Difference between revisions of "Maeda Lab:Publications"

From Maeda Lab
Jump to: navigation, search
Line 19: Line 19:
 
<ol>  
 
<ol>  
 
<li>'''Yokoyama R.'''''#'', '''de Oliveira M.V.V.'''''#'', '''Takeda-Kimura Y.''', Ishihara H., Alseekh S., Arrivault S., Kukshal V., Jez JM, Stitt M.,  Fernie A.R., '''Maeda H.A.*''' (2022) Point mutations that boost aromatic amino acid production and CO2 assimilation in plants [https://www.science.org/doi/10.1126/sciadv.abo3416 '''''Science Adv.'''''] ''online'', [https://news.wisc.edu/altered-gene-helps-plants-absorb-more-carbon-dioxide-produce-more-useful-compounds/ '''''UW News''''']. ''#two authors contributed equally''
 
<li>'''Yokoyama R.'''''#'', '''de Oliveira M.V.V.'''''#'', '''Takeda-Kimura Y.''', Ishihara H., Alseekh S., Arrivault S., Kukshal V., Jez JM, Stitt M.,  Fernie A.R., '''Maeda H.A.*''' (2022) Point mutations that boost aromatic amino acid production and CO2 assimilation in plants [https://www.science.org/doi/10.1126/sciadv.abo3416 '''''Science Adv.'''''] ''online'', [https://news.wisc.edu/altered-gene-helps-plants-absorb-more-carbon-dioxide-produce-more-useful-compounds/ '''''UW News''''']. ''#two authors contributed equally''
 +
 +
:<font color="#404040"> ''Aromatic compounds having unusual stability provide high-value chemicals and considerable promise for carbon storage. Terrestrial plants can convert atmospheric CO2 into diverse and abundant aromatic compounds. However, it is unclear how plants control the shikimate pathway that connects the photosynthetic carbon fixation with the biosynthesis of aromatic amino acids, the major precursors of plant aromatic natural products. This study identified suppressor of tyra2 (sota) mutations that deregulate the first step in the plant shikimate pathway by alleviating multiple effector-mediated feedback regulation in Arabidopsis thaliana. The sota mutant plants showed hyper-accumulation of aromatic amino acids accompanied by a striking 30% increase in net CO2 assimilation. The identified mutations can be used to enhance plant-based, sustainable conversion of atmospheric CO2 to high-energy and high-value aromatic compounds.''
  
 
<li>'''Koper K.''', Han S-W., Pastor D.C., Yoshikuni Y.,  '''Maeda H.A.*''' (2022) Evolutionary Origin and Functional Diversification of Aminotransferases '''''J. Biol. Chem.''''' ''Accepted''  
 
<li>'''Koper K.''', Han S-W., Pastor D.C., Yoshikuni Y.,  '''Maeda H.A.*''' (2022) Evolutionary Origin and Functional Diversification of Aminotransferases '''''J. Biol. Chem.''''' ''Accepted''  

Revision as of 20:19, 8 June 2022

Maeda lab banner 2020.jpg

Home        Research        Outreach        Diversity        Team        Pubs        Protocols       


Publications (*corresponding author)

Google Scholar citations
  1. Yokoyama R.#, de Oliveira M.V.V.#, Takeda-Kimura Y., Ishihara H., Alseekh S., Arrivault S., Kukshal V., Jez JM, Stitt M., Fernie A.R., Maeda H.A.* (2022) Point mutations that boost aromatic amino acid production and CO2 assimilation in plants Science Adv. online, UW News. #two authors contributed equally
    Aromatic compounds having unusual stability provide high-value chemicals and considerable promise for carbon storage. Terrestrial plants can convert atmospheric CO2 into diverse and abundant aromatic compounds. However, it is unclear how plants control the shikimate pathway that connects the photosynthetic carbon fixation with the biosynthesis of aromatic amino acids, the major precursors of plant aromatic natural products. This study identified suppressor of tyra2 (sota) mutations that deregulate the first step in the plant shikimate pathway by alleviating multiple effector-mediated feedback regulation in Arabidopsis thaliana. The sota mutant plants showed hyper-accumulation of aromatic amino acids accompanied by a striking 30% increase in net CO2 assimilation. The identified mutations can be used to enhance plant-based, sustainable conversion of atmospheric CO2 to high-energy and high-value aromatic compounds.
  2. Koper K., Han S-W., Pastor D.C., Yoshikuni Y., Maeda H.A.* (2022) Evolutionary Origin and Functional Diversification of Aminotransferases J. Biol. Chem. Accepted
  3. Yokoyama R.*, Kleven B., Gupta A., Wang Y., Maeda H.A.* (2022) 3-Deoxy-D-arabino-heptulosonate 7-phosphate synthase as the gatekeeper of plant aromatic natural product biosynthesis (2022) Curr. Opin. Plant Biol. online
  4. Lopez-Nieves S., El-Azaz J., Men Y., Holland C.K., Feng T., Brockington S.F., Jez J.M., Maeda HA* (2021) Two independently evolved natural mutations additively deregulate TyrA enzymes and boost tyrosine production in planta. Plant J online (full article)
    TPJ2022cover.jpg
    Tyrosine is a critical amino acid precursor for biosynthesis of numerous plant natural products, including betalain pigments that are uniquely produced in the plant order Caryophyllales. This study identified key residues involved in the evolution of deregulated TyrA enzymes that underlie the overaccumulation of tyrosine and betalains in core Caryophyllales. Furthermore, combined introduction of the identified residue together with one independently evolved in legume TyrAs (Schenck et al., 2017) converted highly-regulated Arabidopsis TyrA into a tyrosine-insensitive enzyme, demonstrating the utility of these natural mutations in elevating tyrosine levels in plants.
  5. Maeda H.A.* and Fernie A.R.* (2021) Evolutionary History of Plant Metabolism Ann. Rev. Plant Biol. 72, 185-216
  6. Yokoyama R., de Oliveira V.V.M., Kleven B., Maeda H.A.* (2021) The Entry Reaction of the Plant Shikimate Pathway is Subjected to Highly Complex Metabolite-Mediated Regulation Plant Cell 33, 671–696
    DHS icon.jpg
    The shikimate pathway interconnects the central carbon metabolism and biosynthesis of aromatic amino acids and a wide range of aromatic natural products. This study found that the first enzyme of the shikimate pathway, DAHP synthases (DHSs), are regulated by at least five downstream metabolites (i.e. tyrosine, tryptophan, chorimate, arogenate, caffeate), uncovering much more complex feedback regulation of the shikimate pathway in plants than in microbes. The findings will help us enhance the production of these essential amino acids and natural products in plants.
  7. Zhu F, Alseekh S, Koper K, Tong H, Nikoloski Z, Naake T, Liu H, Yan J, Brotman Y, Wen W, Maeda H, Cheng Y, Fernie AR*. (2021) Genome-wide association of the metabolic shifts underpinning dark-induced senescence in Arabidopsis. Plant Cell online
  8. Gibbs NM, Su SH, Lopez-Nieves S, Mann S, Alban C, Maeda HA, Masson PH*. (2021) Cadaverine regulates biotin synthesis to modulate primary root growth in Arabidopsis. Plant J 107:1283-1298.
  9. Yoo H, Shrivastava S, Lynch JH, Huang XQ, Widhalm JR, Guo L, Carter BC, Qian Y, Maeda HA, Ogas JP, Morgan JA, Marshall-Colón A, Dudareva N*. Overexpression of arogenate dehydratase reveals an upstream point of metabolic control in phenylalanine biosynthesis. Plant J 2021, 108:737-751.
  10. Naake T., Maeda H.A., Proost S., Tohge T., Fernie A.R.* (2020) Kingdom-wide analysis of the evolution of the plant type III polyketide synthase superfamily. Plant Physiol. online
  11. Schenck C.A., Westphal J., Jayaraman D., Garcia K., Wen J., Mysore K.S., Ané J.M., Sumner L.W., Maeda H.A.* (2020) Role of Cytosolic, Tyrosine-Insensitive Prephenate Dehydrogenase in Medicago truncatula. Plant Direct 4: e00218
  12. Maeda H.A.* (2019b) Harnessing evolutionary diversification of primary metabolism for plant synthetic biology J. Biol. Chem., 294, 16549-16566.' Invited review in "Natural product biosynthesis: What's next? A thematic series"
  13. Maeda H.A.* (2019a) Evolutionary diversification of primary metabolism and its contribution to plant chemical diversity Front. Plant Sci., 10 July 2019 Invited review on the special issue, "The Origin of Plant Chemodiversity".
  14. Wang M., Toda K., Block A., Maeda H.A.* (2019) TAT1 and TAT2 tyrosine aminotransferases have both distinct and shared functions in tyrosine metabolism and degradation in Arabidopsis thaliana. J. Biol. Chem. 294, 3563-3576.
  15. Lopez-Nieves S.*, Pringle A., Maeda H.A. (2019) Biochemical characterization of TyrA dehydrogenases from Saccharomyces cerevisiae (Ascomycota) and Pleurotus ostreatus (Basidiomycota) Arch Biochem Biophys. [Epub ahead of print]
  16. de Oliveira M.V.V., Jin X., Chen X., Griffith D., Batchu S., Maeda H.A.* (2019). Imbalance of tyrosine by modulating TyrA arogenate dehydrogenases impacts growth and development of Arabidopsis thaliana.Plant J. 97, 901-922.
  17. Smith S.D.*, Angelovici R., Heyduk K., Maeda H.A., Moghe G.D., Pires J.C., Widhalm J.R., Wisecaver J.H. (2019). The Renaissance of Comparative Biochemistry. Am. J. Bot.. 106, 3-13.
    NPhytol.jpg
  18. Lopez-Nieves S., Yang Y., Timoneda T., Wang M., Feng T., Smith S.A., Brockington S.F., Maeda H.A.* (2018) Relaxation of Tyrosine Pathway Regulation Underlies the Evolution of Betalain Pigmentation in Caryophyllales. New Phytologist 217, 896-908. Free view-only version Featured in Nature Plants, UW News, USDA NIFA, NY Times, and BBC (Spanish)
  19. Timoneda A., Sheehan H., Feng T., Lopez-Nieves S., Maeda H.A., Brockington S. (2018) Redirecting Primary Metabolism to Boost Production of Tyrosine-Derived Specialised Metabolites in Planta. Sci. Rep. 8; 17256
  20. Schenck C.A.. and Maeda H.A.* (2018) Tyrosine Biosynthesis, Metabolism, Catabolism in Plants. Phytochemistry 149, 82-102.
    This article provides a comprehensive review on tyrosine biosynthesis, catabolism, and metabolism to downstream specialized metabolites in plants.
  21. Hollland CK, Berkovich DA, Kohn ML, Maeda H, Jez JM. (2018) Structural Basis for Substrate Recognition and Inhibition of Prephenate Aminotransferase from Arabidopsis. Plant J. doi: 10.1111/tpj.13856.
  22. Schenck C.A., Men Y. and Maeda H.A.* (2017b) Conserved Molecular Mechanism of TyrA Dehydrogenase Substrate Specificity Underlying Alternative Tyrosine Biosynthetic Pathways in Plants and Microbes Frontiers Mol. Biosci. online
    2017 cover.jpg
  23. Schenck C.A., Holland C.K., Schneider M., Men Y., Lee S.G., Jez J. and Maeda H.A.* (2017a) Molecular Basis of the Evolution of Alternative Tyrosine Biosynthetic Routes in Plants. Nature Chem. Biol. 13, 1029-1035 Free view-only version Featured in UW News and Nature Plants.
  24. Wang M. and Maeda H.A.* (2017) Aromatic Amino Acid Aminotransferases in Plants. Phytochemistry Reviews, 1-29. DOI:10.1007/s11101-017-9520-6. Free view-only version
  25. Lynch JH, Orlova I, Zhao C, Guo L, Jaini R, Maeda H, Akhtar T, Cruz-Lebron J, Rhodes D, Morgan J, Pilot G, Pichersky E, Dudareva N. (2017) Multifaceted plant responses to circumvent Phe hyperaccumulation by downregulation of flux through the shikimate pathway and by vacuolar Phe sequestration. Plant J. 92, 939-950.
  26. Wang M., Lopez-Nieves S., Goldman I., Maeda H.A.* (2017) Limited Tyrosine Utilization Explains Lower Betalain Contents in Yellow than Red Table Beet Genotypes. J Agric Food Chem. 65, 4305–4313.
    Betalains are red and yellow alkaloid pigments derived from tyrosine. Previous studies showed that yellow pigments accumulate much less than red pigments. Through quantitative chemical analyses of different beet genotypes, this study found that increased tyrosine levels were positively correlated with elevated betalain accumulations among red but not yellow genotypes, suggesting that yellow beets are not efficiently converting tyrosine into betalain pigments. Thus, better utilization of the accumulated tyrosine can likely improve betaxanthin production in yellow beets.
  27. Wang M., Toda K., Maeda H.A.* (2016) Biochemical Properties and Subcellular Localization of Tyrosine Aminotransferases from Arabidopsis thaliana. Phytochemistry, 132, 16–25
  28. Maeda H.A.* (2016) Lignin biosynthesis: Tyrosine shortcut in grasses. Nature Plants 2, 16080 DOI: 10.1038/NPLANTS.2016.80
    Soybean cover.jpg
  29. Schenck C.A., Chen S., Siehl D., Maeda H.A.* (2015) Non-plastidic, Tyrosine-Insensitive Prephenate Dehydrogenases from Legumes. Nature Chem. Biol. 11, 52-57 *Featured on the Cover.
    L-Tyrosine (Tyr) and its plant-derived natural products are essential in both plants and humans. In plants, Tyr is generally assumed to be synthesized in the plastids via arogenate dehydrogenase (ADH) that is strictly inhibited by Tyr. Here we identified non-plastidic Tyr-insensitive prephenate dehydrogenases (PDHs) uniquely present in legumes, providing molecular evidence for the diversification of primary metabolic Tyr pathway via an alternative cytosolic PDH pathway in plants. Also, the Tyr-insensitive property of the identified PDH enzymes has immediate impacts on metabolic engineering to improve the production of Tyr and Tyr-derived natural products.
    PlantCellcover.jpg
  30. Dornfeld C., Weisberg A.J., Ritesh KC, Dudareva N., Jelesko J.G., Maeda H.A.* (2014) Phylobiochemical Characterization of Class-Ib Aspartate/Prephenate Aminotransferases Reveals Evolution of the Plant Arogenate Phenylalanine Pathway Plant Cell 26, 3101-3114
  31. Plants use phenylalanine to produce abundant and diverse phenylpropanoid compounds, such as flavonoids, tannins, and lignin. Through phylogenetic, bioinformatic, and biochemical analyses of prephenate aminotransferase enzymes from plant and bacterial lineages, this study revealed unique evolutionary history and molecular changes of key enzymes responsible for phenylalanine biosynthesis in plants. The findings assist the rational design of antimicrobial drugs and herbicides, but also highlight the use of phylobiochemical characterization of enzymes from deep taxonomic lineages in determining key molecular changes that lead to the evolution of new metabolic pathways. UW news release.
  32. Luby C., Maeda H.A., Goldman I. (2014) Genetic and Phenological Variation of Tocochromanol (Vitamin E) Content in Wild (Daucus carota L. var. carota) and Domesticated Carrot (D. carota L. var. sativa) Horticulture Research 1:15
  33. Maeda H., Song W., Sage T.L., DellaPenna D. (2014) Role of Callose Synthases in Transfer Cell Wall Development in Tocopherol Deficient Arabidopsis Mutants. Front. Plant Sci. 5:46.
  34. Yoo H., Widhalma J.R., Qiana Y., Maeda H., Cooperc B.R., Jannaschc A.S., Gondae I., Lewinsohne E., Rhodes D., Dudareva D. (2013) An Alternative Pathway Contributes to Phenylalanine Biosynthesis in Plants via a Cytosolic Tyrosine:Phenylpyruvate Aminotransferase. Nature Commun. 4:2833
  35. Maeda H. and Dudareva N. (2012) The Shikimate Pathway and Aromatic Amino Acid Biosynthesis in Plants. Ann. Rev. Plant Biol. Vol. 63, 73-105
  36. Muhlemann J.K., Maeda H., Chang C.Y., San Miguel P., Baxter I., Cooper B., Perera M.A., Nikolau B.J., Vitek O., Morgan J.A., Dudareva N. (2012) Developmental Changes in the Metabolic Network of Snapdragon Flowers. PLoS ONE 7(7): e40381
  37. Maeda H., Yoo H., and Dudareva N. (2011) Prephenate Aminotransferase Directs Plant Phenylalanine Biosynthesis via Arogenate. Nature Chem. Biol., DOI:10.1038/nchembio.485
  38. Maeda H., Shasany A.K., Schnepp J., Orlova1 I., Taguchi G., Cooper B.R., Rhodes D., Pichersky E. and Dudareva N. (2010) RNAi Suppression of Arogenate Dehydratase1 Reveals That Phenylalanine Is Synthesized Predominantly via the Arogenate Pathway in Petunia Petals. Plant Cell 22, 832-849 *Described as a Research Highlight in Nature Chem. Biol. 6, 310
  39. Song W., Maeda H., and DellaPenna D. (2010) Mutations of the ER to plastid lipid transporters (TGD1, 2, 3 and 4) and the ER oleate desaturase (FAD2) suppress the low temperature-induced phenotype of Arabidopsis tocopherol deficient mutant vte2. Plant J. 62, 1004-1018
  40. Orlova I., Nagegowda D.A., Kish C.M., Gutensohn M., Maeda H., Varbanova M., Fridman E., Yamaguchi S., Hanada A., Kamiya Y., Krichevsky A., Citovsky V., Pichersky E., and Dudareva N. (2009) The Small Subunit Snapdragon Geranyl Diphosphate Synthase Modifies the Chain Length Specificity of Tobacco Geranylgeranyl Diphosphate Synthase in Planta. Plant Cell 21, 4002-4017
  41. Maeda H., Sage T.L., Isaac G.., Welti R., and DellaPenna D. (2008) Tocopherols Modulate Extra-Plastidic Polyunsaturated Fatty Acid Metabolism in Arabidopsis at Low Temperature. Plant Cell 20, 452-470 *Described in the Featured Article of the issue Plant Cell 20, 246
  42. Maeda H. and DellaPenna D. (2007) Tocopherol Functions in Photosynthetic Organisms. Curr. Opin. Plant Biol. 10, 260-265
  43. Maeda H., Song W., Sage T.L. and DellaPenna D. (2007) Tocopherols Play a Limited Role in Photoprotection but a Crucial Role in Chilling Adaptation in Arabidopsis Leaves. In Current Advances in the Biochemistry and Cell Biology of Plant Lipids, C. Benning and J. Ohlrogge, eds (Aardvark Global Publishing Company, LLC, Salt Lake City, UT), pp. 112-115 PDF download (4.5 MB)
  44. Maeda H., Song W., Sage T.L. and DellaPenna D. (2006) Tocopherols Play a Crucial Role in Low Temperature Adaptation and Phloem Loading in Arabidopsis. Plant Cell 18, 2710-2732 *Highlighted on the Cover of the issue.
  45. Sakuragi Y., Maeda H., DellaPenna D. and Bryant D.A. (2006) α-Tocopherol Plays a Role in Photosynthesis and Macronutrient Homeostasis of the Cyanobacterium Synechocystis sp. PCC 6803 That is Independent of its Antioxidant Function. Plant Physiol. 141, 508-521
  46. Maeda H., Sakuragi Y., Bryant D.A., and DellaPenna D. (2005) Tocopherols Protect Synechocystis sp. Strain PCC 6803 from Lipid Peroxidation. Plant Physiol. 138, 1422-1435
  47. Cheng Z., Sattler S., Maeda H., Sakuragi Y., Bryant D.A., and DellaPenna D. (2003) Highly Divergent Methyltransferases Catalyze a Conserved Reaction in Tocopherol and Plastoquinone Synthesis in Cyanobacteria and Photosynthetic Eukaryotes. Plant Cell 15, 2343-2356
  48. Okazawa A., Maeda H., Fukusaki E., Katakura Y., and Kobayashi A. (2000) In Vitro Selection of Hematoporphyrin Binding DNA Aptamers. Bioorg. Med. Chem. Lett. 10, 2653-2656
  49. Fukusaki E., Kato T., Maeda H., Kawazoe N., Ito Y., Okazawa A., Kajiyama S. and Kobayashi A. (2000) DNA Aptamers that Bind to Chitin. Bioorg. Med. Chem. Lett. 10, 423-425
  50. </ol>