacterial protein digests using liquid chromatography/tandem mass spectrometry despite spontaneous formation and matrix effects'

Author

Andrew D. Hanson, Jenelle A. Patterson, Oliver Fiehn, and Jacob S. Folz

Subjects

Bacterial protein, Chromatography, Chemistry, Liquid chromatography–mass spectrometry, Lysine

Published

2020

34. Potential For Applying Continuous Directed Evolution To Plant Enzymes

Author

Jaya Joshi, Lidimarie Trujillo-Rodriguez, Alex A. Javanpour, Jorge D. García-García, Jenelle A. Patterson, Andrew D. Hanson, Christopher R. Reisch, and Chang C. Liu

Subjects

Plant evolution, chemistry.chemical_classification, biology, Computer science, Mutagenesis, Saccharomyces cerevisiae, Mutagenesis (molecular biology technique), Directed evolution, biology.organism_classification, Replication (computing), Plasmid, Enzyme, chemistry, Biochemical engineering, Target gene, Gene, Function (biology)

Abstract

SUMMARYPlant evolution has produced enzymes that may not be optimal for maximizing yield and quality in today’s agricultural environments and plant biotechnology applications. By improving enzyme performance, it should be possible to alleviate constraints on yield and quality currently imposed by kinetic properties or enzyme instability. Enzymes can be optimized faster than naturally possible by applying directed evolution, which entails mutating a target gene in vitro and screening or selecting the mutated gene products for the desired characteristics. Continuous directed evolution is a more efficient and scalable version that accomplishes the mutagenesis and selection steps simultaneously in vivo via error-prone replication of the target gene and coupling of the host cell’s growth rate to the target gene’s function. However, published continuous systems require custom plasmid assembly, and convenient multipurpose platforms are not available. We discuss two systems suitable for continuous directed evolution of enzymes, OrthoRep in Saccharomyces cerevisiae and EvolvR in Escherichia coli, and our pilot efforts to adapt each system for high-throughput plant enzyme engineering. To test our modified systems, we used the thiamin synthesis enzyme THI4, previously identified as a prime candidate for improvement. Our adapted OrthoRep system shows promise for efficient plant enzyme engineering.

Published

2020

35. Quantification of N

Author

Jacob S, Folz, Jenelle A, Patterson, Andrew D, Hanson, and Oliver, Fiehn

Subjects

Tandem Mass Spectrometry, Escherichia coli Proteins, Lysine, Escherichia coli, Metabolomics, Chromatography, High Pressure Liquid

Abstract

NNWe show that NSpontaneous formation of N

Published

2020

36. Bioinformatic and experimental evidence for suicidal and catalytic plant THI4s

Author

Jaya Joshi, Owen Duncan, A. Harvey Millar, Jenelle A. Patterson, Andrew D. Hanson, Lei Li, Catherine E. Belisle, Lan-Yen Chang, Guillaume A.W. Beaudoin, and Jorge D. García-García

Subjects

Models, Molecular, 0106 biological sciences, Auxotrophy, Mutant, Arabidopsis, medicine.disease_cause, Biochemistry, 01 natural sciences, Catalysis, Ligases, Transcriptome, 03 medical and health sciences, chemistry.chemical_compound, Protein Domains, Escherichia coli, medicine, Thiamine, Thiazole, Molecular Biology, 030304 developmental biology, 2. Zero hunger, chemistry.chemical_classification, 0303 health sciences, ATP synthase, biology, Arabidopsis Proteins, Chemistry, Genetic Complementation Test, Computational Biology, food and beverages, Cell Biology, Plants, Genetically Modified, biology.organism_classification, Thiazoles, Enzyme, biology.protein, 010606 plant biology & botany

Abstract

Like fungi and some prokaryotes, plants use a thiazole synthase (THI4) to make the thiazole precursor of thiamin. Fungal THI4s are suicide enzymes that destroy an essential active-site Cys residue to obtain the sulfur atom needed for thiazole formation. In contrast, certain prokaryotic THI4s have no active-site Cys, use sulfide as sulfur donor, and are truly catalytic. The presence of a conserved active-site Cys in plant THI4s and other indirect evidence implies that they are suicidal. To confirm this, we complemented the Arabidopsis tz-1 mutant, which lacks THI4 activity, with a His-tagged Arabidopsis THI4 construct. LC-MS analysis of tryptic peptides of the THI4 extracted from leaves showed that the active-site Cys was predominantly in desulfurated form, consistent with THI4 having a suicide mech-anism in planta. Unexpectedly, transcriptome datamining and deep proteome profiling showed that barley, wheat, and oat have both a widely expressed canonical THI4 with an active-site Cys, and a THI4-like paralog (non-Cys THI4) that has no active-site Cys and is the major type of THI4 in devel-oping grains. Transcriptomic evidence also indicated that barley, wheat, and oat grains synthesize thiamin de novo, implying that their non-Cys THI4s synthesize thiazole. Structure modeling supported this inference, as did demonstration that non-Cys THI4s have significant capacity to complement thia-zole auxotrophy in Escherichia coli. There is thus a prima facie case that non-Cys cereal THI4s, like their prokaryotic counterparts, are catalytic thiazole synthases. Bioenergetic calculations show that, relative to suicide THI4s, such enzymes could save substantial energy during the grain filling period.AbbreviationsDHAla, dehydroalanine; EST, expressed sequence tag; FDR, false discovery rate; IPTG, β-D-1-thiogalactopyranoside

Published

2020

37. Thioproline formation as a driver of formaldehyde toxicity in Escherichia coli

Author

Arren Bar-Even, Jacob Folz, Oliver Fiehn, Steven D. Bruner, Andrew D. Hanson, Qiang Li, Mark A. Wilson, Hai He, and Jenelle A. Patterson

Subjects

Proline, Peptide, medicine.disease_cause, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Formaldehyde, Endopeptidases, medicine, Escherichia coli, Formate, Cysteine, Molecular Biology, Institut für Biochemie und Biologie, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Chemistry, 030302 biochemistry & molecular biology, Cell Biology, Metabolism, Small molecule, Aldehyde Oxidoreductases, Enzyme, Genes, Bacterial, Proline aminopeptidase, ddc:540, Thiazolidines, Genome, Bacterial

Abstract

Formaldehyde (HCHO) is a reactive carbonyl compound that formylates and cross-links proteins, DNA, and small molecules. It is of specific concern as a toxic intermediate in the design of engineered pathways involving methanol oxidation or formate reduction. The high interest in engineering these pathways is not, however, matched by engineering-relevant information on precisely why HCHO is toxic or on what damage-control mechanisms cells deploy to manage HCHO toxicity. The only well-defined mechanism for managing HCHO toxicity is formaldehyde dehydrogenase-mediated oxidation to formate, which is counterproductive if HCHO is a desired pathway intermediate. We therefore sought alternative HCHO damage-control mechanisms via comparative genomic analysis. This analysis associated homologs of theEscherichia coli pepPgene with HCHO-related one-carbon metabolism. Furthermore, deletingpepPincreased the sensitivity ofE. colito supplied HCHO but not other carbonyl compounds. PepP is a proline aminopeptidase that cleaves peptides of the general formula X-Pro-Y, yielding X + Pro-Y. HCHO is known to react spontaneously with cysteine to form the close proline analog thioproline (thiazolidine-4-carboxylate), which is incorporated into proteins and hence into proteolytic peptides. We therefore hypothesized that thioproline-containing peptides are toxic and that PepP cleaves these aberrant peptides. Supporting this hypothesis, PepP cleaved the model peptide Ala-thioproline-Ala as efficiently as Ala-Pro-Alain vitroandin vivo, and deletingpepPincreased sensitivity to supplied thioproline. Our data thus (i) provide biochemical genetic evidence that thioproline formation contributes substantially to HCHO toxicity and (ii) make PepP a candidate damage-control enzyme for engineered pathways having HCHO as an intermediate.

Published

2020

38. In Vivo Rate of Formaldehyde Condensation with Tetrahydrofolate

Author

Andrew D. Hanson, Liliana E. García-Valencia, Perla A. Ramos-Parra, Elad Noor, Jenelle A. Patterson, Rocío I. Díaz de la Garza, Hai He, and Arren Bar-Even

Subjects

0301 basic medicine, Sarcosine, phenotypic phase plane, Endocrinology, Diabetes and Metabolism, lcsh:QR1-502, auxotrophy, Formaldehyde, Photochemistry, Biochemistry, Article, lcsh:Microbiology, Formaldehyde assimilation, 03 medical and health sciences, chemistry.chemical_compound, ddc:570, Doubling time, Molecular Biology, Institut für Biochemie und Biologie, chemistry.chemical_classification, 030102 biochemistry & molecular biology, Assimilation (biology), one-carbon metabolism, Condensation reaction, spontaneous reaction, serine cycle, 030104 developmental biology, Enzyme, chemistry, ddc:540, Methanol

Abstract

Formaldehyde is a highly reactive compound that participates in multiple spontaneous reactions, but these are mostly deleterious and damage cellular components. In contrast, the spontaneous condensation of formaldehyde with tetrahydrofolate (THF) has been proposed to contribute to the assimilation of this intermediate during growth on C1 carbon sources such as methanol. However, the in vivo rate of this condensation reaction is unknown and its possible contribution to growth remains elusive. Here, we used microbial platforms to assess the rate of this condensation in the cellular environment. We constructed Escherichia coli strains lacking the enzymes that naturally produce 5,10-methylene-THF. These strains were able to grow on minimal medium only when equipped with a sarcosine (N-methyl-glycine) oxidation pathway that sustained a high cellular concentration of formaldehyde, which spontaneously reacts with THF to produce 5,10-methylene-THF. We used flux balance analysis to derive the rate of the spontaneous condensation from the observed growth rate. According to this, we calculated that a microorganism obtaining its entire biomass via the spontaneous condensation of formaldehyde with THF would have a doubling time of more than three weeks. Hence, this spontaneous reaction is unlikely to serve as an effective route for formaldehyde assimilation., Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe, 998

Published

2020

39. Parts-Prospecting for a High-Efficiency Thiamin Thiazole Biosynthesis Pathway

Author

Guillaume A.W. Beaudoin, Thomas A. Colquhoun, Jiayi Sun, Jesse F. Gregory, Keun H. Cho, Maria Ralat, Andrew D. Hanson, Cindy L. Sigler, Jaya Joshi, Jenelle A. Patterson, Zhanao Deng, and David G. Clark

Subjects

0106 biological sciences, Physiology, Methanococcus, Research Articles - Focus Issue, Plant Science, medicine.disease_cause, 01 natural sciences, chemistry.chemical_compound, Bacterial Proteins, Escherichia coli, Genetics, medicine, Araceae, Thiamine, Thiazole, chemistry.chemical_classification, Bacteria, food and beverages, Plants, Directed evolution, Plant cell, Biosynthetic Pathways, Complementation, Thiazoles, Enzyme, Metabolic Engineering, Biochemistry, chemistry, Alternative complement pathway, Function (biology), 010606 plant biology & botany

Abstract

Plants synthesize the thiazole precursor of thiamin (cThz-P) via THIAMIN4 (THI4), a suicide enzyme that mediates one reaction cycle and must then be degraded and resynthesized. It has been estimated that this THI4 turnover consumes 2% to 12% of the maintenance energy budget and that installing an energy-efficient alternative pathway could substantially increase crop yield potential. Available data point to two natural alternatives to the suicidal THI4 pathway: (i) nonsuicidal prokaryotic THI4s that lack the active-site Cys residue on which suicide activity depends, and (ii) an uncharacterized thiazole synthesis pathway in flowers of the tropical arum lily Caladium bicolor that enables production and emission of large amounts of the cThz-P analog 4-methyl-5-vinylthiazole (MVT). We used functional complementation of an Escherichia coli ΔthiG strain to identify a nonsuicidal bacterial THI4 (from Thermovibrio ammonificans) that can function in conditions like those in plant cells. We explored whether C. bicolor synthesizes MVT de novo via a novel route, via a suicidal or a nonsuicidal THI4, or by catabolizing thiamin. Analysis of developmental changes in MVT emission, extractable MVT, thiamin level, and THI4 expression indicated that C. bicolor flowers make MVT de novo via a massively expressed THI4 and that thiamin is not involved. Functional complementation tests indicated that C. bicolor THI4, which has the active-site Cys needed to operate suicidally, may be capable of suicidal and – in hypoxic conditions – nonsuicidal operation. T. ammonificans and C. bicolor THI4s are thus candidate parts for rational redesign or directed evolution of efficient, nonsuicidal THI4s for use in crop improvement.

Published

2018

40. A Tale of Two Concepts: Harmonizing the Free Radical and Antagonistic Pleiotropy Theories of Aging

Author

Alexey Golubev, Vadim N. Gladyshev, and Andrew D. Hanson

Subjects

0301 basic medicine, Aging, Free Radicals, Physiology, Clinical Biochemistry, Population, Biology, Biochemistry, 03 medical and health sciences, Animals, Humans, education, Molecular Biology, General Environmental Science, Free-radical theory of aging, Genetics, education.field_of_study, Genetic Pleiotropy, Cell Biology, Biological evolution, Take over, Forum Review Articles, 030104 developmental biology, Pleiotropy (drugs), Evolutionary biology, General Earth and Planetary Sciences, Reactive Oxygen Species

Abstract

Significance: The two foremost concepts of aging are the mechanistic free radical theory (FRT) of how we age and the evolutionary antagonistic pleiotropy theory (APT) of why we age. Both date from the late 1950s. The FRT holds that reactive oxygen species (ROS) are the principal contributors to the lifelong cumulative damage suffered by cells, whereas the APT is generally understood as positing that genes that are good for young organisms can take over a population even if they are bad for the old organisms. Recent Advances: Here, we provide a common ground for the two theories by showing how aging can result from the inherent chemical reactivity of many biomolecules, not just ROS, which imposes a fundamental constraint on biological evolution. Chemically reactive metabolites spontaneously modify slowly renewable macromolecules in a continuous way over time; the resulting buildup of damage wrought by the genes coding for enzymes that generate such small molecules eventually masquerades as late-acting pleiotropic effects. In aerobic organisms, ROS are major agents of this damage but they are far from alone. Critical Issues: Being related to two sides of the same phenomenon, these theories should be compatible. However, the interface between them is obscured by the FRT mistaking a subset of damaging processes for the whole, and the APT mistaking a cumulative quantitative process for a qualitative switch. Future Directions: The manifestations of ROS-mediated cumulative chemical damage at the population level may include the often-observed negative correlation between fitness and the rate of its decline with increasing age, further linking FRT and APT. Antioxid. Redox Signal. 29, 1003–1017.

Published

2018

41. PlantSEED enables automated annotation and reconstruction of plant primary metabolism with improved compartmentalization and comparative consistency

Author

Andrew D. Hanson, Avinash Sreedasyam, Claudia Lerma-Ortiz, Neal Conrad, Arman Mikaili, Samuel M. D. Seaver, and Christopher S. Henry

Subjects

0106 biological sciences, 0301 basic medicine, Databases, Factual, Compartmentalization (information security), Plant Science, Computational biology, Biology, 01 natural sciences, Genome, Set (abstract data type), 03 medical and health sciences, Consistency (database systems), Annotation, Upload, Genetics, Metabolomics, Computational Biology, High-Throughput Nucleotide Sequencing, Cell Biology, Plants, Flux balance analysis, 030104 developmental biology, User interface, Transcriptome, Algorithms, Genome, Plant, Metabolic Networks and Pathways, 010606 plant biology & botany

Abstract

Genome-scale metabolic reconstructions help us to understand and engineer metabolism. Next-generation sequencing technologies are delivering genomes and transcriptomes for an ever-widening range of plants. While such omic data can, in principle, be used to compare metabolic reconstructions in different species, organs and environmental conditions, these comparisons require a standardized framework for the reconstruction of metabolic networks from transcript data. We previously introduced PlantSEED as a framework covering primary metabolism for 10 species. We have now expanded PlantSEED to include 39 species and provide tools that enable automated annotation and metabolic reconstruction from transcriptome data. The algorithm for automated annotation in PlantSEED propagates annotations using a set of signature k-mers (short amino acid sequences characteristic of particular proteins) that identify metabolic enzymes with an accuracy of about 97%. PlantSEED reconstructions are built from a curated template that includes consistent compartmentalization for more than 100 primary metabolic subsystems. Together, the annotation and reconstruction algorithms produce reconstructions without gaps and with more accurate compartmentalization than existing resources. These tools are available via the PlantSEED web interface at http://modelseed.org, which enables users to upload, annotate and reconstruct from private transcript data and simulate metabolic activity under various conditions using flux balance analysis. We demonstrate the ability to compare these metabolic reconstructions with a case study involving growth on several nitrogen sources in roots of four species.

Published

2018

42. Redesigning thiamin synthesis: Prospects and potential payoffs

Author

Jesse F. Gregory, Steven D. Bruner, Andrew D. Hanson, Jiayi Sun, Jeffrey S. Amthor, Yousong Ding, and Thomas D. Niehaus

Subjects

0106 biological sciences, 0301 basic medicine, Vitamin b, Plant growth, Plant Science, Biology, 01 natural sciences, Metabolic engineering, 03 medical and health sciences, Biomass yield, Genetics, Thiamine, food and beverages, General Medicine, Plants, Oxygen, Thiazoles, Pyrimidines, 030104 developmental biology, Metabolic Engineering, Crop biomass, Synthetic Biology, Biochemical engineering, human activities, Agronomy and Crop Science, Metabolic Networks and Pathways, 010606 plant biology & botany

Abstract

Thiamin is essential for plant growth but is short-lived in vivo and energetically very costly to produce – a combination that makes thiamin biosynthesis a prime target for improvement by redesign. Thiamin consists of thiazole and pyrimidine moieties. Its high biosynthetic cost stems from use of the suicide enzyme THI4 to form the thiazole and the near-suicide enzyme THIC to form the pyrimidine. These energetic costs lower biomass yield potential and are likely compounded by environmental stresses that destroy thiamin and hence increase the rate at which it must be made. The energy costs could be slashed by refactoring the thiamin biosynthesis pathway to eliminate the suicidal THI4 and THIC reactions. To substantiate this design concept, we first document the energetic costs of the THI4 and THIC steps in the pathway and explain how cutting these costs could substantially increase crop biomass and grain yields. We then show that a refactored pathway must produce thiamin itself rather than a stripped-down analog because the thiamin molecule cannot be simplified without losing biological activity. Lastly, we consider possible energy-efficient alternatives to the inefficient natural THI4- and THIC-mediated steps.

Published

2018

43. Salvage of the 5-deoxyribose byproduct of radical SAM enzymes

Author

Oliver Fiehn, Alexander Angerhofer, Guillaume A.W. Beaudoin, Steven D. Bruner, Andrew D. Hanson, Justin L. Goodsell, Jacob Folz, and Qiang Li

Subjects

0301 basic medicine, S-Adenosylmethionine, Protein Conformation, Science, Bacillus thuringiensis, General Physics and Astronomy, Isomerase, Crystallography, X-Ray, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, Escherichia coli, Metabolomics, lcsh:Science, Isomerases, Nucleotide salvage, Dihydroxyacetone phosphate, Aldehyde-Lyases, chemistry.chemical_classification, Aldehydes, Multidisciplinary, Crystallography, 030102 biochemistry & molecular biology, biology, Deoxyadenosines, Deoxyribose, Aldolase A, Phosphotransferases, Biological Transport, General Chemistry, Lyase, 030104 developmental biology, Enzyme, Phenotype, chemistry, Biochemistry, biology.protein, X-Ray, lcsh:Q, Ribosemonophosphates, Radical SAM, Gene Deletion

Abstract

5-Deoxyribose is formed from 5′-deoxyadenosine, a toxic byproduct of radical S-adenosylmethionine (SAM) enzymes. The degradative fate of 5-deoxyribose is unknown. Here, we define a salvage pathway for 5-deoxyribose in bacteria, consisting of phosphorylation, isomerization, and aldol cleavage steps. Analysis of bacterial genomes uncovers widespread, unassigned three-gene clusters specifying a putative kinase, isomerase, and sugar phosphate aldolase. We show that the enzymes encoded by the Bacillus thuringiensis cluster, acting together in vitro, convert 5-deoxyribose successively to 5-deoxyribose 1-phosphate, 5-deoxyribulose 1-phosphate, and dihydroxyacetone phosphate plus acetaldehyde. Deleting the isomerase decreases the 5-deoxyribulose 1-phosphate pool size, and deleting either the isomerase or the aldolase increases susceptibility to 5-deoxyribose. The substrate preference of the aldolase is unique among family members, and the X-ray structure reveals an unusual manganese-dependent enzyme. This work defines a salvage pathway for 5-deoxyribose, a near-universal metabolite., 5-Deoxyribose is formed from 5′-deoxyadenosine, a toxic byproduct of radical S-adenosylmethionine enzymes. Here, the authors identify and biochemically characterize a bacterial salvage pathway for 5-deoxyribose, consisting of three enzymes, and solve the crystal structure of the key aldolase.

Published

2018

44. Provenance and paleogeography of the 25–17 Ma Rainbow Gardens Formation: Evidence for tectonic activity at ca. 19 Ma and internal drainage rather than throughgoing paleorivers on the southwestern Colorado Plateau

Author

Karl E. Karlstrom, William C. McIntosh, Mark E. Sitton, Andrew D. Hanson, Nelia W. Dunbar, Melissa A. Lamb, Paul J. Umhoefer, Thomas A. Hickson, L. Sue Beard, and Malia Dragos

Subjects

Provenance, Tectonics, 010504 meteorology & atmospheric sciences, Stratigraphy, Geochemistry, Geology, Colorado plateau, Drainage, 010502 geochemistry & geophysics, 01 natural sciences, Palaeogeography, 0105 earth and related environmental sciences

Published

2018

45. Identification of a metabolic disposal route for the oncometabolite S-(2-succino)cysteine in Bacillus subtilis

Author

David Moraga Amador, Arthur J.L. Cooper, Donald R. McCarty, Andrew D. Hanson, Jacob Folz, Oliver Fiehn, and Thomas D. Niehaus

Subjects

0301 basic medicine, Biochemistry & Molecular Biology, Operon, Metabolite, Cystine, Bacillus subtilis, N-acetylation, Medical and Health Sciences, Biochemistry, protein modification, 03 medical and health sciences, chemistry.chemical_compound, Fumarates, sulfhydryl group, Neoplasms, energy metabolism, Genetics, Metabolomics, Citrate synthase, Cysteine, protein succination, Molecular Biology, fumarate, biology, Chemistry, microbiology, Acetylation, Cell Biology, Metabolism, Biological Sciences, metabolic disease, biology.organism_classification, oncometabolite, 030104 developmental biology, Chemical Sciences, biology.protein, metabolism, respiration, Signal Transduction

Abstract

Cellular thiols such as cysteine spontaneously and readily react with the respiratory intermediate fumarate, resulting in the formation of stable S-(2-succino)-adducts. Fumarate-mediated succination of thiols increases in certain tumors and in response to glucotoxicity associated with diabetes. Therefore, S-(2-succino)-adducts such as S-(2-succino)cysteine (2SC) are considered oncometabolites and biomarkers for human disease. No disposal routes for S-(2-succino)-compounds have been reported prior to this study. Here, we show that Bacillus subtilis metabolizes 2SC to cysteine using a pathway encoded by the yxe operon. The first step is N-acetylation of 2SC followed by an oxygenation that we propose results in the release of oxaloacetate and N-acetylcysteine, which is deacetylated to give cysteine. Knockouts of the genes predicted to mediate each step in the pathway lose the ability to grow on 2SC as the sulfur source and accumulate the expected upstream metabolite(s). We further show that N-acetylation of 2SC relieves toxicity. This is the first demonstration of a metabolic disposal route for any S-(2-succino)-compound, paving the way toward the identification of corresponding pathways in other species.

Published

2018

46. Carboxythiazole is a key microbial nutrient currency and critical component of thiamin biosynthesis

Author

Phillippe Schatt, Thomas D. Niehaus, Elden E. Rowland, Andrew D. Hanson, Mohamed Mehiri, Lasse Riemann, Ryan W. Paerl, Erin M. Bertrand, François-Yves Bouget, Department of Marine, Earth, and Atmospheric Sciences [NCSU] (MEAS), North Carolina State University [Raleigh] (NC State), University of North Carolina System (UNC)-University of North Carolina System (UNC), Department of Biology [Copenhagen], Faculty of Science [Copenhagen], University of Copenhagen = Københavns Universitet (KU)-University of Copenhagen = Københavns Universitet (KU), Department of Biology (Dalhousie University), Dalhousie University [Halifax], Laboratoire d'Océanographie Microbienne (LOMIC), Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire océanologique de Banyuls (OOB), Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Institut de Chimie de Nice (ICN), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015 - 2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015 - 2019) (COMUE UCA)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA), Horticultural Sciences Department, University of Florida [Gainesville], ANR: 15-IDEX-0001,UCA JEDI,Idex UCA JEDI(2015), ANR-14-CE02-0018,Photo-Phyto,Effets du réchauffement climatique sur le déclenchement des blooms phytoplanctoniques marins : photoperiodisme, composition et adaptation(2014), European Project: 654008,H2020,H2020-INFRADEV-1-2014-1,EMBRIC(2015), University of North Carolina System (UNC), University of Copenhagen = Københavns Universitet (KU), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA), University of Florida [Gainesville] (UF), Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA)-Université Nice Sophia Antipolis (... - 2019) (UNS), and COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)

Subjects

0106 biological sciences, 0301 basic medicine, Water microbiology, Microorganism, Arabidopsis, lcsh:Medicine, Chemical ecology, [CHIM.THER]Chemical Sciences/Medicinal Chemistry, Biology, medicine.disease_cause, 01 natural sciences, Article, Cell Line, Microbial ecology, 03 medical and health sciences, Thiamine biosynthesis, chemistry.chemical_compound, Mice, Nutrient, Biosynthesis, [CHIM.ANAL]Chemical Sciences/Analytical chemistry, medicine, Escherichia coli, Arabidopsis thaliana, Animals, Thiamine, [SDV.BBM.BC]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biochemistry [q-bio.BM], lcsh:Science, Primary productivity, [SDV.EE]Life Sciences [q-bio]/Ecology, environment, [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, Multidisciplinary, Arabidopsis Proteins, lcsh:R, Nutrients, biology.organism_classification, Thiazoles, 030104 developmental biology, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, Biochemistry, chemistry, Phytoplankton, lcsh:Q, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, 010606 plant biology & botany

Abstract

Almost all cells require thiamin, vitamin B1 (B1), which is synthesized via the coupling of thiazole and pyrimidine precursors. Here we demonstrate that 5-(2-hydroxyethyl)-4-methyl-1,3-thiazole-2-carboxylic acid (cHET) is a useful in vivo B1 precursor for representatives of ubiquitous marine picoeukaryotic phytoplankton and Escherichia coli – drawing attention to cHET as a valuable exogenous micronutrient for microorganisms with ecological, industrial, and biomedical value. Comparative utilization experiments with the terrestrial plant Arabidopsis thaliana revealed that it can also use exogenous cHET, but notably, picoeukaryotic marine phytoplankton and E. coli were adapted to grow on low (picomolar) concentrations of exogenous cHET. Our results call for the modification of the conventional B1 biosynthesis model to incorporate cHET as a key precursor for B1 biosynthesis in two domains of life, and for consideration of cHET as a microbial micronutrient currency modulating marine primary productivity and community interactions in human gut-hosted microbiomes.

Published

2018

47. A plastidial pantoate transporter with a potential role in pantothenate synthesis

Author

Lili Huang, Saleh Alseekh, Donald R. McCarty, Christopher S. Henry, Jesse F. Gregory, Valérie de Crécy-Lagard, Michal Pyc, Robert T. Mullen, Alisdair R. Fernie, and Andrew D. Hanson

Subjects

Monocarboxylic Acid Transporters, 0301 basic medicine, Nicotiana tabacum, Coenzyme A, Green Fluorescent Proteins, Mutant, Arabidopsis, Organic Anion Transporters, Sodium-Dependent, Zea mays, Biochemistry, Pantothenic Acid, Mitochondrial Proteins, Chloroplast Proteins, Gene Knockout Techniques, 03 medical and health sciences, chemistry.chemical_compound, Cytosol, Gene Expression Regulation, Plant, Arabidopsis thaliana, Plastids, Plastid, Molecular Biology, Plant Proteins, biology, Arabidopsis Proteins, Chemistry, Membrane Transport Proteins, Salmonella enterica, food and beverages, Cell Biology, biology.organism_classification, Subcellular localization, Mitochondria, 030104 developmental biology, Symporter, Metabolic Networks and Pathways

Abstract

The pantothenate (vitamin B5) synthesis pathway in plants is not fully defined because the subcellular site of its ketopantoate → pantoate reduction step is unclear. However, the pathway is known to be split between cytosol, mitochondria, and potentially plastids, and inferred to involve mitochondrial or plastidial transport of ketopantoate or pantoate. No proteins that mediate these transport steps have been identified. Comparative genomic and transcriptomic analyses identified Arabidopsis thaliana BASS1 (At1g78560) and its maize (Zea mays) ortholog as candidates for such a transport role. BASS1 proteins belong to the bile acid : sodium symporter family and share similarity with the Salmonella enterica PanS pantoate/ketopantoate transporter and with predicted bacterial transporters whose genes cluster on the chromosome with pantothenate synthesis genes. Furthermore, Arabidopsis BASS1 is co-expressed with genes related to metabolism of coenzyme A, the cofactor derived from pantothenate. Expression of Arabidopsis or maize BASS1 promoted the growth of a S. enterica panB panS mutant strain when pantoate, but not ketopantoate, was supplied, and increased the rate of [3H]pantoate uptake. Subcellular localization of green fluorescent protein fusions in Nicotiana tabacum BY-2 cells demonstrated that Arabidopsis BASS1 is targeted solely to the plastid inner envelope. Two independent Arabidopsis BASS1 knockout mutants accumulated pantoate ∼10-fold in leaves and had smaller seeds. Taken together, these data indicate that BASS1 is a physiologically significant plastidial pantoate transporter and that the pantoate reduction step in pantothenate biosynthesis could be at least partly localized in plastids.

Published

2018

48. Focus Issue Editorial: Synthetic Biology

Author

Eleanore T. Wurtzel, Andrew D. Hanson, Julian M. Hibberd, Mattheos A. G. Koffas, Joachim Kopka, Hanson, Andrew D [0000-0003-2585-9340], Hibberd, Julian M [0000-0003-0662-7958], Kopka, Joachim [0000-0001-9675-4883], Wurtzel, Eleanore T [0000-0002-9186-3260], and Apollo - University of Cambridge Repository

Subjects

0106 biological sciences, Focus (computing), Engineering, Physiology, business.industry, Botany, Plant Science, Plants, 01 natural sciences, Plant Physiological Phenomena, Synthetic biology, Plant science, Genetics, Synthetic Biology, Editorial - Focus Issue, Engineering ethics, business, 010606 plant biology & botany

Abstract

Synthetic biology (SynBio) is a conceptual and operational revolution ([Church et al., 2014][1]) that’s coming soon to a branch of plant science near you, if it’s not there already ([Liu and Stewart, 2015][2]). The Synthetic Biology Focus Issue sets out to spread this disruptive news. SynBio is

Published

2019

49. A Core Metabolome Response of Maize Leaves Subjected to Long-Duration Abiotic Stresses

Author

Taylor Logue, Saleh Alseekh, Donald R. McCarty, Andrew D. Hanson, Ghulam Hasnain, Madeline Lynch, Alisdair R. Fernie, Jiahn-Chou Guan, Jaya Joshi, and Shan Wu

Subjects

Abiotic component, Regulation of gene expression, Abiotic stress, Chemistry, Endocrinology, Diabetes and Metabolism, drought, salinity, heat stress, metabolomics, RNA-seq, RNA-Seq, Microbiology, Biochemistry, QR1-502, Article, Cell biology, Citric acid cycle, Transcriptome, Metabolomics, Metabolome, Molecular Biology

Abstract

Abiotic stresses reduce crop growth and yield in part by disrupting metabolic homeostasis and triggering responses that change the metabolome. Experiments designed to understand the mechanisms underlying these metabolomic responses have usually not used agriculturally relevant stress regimes. We therefore subjected maize plants to drought, salt, or heat stresses that mimic field conditions and analyzed leaf responses at metabolome and transcriptome levels. Shared features of stress metabolomes included synthesis of raffinose, a compatible solute implicated in tolerance to dehydration. In addition, a marked accumulation of amino acids including proline, arginine, and γ-aminobutyrate combined with depletion of key glycolysis and tricarboxylic acid cycle intermediates indicated a shift in balance of carbon and nitrogen metabolism in stressed leaves. Involvement of the γ-aminobutyrate shunt in this process is consistent with its previously proposed role as a workaround for stress-induced thiamin-deficiency. Although convergent metabolome shifts were correlated with gene expression changes in affected pathways, patterns of differential gene regulation induced by the three stresses indicated distinct signaling mechanisms highlighting the plasticity of plant metabolic responses to abiotic stress.

Published

2021

50. A strictly monofunctional bacterial hydroxymethylpyrimidine phosphate kinase precludes damaging errors in thiamin biosynthesis

Author

Antje M. K. Thamm, Gengnan Li, Marlene Taja-Moreno, Svetlana Gerdes, Steven D. Bruner, Valérie de Crécy-Lagard, and Andrew D. Hanson

Subjects

0301 basic medicine, animal structures, Protein family, Kinase, 030106 microbiology, food and beverages, Cell Biology, Bacterial genome size, Biology, Phosphate, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Biosynthesis, Phosphorylation, Bacimethrin, Molecular Biology, Gene

Abstract

The canonical kinase (ThiD) that converts the thiamin biosynthesis intermediate hydroxymethylpyrimidine (HMP) monophosphate into the diphosphate can also very efficiently convert free HMP into the monophosphate in prokaryotes, plants, and fungi. This HMP kinase activity enables salvage of HMP, but it is not substrate-specific and so allows toxic HMP analogs and damage products to infiltrate the thiamin biosynthesis pathway. Comparative analysis of bacterial genomes uncovered a gene, thiD2, that is often fused to the thiamin synthesis gene thiE and could potentially encode a replacement for ThiD. Standalone ThiD2 proteins and ThiD2 fusion domains are small (∼130 residues) and do not belong to any previously known protein family. Genetic and biochemical analyses showed that representative standalone and fused ThiD2 proteins catalyze phosphorylation of HMP monophosphate, but not of HMP or its toxic analogs and damage products such as bacimethrin and 5-(hydroxymethyl)-2-methylpyrimidin-4-ol. As strictly monofunctional HMP monophosphate kinases, ThiD2 proteins eliminate a potentially fatal vulnerability of canonical ThiD, at the cost of the ability to reclaim HMP formed by thiamin turnover.

Published

2017