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2. The Mediator complex subunit MED25 interacts with HDA9 and PIF4 to regulate thermomorphogenesis

Author

Shapulatov, Umidjon, Van zanten, Martijn, Van hoogdalem, Mark, Meisenburg, Mara, Van hall, Alexander, Kappers, Iris, Fasano, Carlo, Facella, Paolo, Loh, Chi Cheng, Perrella, Giorgio, Van der krol, Alexander, Plant Stress Resilience, Molecular Plant Physiology, Sub Plant Stress Resilience, Sub Molecular Plant Physiology, Plant Stress Resilience, Molecular Plant Physiology, Sub Plant Stress Resilience, and Sub Molecular Plant Physiology

Subjects
Histone Deacetylases/genetics, Crop Physiology, Basic Helix-Loop-Helix Transcription Factors/genetics, Physiology, Transcription Factors/genetics, Plant Science, Plant, Arabidopsis/metabolism, Arabidopsis Proteins/genetics, Phytochrome/metabolism, Gene Expression Regulation, Gene Expression Regulation, Plant, Genetics, Life Science, Laboratorium voor Plantenfysiologie, EPS, Gewasfysiologie, Mediator Complex/genetics, Laboratory of Plant Physiology
Abstract

Thermomorphogenesis is, among other traits, characterized by enhanced hypocotyl elongation due to the induction of auxin biosynthesis genes like YUCCA8 by transcription factors, most notably PHYTOCHROME INTERACTING FACTOR 4 (PIF4). Efficient binding of PIF4 to the YUCCA8 locus under warmth depends on HISTONE DEACETYLASE 9 (HDA9) activity, which mediates histone H2A.Z depletion at the YUCCA8 locus. However, HDA9 lacks intrinsic DNA-binding capacity, and how HDA9 is recruited to YUCCA8, and possibly other PIF4-target sites, is currently not well understood. The Mediator complex functions as a bridge between transcription factors bound to specific promoter sequences and the basal transcription machinery containing RNA polymerase II. Mutants of Mediator component Mediator25 (MED25) exhibit reduced hypocotyl elongation and reduced expression of YUCCA8 at 27°C. In line with a proposed role for MED25 in thermomorphogenesis in Arabidopsis (Arabidopsis thaliana), we demonstrated an enhanced association of MED25 to the YUCCA8 locus under warmth and interaction of MED25 with both PIF4 and HDA9. Genetic analysis confirmed that MED25 and HDA9 operate in the same pathway. Intriguingly, we also showed that MED25 destabilizes HDA9 protein. Based on our findings, we propose that MED25 recruits HDA9 to the YUCCA8 locus by binding to both PIF4 and HDA9.

Published
2023

3. Arabidopsis latent virus 1, a comovirus widely spread in Arabidopsis thaliana collections

Author

Verhoeven, Ava, Kloth, Karen J., Kupczok, Anne, Oymans, Geert H., Damen, Janna, Rijnsburger, Karin, Jiang, Zhang, Deelen, Cas, Sasidharan, Rashmi, Van zanten, Martijn, Van der vlugt, René A. A., Plant Stress Resilience, Sub Plant Stress Resilience, Sub Plant-Environment Signaling, Sub Molecular Plant Physiology, Plant-Environment Signaling, Molecular Plant Physiology, Plant Stress Resilience, Sub Plant Stress Resilience, Sub Plant-Environment Signaling, Sub Molecular Plant Physiology, Plant-Environment Signaling, and Molecular Plant Physiology

Subjects
drought resilience, Arabidopsis thaliana, Bioinformatics, Physiology, Laboratory of Virology, comovirus, OT Team Fruit-Bomen, RNA sequencing, Plant Science, PE&RC, Laboratorium voor Entomologie, Arabidopsis latent virus 1 (ArLV1), Laboratorium voor Virologie, Biointeractions and Plant Health, sequence read archives, Bioinformatica, EPS, Laboratory of Entomology, Laboratory of Nematology, Laboratorium voor Nematologie
Abstract

SummaryTranscriptome studies of Illumina RNA-seq datasets of different Arabidopsis thaliana natural accessions and T-DNA mutants revealed the presence of two virus-like RNA sequences which showed the typical two segmented genome characteristics of a comovirus.This comovirus did not induce any visible symptoms in infected Arabidopsis plants cultivated under standard laboratory conditions. Hence it was named Arabidopsis latent virus 1 (ArLV1). Virus infectivity in Arabidopsis plants was confirmed by RT-qPCR, transmission electron microscopy and mechanical inoculation. ArLV1 can also mechanically infect Nicotiana benthamiana, causing distinct mosaic symptoms.A bioinformatics investigation of Arabidopsis RNA-Seq repositories, including nearly 6500 Sequence Read Archives (SRAs) in the NCBI SRA database, revealed the presence of ArLV1 in 25% of all archived natural Arabidopsis accessions and in 8.5% of all analyzed SRAs. ArLV1 could also be detected in Arabidopsis plants collected from the wild.ArLV1 is highly seed-transmissible with up to 40% incidence on the progeny derived from infected Arabidopsis plants. This has likely led to a worldwide distribution in the model plant Arabidopsis with yet unknown effects on plant performance in a substantial number of studies.Plain language summaryWe identified Arabidopsis latent virus 1 (ArLV1), a comovirus that infects the model plant Arabidopsis thaliana without causing any visible symptoms. It is efficiently spread by transmission via seeds to the plant progeny. ArLV1 is infectious to Arabidopsis plants and another model plant, Nicotiana benthamiana. By analyzing public sequencing data, we found that ArLV1 is widely spread in Arabidopsis laboratory collections worldwide. Moreover, it was also detected in wild Arabidopsis plants collected from different locations in the Netherlands and Spain, suggesting that it is a virus that naturally occurs in Arabidopsis.

Published
2023

4. SeedTransNet: a directional translational network revealing regulatory patterns during seed maturation and germination

Author

Bai, Bing, Schiffthaler, Bastian, van der Horst, Sjors, Willems, Leo, Vergara, Alexander, Karström, Jacob, Mähler, Niklas, Delhomme, Nicolas, Bentsink, Leónie, Hanson, Johannes, Molecular Plant Physiology, Sub Molecular Plant Physiology, Molecular Plant Physiology, and Sub Molecular Plant Physiology

Subjects
Seeds/metabolism, Arabidopsis thaliana, translatome profiling, Physiology, seed maturation, Botany, Germination/genetics, seed germination, Plant Science, mRNA regulation, Botanik, Arabidopsis/metabolism, ribosome, Seedlings/metabolism, Life Science, Plant Biotechnology, Laboratorium voor Plantenfysiologie, EPS, Transcriptome, Laboratory of Plant Physiology
Abstract

We describe the dramatic shifts in translation that occur during seed maturation, germination, and seedling establishment. Using network analysis, we identify putative regulatory relationships and subsequently confirm some of them in vivo.Seed maturation is the developmental process that prepares the embryo for the desiccated waiting period before germination. It is associated with a series of physiological changes leading to the establishment of seed dormancy, seed longevity, and desiccation tolerance. We studied translational changes during seed maturation and observed a gradual reduction in global translation during seed maturation. Transcriptome and translatome profiling revealed specific reduction in the translation of thousands of genes. By including previously published data on germination and seedling establishment, a regulatory network based on polysome occupancy data was constructed: SeedTransNet. Network analysis predicted translational regulatory pathways involving hundreds of genes with distinct functions. The network identified specific transcript sequence features suggesting separate translational regulatory circuits. The network revealed several seed maturation-associated genes as central nodes, and this was confirmed by specific seed phenotypes of the respective mutants. One of the regulators identified, an AWPM19 family protein, PM19-Like1 (PM19L1), was shown to regulate seed dormancy and longevity. This putative RNA-binding protein also affects the translational regulation of its target mRNA, as identified by SeedTransNet. Our data show the usefulness of SeedTransNet in identifying regulatory pathways during seed phase transitions.

Published
2023

5. SeedTransNet: A directional translational network revealing regulatory patterns during seed maturation and germination

Author

Molecular Plant Physiology, Sub Molecular Plant Physiology, Bai, Bing, Schiffthaler, Bastian, van der Horst, Sjors, Willems, Leo, Vergara, Alexander, Karström, Jacob, Mähler, Niklas, Delhomme, Nicolas, Bentsink, Leónie, Hanson, Johannes, Molecular Plant Physiology, Sub Molecular Plant Physiology, Bai, Bing, Schiffthaler, Bastian, van der Horst, Sjors, Willems, Leo, Vergara, Alexander, Karström, Jacob, Mähler, Niklas, Delhomme, Nicolas, Bentsink, Leónie, and Hanson, Johannes

Published
2023

6. The Mediator complex subunit MED25 interacts with HDA9 and PIF4 to regulate thermomorphogenesis

Author

Plant Stress Resilience, Molecular Plant Physiology, Sub Plant Stress Resilience, Sub Molecular Plant Physiology, Shapulatov, Umidjon, Van zanten, Martijn, Van hoogdalem, Mark, Meisenburg, Mara, Van hall, Alexander, Kappers, Iris, Fasano, Carlo, Facella, Paolo, Loh, Chi Cheng, Perrella, Giorgio, Van der krol, Alexander, Plant Stress Resilience, Molecular Plant Physiology, Sub Plant Stress Resilience, Sub Molecular Plant Physiology, Shapulatov, Umidjon, Van zanten, Martijn, Van hoogdalem, Mark, Meisenburg, Mara, Van hall, Alexander, Kappers, Iris, Fasano, Carlo, Facella, Paolo, Loh, Chi Cheng, Perrella, Giorgio, and Van der krol, Alexander

Published
2023

7. Arabidopsis latent virus 1, a comovirus widely spread in Arabidopsis thaliana collections

Author

Plant Stress Resilience, Sub Plant Stress Resilience, Sub Plant-Environment Signaling, Sub Molecular Plant Physiology, Plant-Environment Signaling, Molecular Plant Physiology, Verhoeven, Ava, Kloth, Karen J., Kupczok, Anne, Oymans, Geert H., Damen, Janna, Rijnsburger, Karin, Jiang, Zhang, Deelen, Cas, Sasidharan, Rashmi, Van zanten, Martijn, Van der vlugt, René A. A., Plant Stress Resilience, Sub Plant Stress Resilience, Sub Plant-Environment Signaling, Sub Molecular Plant Physiology, Plant-Environment Signaling, Molecular Plant Physiology, Verhoeven, Ava, Kloth, Karen J., Kupczok, Anne, Oymans, Geert H., Damen, Janna, Rijnsburger, Karin, Jiang, Zhang, Deelen, Cas, Sasidharan, Rashmi, Van zanten, Martijn, and Van der vlugt, René A. A.

Published
2023

8. Crane fly semiochemical overrules plant control over cyanobiont in Azolla symbioses

Author

Sub Plant Stress Resilience, Sub Molecular Plant Physiology, Molecular Plant Physiology, Plant Stress Resilience, Güngör, Erbil, Savary, Jérôme, Adema, Kelvin, Dijkhuizen, Laura W., Keilwagen, Jens, Himmelbach, Axel, Mascher, Martin, Koppers, Nils, Bräutigam, Andrea, Hove, Charles van, Riant, Olivier, Nierzwicki-Bauer, Sandra, Schluepmann, Henriette, Sub Plant Stress Resilience, Sub Molecular Plant Physiology, Molecular Plant Physiology, Plant Stress Resilience, Güngör, Erbil, Savary, Jérôme, Adema, Kelvin, Dijkhuizen, Laura W., Keilwagen, Jens, Himmelbach, Axel, Mascher, Martin, Koppers, Nils, Bräutigam, Andrea, Hove, Charles van, Riant, Olivier, Nierzwicki-Bauer, Sandra, and Schluepmann, Henriette

Published
2023

9. Arabidopsis thaliana rosette habit is controlled by combined light and energy signaling converging on transcriptional control of the TALE homeobox gene ATH1

Author

Molecular Plant Physiology, Translational Plant Biology, Sub Translational Plant Biology, Sub Molecular Plant Physiology, Shokrian Hajibehzad, Shahram, Silva, Savani S, Peeters, Niels, Stouten, Evelien, Buijs, Guido, Smeekens, Sjef, Proveniers, Marcel, Molecular Plant Physiology, Translational Plant Biology, Sub Translational Plant Biology, Sub Molecular Plant Physiology, Shokrian Hajibehzad, Shahram, Silva, Savani S, Peeters, Niels, Stouten, Evelien, Buijs, Guido, Smeekens, Sjef, and Proveniers, Marcel

Published
2023

10. Sucrose-mediated translational stalling involves a conserved ribosomal pocket

Author

Molecular Plant Physiology, Sub Molecular Plant Physiology, Sub Structural Biochemistry, Structural Biochemistry, Horst, Sjors van der, Englmeier, Robert, Hanson, Johannes, Smeekens, Sjef, Förster, Friedrich, Molecular Plant Physiology, Sub Molecular Plant Physiology, Sub Structural Biochemistry, Structural Biochemistry, Horst, Sjors van der, Englmeier, Robert, Hanson, Johannes, Smeekens, Sjef, and Förster, Friedrich

Published
2023

11. Carbon utilization and growth-inhibition of citrus-colonizing Phyllosticta species

Author

Buijs, Valerie A., Zuijdgeest, Xander C.l., Groenewald, Johannes Z., Crous, Pedro W., De Vries, Ronald P., Sub Molecular Microbiology, Sub Molecular Plant Physiology, Molecular Microbiology, Molecular Plant Physiology, Sub Molecular Microbiology, Sub Molecular Plant Physiology, Molecular Microbiology, Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute, Westerdijk Fungal Biodiversity Institute - Evolutionary Phytopathology, and Westerdijk Fungal Biodiversity Institute - Fungal Physiology

Subjects
0106 biological sciences, Citrus, Sugar beet pulp, Phyllosticta, Range (biology), Citrus black spot, 01 natural sciences, Carbon utilization, Fungal plant pathogens, 03 medical and health sciences, Ascomycota, Genus, Botany, Genetics, Phyllosticta capitalensis, medicine, Gene, Ecology, Evolution, Behavior and Systematics, Plant Diseases, 030304 developmental biology, 0303 health sciences, biology, food and beverages, biology.organism_classification, medicine.disease, Carbon, Laboratorium voor Phytopathologie, Infectious Diseases, Laboratory of Phytopathology, Sugar beet, EPS, CAZymes, 010606 plant biology & botany
Abstract

The genus Phyllosticta includes both endophytic and phytopathogenic species that occur on a broad range of plant hosts, including Citrus. Some pathogenic species cause severe disease, such as Phyllosticta citricarpa, the causal agent of Citrus Black Spot (CBS). In contrast, other species, such as Phyllosticta capitalensis, have an endophytic lifestyle in numerous plant hosts. Carbon utilization capabilities are hypothesized to influence both host range and lifestyle, and are in part determined by the set of Carbohydrate Active Enzyme (CAZyme) encoding genes of a species. In this study, carbon utilization capabilities of five Phyllosticta species were determined, as well as the CAZyme repertoire (CAZome) encoded in their genomes. Little variation was found among species in terms of carbon utilization capabilities and CAZome. However, one of the tested carbon sources, sugar beet pulp (SBP), inhibited growth of the plant pathogens, also when combined with another carbon source, while endophytic species remained unaffected.

Published
2021

12. Azolla ferns testify: seed plants and ferns share a common ancestor for leucoanthocyanidin reductase enzymes

Author

Güngör, Erbil, Brouwer, Paul, Dijkhuizen, Laura W., Shaffar, Dally Chaerul, Nierop, Klaas G.j., Vos, Ric C.h., Sastre Toraño, Javier, Meer, Ingrid M., Schluepmann, Henriette, Molecular Plant Physiology, Sub Molecular Plant Physiology, GeoLab Algemeen, Afd Chemical Biology and Drug Discovery, Dep GeoLab, Chemical Biology and Drug Discovery, Molecular Plant Physiology, Sub Molecular Plant Physiology, GeoLab Algemeen, Afd Chemical Biology and Drug Discovery, Dep GeoLab, and Chemical Biology and Drug Discovery

Subjects
Nostoc, Physiology, phenolics, PIP‐family reductases, RNA-sequencing, RNA‐sequencing, Plant Science, Catechin, Anthocyanins, chemistry.chemical_compound, Biosynthesis, Phylogenomics, Botany, PIP-family reductases, Azolla, Full Paper, biology, Research, Leucoanthocyanidin reductase, Full Papers, biology.organism_classification, leucoanthocyanidin reductase, Azolla filiculoides, chemistry, Seeds, flavonoids, Ferns, BIOS Applied Metabolic Systems, Bioscience, Fern, Oxidoreductases, proanthocyanidins, Biogenesis
Abstract

Summary Questions about in vivo substrates for proanthocyanidin (PA) biosynthesis and condensation have not been resolved and wide gaps in the understanding of transport and biogenesis in ‘tannosomes’ persist. Here we examined the evolution of PA biosynthesis in ferns not previously reported, asking what PAs are synthesised and how.Chemical and gene‐expression analyses were combined to characterise PA biosynthesis, leveraging genome annotation from the floating fern Azolla filiculoides. In vitro assay and phylogenomics of PIP‐dehydrogenases served to infer the evolution of leucoanthocyanidin reductase (LAR).Sporophyte‐synthesised (epi)catechin polymers, averaging only seven subunits, accumulated to 5.3% in A. filiculoides, and 8% in A. pinnata biomass dry weight. Consistently, a LAR active in vitro was highly expressed in A. filiculoides. LAR, and paralogous fern WLAR‐enzymes with differing substrate binding sites, represent an evolutionary innovation of the common ancestor of fern and seed plants.The specific ecological niche of Azolla ferns, a floating plant–microbe mat massively fixing CO2 and N2, shaped their metabolism in which PA biosynthesis predominates and employs novel fern LAR enzymes. Characterisation of in vivo substrates of these LAR, will help to shed light on the recently assigned and surprising dual catalysis of LAR from seed plants.

Published
2021

13. Potential Fungi Isolated From Anti-biodegradable Chinese Medicine Residue to Degrade Lignocellulose

Author

Cheng, Min, Wijayawardene, Nalin N., Promputtha, Itthayakorn, de Vries, Ronald P., Lan, Yongzhe, Luo, Gang, Wang, Meizhu, Li, Qirui, Guo, Xinyao, Wang, Feng, Liu, Yanxia, Kang, Yingqian, Molecular Plant Physiology, Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute, and Westerdijk Fungal Biodiversity Institute - Fungal Physiology

Subjects
fungal diversity, Microbiology (medical), hydrolysis, filamentous fungi, ITS, synergistic fungal combinations, Microbiology, CAZymes
Abstract

Traditional Chinese medicine is one of the ancient medicines which is popular in Asian countries, among which the residue produced by the use of anti-biodegradables is endless, and causes significant adverse impacts on the environment. However, the high acidity of anti-biodegradable residues and some special biological activities make it difficult for microorganisms to survive, resulting in a very low degradation rate of lignocellulose in naturally stacked residues, which directly impedes the degradation of residues. We aimed to identify the fungal strains that efficiently biodegrade anti-biodegradable residue and see the possibility to improve the biodegradation of it and other agricultural wastes by co-cultivating these fungi. We isolated 302 fungal strains from anti-biodegradable residue to test hydrolysis ability. Finally, we found Coniochaeta sp., Fomitopsis sp., Nemania sp., Talaromyces sp., Phaeophlebiopsis sp. which inhabit the anti-biodegradable residues are capable of producing higher concentrations of extracellular enzymes. Synergistic fungal combinations (viz., Fomitopsis sp. + Phaeophlebiopsis sp.; Talaromyces sp. + Coniochaeta sp. + Fomitopsis sp.; Talaromyces sp. + Fomitopsis sp. + Piloderma sp. and Talaromyces sp. + Nemania sp. + Piloderma sp.) have better overall degradation effect on lignocellulose. Therefore, these fungi and their combinations have strong potential to be further developed for bioremediation and biological enzyme industrial production.

Published
2022

14. Unraveling the regulation of sugar beet pulp utilization in the industrially relevant fungus Aspergillus niger

Author

Garrigues, Sandra, Kun, Roland S., Peng, Mao, Bauer, Diane, Keymanesh, Keykhosrow, Lipzen, Anna, Ng, Vivian, Grigoriev, Igor V., de Vries, Ronald P., Molecular Plant Physiology, Sub Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, Molecular Plant Physiology, and Sub Molecular Plant Physiology

Subjects
Multidisciplinary, Mycology, General, Microbial metabolism
Abstract

Efficient utilization of agro-industrial waste, such as sugar beet pulp, is crucial for the bio-based economy. The fungus Aspergillus niger possesses a wide array of enzymes that degrade complex plant biomass substrates, and several regulators have been reported to play a role in their production. The role of the regulators GaaR, AraR, and RhaR in sugar beet pectin degradation has previously been reported. However, genetic regulation of the degradation of sugar beet pulp has not been assessed in detail. In this study, we generated a set of single and combinatorial deletion mutants targeting the pectinolytic regulators GaaR, AraR, RhaR, and GalX as well as the (hemi-)cellulolytic regulators XlnR and ClrB to address their relative contribution to the utilization of sugar beet pulp. We show that A.niger has a flexible regulatory network, adapting to the utilization of (hemi-)cellulose at early timepoints when pectin degradation is impaired.

Published
2022

15. Detailed analysis of the D-galactose catabolic pathways in Aspergillus niger reveals complexity at both metabolic and regulatory level

Author

Chroumpi, Tania, Martínez-Reyes, Natalia, Kun, Roland S., Peng, Mao, Lipzen, Anna, Ng, Vivian, Tejomurthula, Sravanthi, Zhang, Yu, Grigoriev, Igor V., Mäkelä, Miia R., de Vries, Ronald P., Garrigues, Sandra, Molecular Plant Physiology, Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, Department of Microbiology, Helsinki Institute of Sustainability Science (HELSUS), Fungal Genetics and Biotechnology, Westerdijk Fungal Biodiversity Institute, and Westerdijk Fungal Biodiversity Institute - Fungal Physiology

Subjects
EXPRESSION, Oxido-reductive D-galactose catabolic pathway, CELLULASE INDUCTION, Pentose Catabolic Pathway, Plant Biology, Microbiology, Leloir pathway, Affordable and Clean Energy, Transcription factors, Genetics, Biomass, OXIDOREDUCTIVE PATHWAY, D-galactose catabolism, Pentose Catabolic Pathway (PCP), 11832 Microbiology and virology, ALPHA-GALACTOSIDASE, Galactose, BETA-GALACTOSIDASE, DEGRADATION, GENE, HYPOCREA-JECORINA, Aspergillus, TRANSCRIPTIONAL ACTIVATOR XLNR, Pectins, D-XYLOSE REDUCTASE, Aspergillus niger
Abstract

Funding Information: TC was supported by a grant of the NWO ALWOP.233 to RPdV. RSK and SG were supported by a grant of the Applied Science division (TTW) of NWO and the Technology Program of the Ministry of Infrastructure and Water Management 15807 to RPdV. The work conducted by the U.S. Department of Energy Joint Genome Institute, a DOE Office of Science User Facility, was supported by the Office of Science of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231. The Academy of Finland grant no. 308284 to MRM is also acknowledged. Publisher Copyright: © 2022 The Author(s) The current impetus towards a sustainable bio-based economy has accelerated research to better understand the mechanisms through which filamentous fungi convert plant biomass, a valuable feedstock for biotechnological applications. Several transcription factors have been reported to control the polysaccharide degradation and metabolism of the resulting sugars in fungi. However, little is known about their individual contributions, interactions and crosstalk. D-galactose is a hexose sugar present mainly in hemicellulose and pectin in plant biomass. Here, we study D-galactose conversion by Aspergillus niger and describe the involvement of the arabinanolytic and xylanolytic activators AraR and XlnR, in addition to the D-galactose-responsive regulator GalX. Our results deepen the understanding of the complexity of the filamentous fungal regulatory network for plant biomass degradation and sugar catabolism, and facilitate the generation of more efficient plant biomass-degrading strains for biotechnological applications.

Published
2022

16. Fungal strain engineering from understanding towards applications

Author

Meng, Jiali, Sub Molecular Plant Physiology, Molecular Plant Physiology, de Vries, Ronald, Mäkelä, M.R., and University Utrecht

Subjects
CRISPR/Cas9 technology, fungal cell factories, transcription factors, sugar transport system, Lignocellulose biomassa, Filamenteuze schimmels, schimmel cel-fabrieken, biotechnologische toepassingen, CRISPR/Cas9-technologie, primaire koolstofmetabolisme, xylitol productie, metabolische engineering, transcriptiefactoren, suiker transportsysteem, filamentous fungi, biotechnological applications, primary carbon metabolism, xylitol production, metabolic engineering, lignocellulosic biomass
Abstract

Lignocellulosic biomass is an abundant and renewable resource, and has a promising potential as an alternative to fossil resources for industrial bioproduction of biofuels and value-added biochemicals. Filamentous fungi are the most important and efficient plant biomass degrading microorganisms and are widely used as cell factories in many industries. Fungal strain engineering has been applied for the development of more robust and versatile filamentous fungal cell factories, and considerable progress have been made in recent years, as described in Chapter 1. A thorough and comprehensive understanding of fungal physiological processes involved in plant biomass utilization is an essential prerequisite of rational and feasible strain engineering. Advances in omics technologies allow the important development of systems biology, and new genetic tools have been developed for improving the efficiency of genetic engineering of filamentous fungi, such as CRISPR/Cas9 technology. Chapter 2 showed that A. niger has the capacity to accumulate xylitol from lignocellulosic biomass and metabolic engineering is highly effective for the improvement of xylitol production in A. niger. This provides the industrial production of xylitol with an attractive alternative, as the direct use of lignocellulosic biomass by A. niger highly simplifies the xylitol bioproduction process. Besides, there are other crucial aspects in the process of xylitol production, which could be alternative targets for strain engineering, including the release of pentoses from lignocellulosic biomass and the transport of pentoses and polyols. The subsequent study showed that the manipulation of the xylanolytic transcriptional activator XlnR also effectively increased xylitol production from lignocellulosic biomass in A. niger. The transport of D-xylose was also considered to further stimulate xylitol production in Chapter 3. In addition to three characterized D-xylose transporters (XltA, XltB and XltC), a fourth D-xylose transporter (XltD) was identified in A. niger. XltD has similar efficiency as XltA, while XltB may be not a major D-xylose transporter under the tested conditions. The results also showed the existence of more D-xylose transporters in A. niger. Unfortunately, the modification of one D-xylose transporter in A. niger alone did not affect xylitol production, showing the complexity and redundancy of sugar transport system similar to sugar metabolism in A. niger. In Chapter 4, an L-arabitol transporter, LatA, was identified with high specificity for L-arabitol in A. niger and its homologs are widely present in Ascomycete fungi. Moreover, the deletion of latA positively affected L-arabitol production from wheat bran and sugar beet pulp, suggesting that this gene could be a target for the improvement of microbial cell factories. In Chapter 5, the interaction between three transcription factors GalX, GalR and AraR in D-galactose and L-arabinose catabolism was investigated in A. nidulans, revealing the involvement of all these regulators in D-galactose catabolism and the compensation phenomenon between different regulators. To summarize, the results of this thesis described different aspects of the physiology of Aspergillus species from metabolic and regulatory networks to sugar transport systems, which improve the understanding of these model fungi and facilitate the biotechnological applications of fungal cell factories for the production of valuable biochemicals.

Published
2022

17. Unraveling the diversity within CAZy families related to hemicellulose degradation

Author

Li, Xinxin, Sub Molecular Plant Physiology, Molecular Plant Physiology, de Vries, Ronald, Kabel, Mirjam, and University Utrecht

Subjects
fylogenetische analyse, hemicellulose degradatie, genoom mijnen, phylogenetic analysis, genome mining, CAZyme characterization, functional diversification, functionele diversificatie, hemicellulose degradation, CAZyme karakterisering
Abstract

Agro-food industrial side streams known as lignocellulosic wastes have received much attention in the last years. These side streams are rich in cellulose, hemicellulose and lignin and can be converted into an array of value-added bioproducts with huge market potentials. Effective bioconversion requires overcoming the recalcitrance of the cell walls of lignocellulosic residues. Hemicellulose is tightly linked to cellulose through hydrogen bonding and to lignin via ester bonds, and its degradation can significantly alter the strength and microstructure of cell walls, thereby improving the overall degradation of agro-food residues. The hydrolysis of hemicellulose requires a variety of fungal enzymes. To date, a considerable number of enzymes have been included into different families in the Carbohydrate Active Enzyme (CAZy) database. However, most of them lack biochemical characterization data, hindering the understanding of diversity within families and the selection of optimal candidates from families for applications. In this thesis, I selectively characterized unknown CAZymes from different CAZy families involved in hemicellulose degradation through fungal genome mining and phylogenetic analysis. Our results discovered novel activities in CAZy families, e.g., feruloyl esterase / acetyl xylan esterase in CE1, xylobiohydrolase in GH30, and endoxyloglucanase in GH44. In addition, I discovered that the expansion of endoxylanases (GH10 and GH11) and α-L-arabinofuranosidase (GH51, GH54, and GH62) in Penicillium subrubescens is followed by functional diversification.

Published
2022

18. MYC2-Activated TRICHOME BIREFRINGENCE-LIKE37 Acetylates Cell Walls and Enhances Herbivore Resistance

Author

Sun, Aiqing, Yu, Bo, Zhang, Qian, Peng, Yu, Yang, Jing, Sun, Yonghua, Qin, Ping, Jia, Tao, Smeekens, Sjef, Teng, Sheng, Molecular Plant Physiology, Sub Molecular Plant Physiology, Molecular Plant Physiology, and Sub Molecular Plant Physiology

Subjects
0106 biological sciences, biology, Physiology, Chemistry, Cell, Mutant, Plant Science, biology.organism_classification, 01 natural sciences, Cell biology, Cell wall, medicine.anatomical_structure, Acetylation, Arabidopsis, Genetics, medicine, Arabidopsis thaliana, Secondary cell wall, Transcription factor, 010606 plant biology & botany
Abstract

O-Acetylation of polysaccharides predominantly modifies plant cell walls by changing the physicochemical properties and, consequently, the structure and function of the cell wall. Expression regulation and specific function of cell wall-acetylating enzymes remain to be fully understood. In this report, we cloned a previously identified stunted growth mutant named sucrose uncoupled1 (sun1) in Arabidopsis (Arabidopsis thaliana). SUN1 encodes a member of the TRICHOME BIREFRINGEN-LIKE family, AtTBL37. AtTBL37 is highly expressed in fast-growing plant tissues and encodes a Golgi apparatus-localized protein that regulates secondary cell wall thickening and acetylation. In sun1, jasmonate signaling and expression of downstream chemical defense genes, including VEGETATIVE STORAGE PROTEIN1 and BRANCHED-CHAIN AMINOTRANSFERASE4, are increased but, unexpectedly, sun1 is more susceptible to insect feeding. The central transcription factor in jasmonate signaling, MYC2, binds to and induces AtTBL37 expression. MYC2 also promotes the expression of many other TBLs. Moreover, MYC activity enhances cell wall acetylation. Overexpression of AtTBL37 in the myc2-2 background reduces herbivore feeding. Our study highlights the role of O-acetylation in controlling plant cell wall properties, plant development, and herbivore defense.

Published
2020

19. Fungal glycoside hydrolase family 44 xyloglucanases are restricted to the phylum Basidiomycota and show a distinct xyloglucan cleavage pattern

Author

Sun, Peicheng, Li, Xinxin, Dilokpimol, Adiphol, Henrissat, Bernard, de Vries, Ronald P, Kabel, Mirjam A, Mäkelä, Miia R, Sub Molecular Plant Physiology, Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, Helsinki Institute of Sustainability Science (HELSUS), Department of Microbiology, Fungal Genetics and Biotechnology, Sub Molecular Plant Physiology, and Molecular Plant Physiology

Subjects
EXPRESSION, 11832 Microbiology and virology, Multidisciplinary, PURIFICATION, Food Chemistry, Science, MASS-SPECTROMETRY, Mycology, PERFORMANCE, Article, SUBSTRATE-SPECIFICITY, CLONING, 1181 Ecology, evolutionary biology, Levensmiddelenchemie, NOMENCLATURE, Enzymology, GH12, Biomass, General, ENZYMES, VLAG
Abstract

Summary Xyloglucan is a prominent matrix heteropolysaccharide binding to cellulose microfibrils in primary plant cell walls. Hence, the hydrolysis of xyloglucan facilitates the overall lignocellulosic biomass degradation. Xyloglucanases (XEGs) are key enzymes classified in several glycoside hydrolase (GH) families. So far, family GH44 has been shown to contain bacterial XEGs only. Detailed genome analysis revealed GH44 members in fungal species from the phylum Basidiomycota, but not in other fungi, which we hypothesized to also be XEGs. Two GH44 enzymes from Dichomitus squalens and Pleurotus ostreatus were heterologously produced and characterized. They exhibited XEG activity and displayed a hydrolytic cleavage pattern different from that observed in fungal XEGs from other GH families. Specifically, the fungal GH44 XEGs were not hindered by substitution of neighboring glucosyl units and generated various “XXXG-type,” “GXXX(G)-type,” and “XXX-type” oligosaccharides. Overall, these fungal GH44 XEGs represent a novel class of enzymes for plant biomass conversion and valorization., Graphical abstract, Highlights • The fungal members of GH44 only belong to the phylum Basidiomycota • The characterized fungal GH44 xyloglucanases (XEGs) are xyloglucan-specific • These XEGs cleave xyloglucan at both sides of unsubstituted glucosyl units, Enzymology; Mycology; Biomass

Published
2022

20. 2D morphometric analysis of Arabidopsis thaliana nuclei reveals characteristic profiles of different cell types and accessions

Author

Pavlova, Penka, van Zanten, Martijn, Snoek, Basten L, de Jong, Hans, Fransz, Paul, Theoretical Biology and Bioinformatics, Sub Molecular Plant Physiology, Sub Bioinformatics, Molecular Plant Physiology, Theoretical Biology and Bioinformatics, Sub Molecular Plant Physiology, Sub Bioinformatics, and Molecular Plant Physiology

Subjects
Cell Nucleus, Cell type, Chromocenter, biology, Euchromatin, Heterochromatin, Differential staining, Arabidopsis, Correction, food and beverages, biology.organism_classification, Laboratorium voor Erfelijkheidsleer, Chromatin, Cell biology, Nuclear phenotype, Genetics, Arabidopsis thaliana, Laboratory of Genetics, EPS, Quantitative analysis, Gene
Abstract

Functional changes of cells upon developmental switches and in response to environmental cues are often reflected in nuclear phenotypes, showing distinctive chromatin states corresponding to transcriptional changes. Such characteristic nuclear shapes have been microscopically monitored and can be quantified after differential staining of euchromatin and heterochromatin domains. Here, we examined several nuclear parameters (size, DNA content, DNA density, chromatin compaction, relative heterochromatin fraction (RHF), and number of chromocenters) in relation to spatial distribution of genes and transposon elements (TEs), using standard 2D fluorescence microscopy. We provide nuclear profiles for different cell types and different accessions of Arabidopsis thaliana. A variable, yet significant, fraction of TEs was found outside chromocenters in all cell types, except for guard cells. The latter cell type features nuclei with the highest level of chromatin compaction, while their chromocenters seem to contain gene-rich regions. The highest number of parameter correlations was found in the accession Cvi, whereas Ler showed only few correlations. This may point at differences in phenotype robustness between accessions. The significantly high association of NOR chromocenters in accessions Ws and Cvi corresponds to their low RHF level.

Published
2022

21. Fungal xylanolytic enzymes: Diversity and applications

Author

Li, Xinxin, Dilokpimol, Adiphol, Kabel, Mirjam A., de Vries, Ronald P., Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, and Molecular Plant Physiology

Subjects
Environmental Engineering, Substrate specificity, Biomass, Bioengineering, Biology, Polysaccharide, Xylanolytic enzymes, Fungal Proteins, Genome mining, Levensmiddelenchemie, Renewable Energy, SDG 7 - Affordable and Clean Energy, Waste Management and Disposal, chemistry.chemical_classification, Endo-1,4-beta Xylanases, Genome comparison, Sustainability and the Environment, Food Chemistry, business.industry, Renewable Energy, Sustainability and the Environment, Fungi, food and beverages, General Medicine, Biotechnology, Xylosidases, Enzyme, chemistry, Biofuel, Industrial application, Xylans, Genome, Fungal, business
Abstract

As important polysaccharide degraders in nature, fungi can diversify their extensive set of carbohydrate-active enzymes to survive in ecological habitats of various composition. Among these enzymes, xylanolytic ones can efficiently and sustainably degrade xylans into (fermentable) monosaccharides to produce valuable chemicals or fuels from, for example relevant for upgrading agro-food industrial side streams. Moreover, xylanolytic enzymes are being used in various industrial applications beyond biomass saccharification, e.g. food, animal feed, biofuel, pulp and paper. As a reference for researchers working in related areas, this review summarized the current knowledge on substrate specificity of xylanolytic enzymes from different families of the Carbohydrate-Active enZyme database. Additionally, the diversity of enzyme sets in fungi were discussed by comparing the number of genes encoding xylanolytic enzymes in selected fungal genomes. Finally, to support bio-economy, the current applications of fungal xylanolytic enzymes in industry were reviewed.

Published
2022

22. Effects of sub-lethal single, simultaneous, and sequential abiotic stresses on phenotypic traits of Arabidopsis thaliana

Author

Morales, Alejandro, De Boer, Hugo J., Douma, Jacob C., Elsen, Saskia, Engels, Sophie, Glimmerveen, Tobias, Sajeev, Nikita, Huber, Martina, Luimes, Mathijs, Luitjens, Emma, Raatjes, Kevin, Hsieh, Chenyun, Teapal, Juliane, Wildenbeest, Tessa, Jiang, Zhang, Pareek, Ashwani, Singla-Pareek, Sneh, Yin, Xinyou, Evers, Jochem, Anten, Niels P.R., Van Zanten, Martijn, Sasidharan, Rashmi, Molecular Plant Physiology, Environmental Sciences, Sub Plant Ecophysiology, Global Ecohydrology and Sustainability, Sub Molecular Plant Physiology, Sub Developmental Biology, Plant Ecophysiology, Developmental Biology, Molecular Plant Physiology, Environmental Sciences, Sub Plant Ecophysiology, Global Ecohydrology and Sustainability, Sub Molecular Plant Physiology, Sub Developmental Biology, Plant Ecophysiology, and Developmental Biology

Subjects
Crop Physiology, Arabidopsis thaliana, simultaneous stresses, food and beverages, drought, Plant Science, acclimation, PE&RC, Abiotic stress, thermomorphogenesis, high temperature, flooding, sequential stresses, Centre for Crop Systems Analysis, Laboratorium voor Plantenfysiologie, EPS, Crop and Weed Ecology, Laboratory of Plant Physiology
Abstract

Plant responses to abiotic stresses are complex and dynamic, and involve changes in different traits, either as the direct consequence of the stress, or as an active acclimatory response. Abiotic stresses frequently occur simultaneously or in succession, rather than in isolation. Despite this, most studies have focused on a single stress and single or few plant traits. To address this gap, our study comprehensively and categorically quantified the individual and combined effects of three major abiotic stresses associated with climate change (flooding, progressive drought and high temperature) on 12 phenotypic traits related to morphology, development, growth and fitness, at different developmental stages in four Arabidopsis thaliana accessions. Combined sublethal stresses were applied either simultaneously (high temperature and drought) or sequentially (flooding followed by drought). In total, we analysed the phenotypic responses of 1782 individuals across these stresses and different developmental stages. Overall, abiotic stresses and their combinations resulted in distinct patterns of effects across the traits analysed, with both quantitative and qualitative differences across accessions. Stress combinations had additive effects on some traits, whereas clear positive and negative interactions were observed for other traits: 9 out of 12 traits for high temperature and drought, 6 out of 12 traits for post-submergence and drought showed significant interactions. In many cases where the stresses interacted, the strength of interactions varied across accessions. Hence, our results indicated a general pattern of response in most phenotypic traits to the different stresses and stress combinations, but it also indicated a natural genetic variation in the strength of these responses. This includes novel results regarding the lack of a response to drought after submergence and a decoupling between leaf number and flowering time after submergence. Overall, our study provides a rich characterization of trait responses of Arabidopsis plants to sublethal abiotic stresses at the phenotypic level and can serve as starting point for further in-depth physiological research and plant modelling efforts.

Published
2021

23. CreA-mediated repression of gene expression occurs at low monosaccharide levels during fungal plant biomass conversion in a time and substrate dependent manner

Author

Peng, Mao, Khosravi, Claire, Lubbers, Ronnie J M, Kun, Roland S, Aguilar Pontes, Maria Victoria, Battaglia, Evy, Chen, Cindy, Dalhuijsen, Sacha, Daly, Paul, Lipzen, Anna, Ng, Vivian, Yan, Juying, Wang, Mei, Visser, Jaap, Grigoriev, Igor V, Mäkelä, Miia R, de Vries, Ronald P, Molecular Plant Physiology, Sub Molecular Microbiology, Sub Molecular Plant Physiology, Molecular Microbiology, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, Westerdijk Fungal Biodiversity Institute, Department of Microbiology, University of Helsinki, Department of Food and Nutrition, Helsinki Institute of Sustainability Science (HELSUS), Fungal Genetics and Biotechnology, Molecular Plant Physiology, Sub Molecular Microbiology, Sub Molecular Plant Physiology, and Molecular Microbiology

Subjects
Catabolite repression, Biomass, Polysaccharide, Applied Microbiology and Biotechnology, Microbiology, Article, Cell wall, 03 medical and health sciences, Affordable and Clean Energy, Fungal plant biomass conversion, Monosaccharide, Sugar, Molecular Biology, 030304 developmental biology, 11832 Microbiology and virology, 2. Zero hunger, chemistry.chemical_classification, 0303 health sciences, QH573-671, biology, 030306 microbiology, Aspergillus niger, fungi, 1184 Genetics, developmental biology, physiology, food and beverages, Cell Biology, Carbon catabolite repression, 15. Life on land, biology.organism_classification, Biochemistry, chemistry, creA, Sugar beet, Transcription factor, Cytology
Abstract

Funding Information: The work conducted by the U.S. Department of Energy Joint Genome Institute, a DOE Office of Science User Facility, was supported by the Office of Science of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231 . CK, EB was supported by a grant of the Applied and Engineering Sciences division of NWO , and the Technology Program of the Ministry of Economic Affairs 016.130.609 to RPdV. PD was supported by a grant of the Netherlands Scientific Organization NWO 824.15.023 to RPdV. The Academy of Finland grant no. 308284 to MRM is acknowledged. Publisher Copyright: © 2021 The Author(s) Carbon catabolite repression enables fungi to utilize the most favourable carbon source in the environment, and is mediated by a key regulator, CreA, in most fungi. CreA-mediated regulation has mainly been studied at high monosaccharide concentrations, an uncommon situation in most natural biotopes. In nature, many fungi rely on plant biomass as their major carbon source by producing enzymes to degrade plant cell wall polysaccharides into metabolizable sugars. To determine the role of CreA when fungi grow in more natural conditions and in particular with respect to degradation and conversion of plant cell walls, we compared transcriptomes of a creA deletion and reference strain of the ascomycete Aspergillus niger during growth on sugar beet pulp and wheat bran. Transcriptomics, extracellular sugar concentrations and growth profiling of A. niger on a variety of carbon sources, revealed that also under conditions with low concentrations of free monosaccharides, CreA has a major effect on gene expression in a strong time and substrate composition dependent manner. In addition, we compared the CreA regulon from five fungi during their growth on crude plant biomass or cellulose. It showed that CreA commonly regulated genes related to carbon metabolism, sugar transport and plant cell wall degrading enzymes across different species. We therefore conclude that CreA has a crucial role for fungi also in adapting to low sugar concentrations as occurring in their natural biotopes, which is supported by the presence of CreA orthologs in nearly all fungi.

Published
2021

24. The Cultivation Method Affects the Transcriptomic Response of Aspergillus niger to Growth on Sugar Beet Pulp

Author

Garrigues, Sandra, Kun, Roland S., Peng, Mao, S.Gruben, Birgit, Gelber, Isabelle Benoit, Mäkelä, Miia, P.deVries, Ronald, Molecular Plant Physiology, Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, Department of Microbiology, and Helsinki Institute of Sustainability Science (HELSUS)

Subjects
Pectin, Physiology, Biomass, PATHWAY, Gene Expression Regulation, Fungal, sugar beet pulp, Food science, Mycelium, 11832 Microbiology and virology, 0303 health sciences, biology, Ecology, QR1-502, Infectious Diseases, Pectins, Sugar beet, Aspergillus niger, Beta vulgaris, Research Article, EXPRESSION, Microbiology (medical), food.ingredient, CAZy, GENES, Fungus, submerged culture, Microbiology, D-GALACTOSE, Fungal Proteins, 03 medical and health sciences, food, D-GALACTURONIC ACID, Immunology and Microbiology(all), Genetics, Sugar, 030304 developmental biology, RELEASE, General Immunology and Microbiology, 030306 microbiology, solid culture, fungi, FUNGI, Cell Biology, 15. Life on land, DEGRADATION, biology.organism_classification, Culture Media, SOLID-STATE, gene expression, Transcriptome
Abstract

In nature, filamentous fungi are exposed to diverse nutritional sources and changes in substrate availability. Conversely, in submerged cultures, mycelia are continuously exposed to the existing substrates, which are depleted over time. Submerged cultures are the preferred choice for experimental setups in laboratory and industry and are often used for understanding the physiology of fungi. However, to what extent the cultivation method affects fungal physiology, with respect to utilization of natural substrates, has not been addressed in detail. Here, we compared the transcriptomic responses of Aspergillus niger grown in submerged culture and solid culture, both containing sugar beet pulp (SBP) as a carbon source. The results showed that expression of CAZy (Carbohydrate Active enZyme)-encoding and sugar catabolic genes in liquid SBP was time dependent. Moreover, additional components of SBP delayed the A. niger response to the degradation of pectin present in SBP. In addition, we demonstrated that liquid cultures induced wider transcriptome variability than solid cultures. Although there was a correlation regarding sugar metabolic gene expression patterns between liquid and solid cultures, it decreased in the case of CAZyme-encoding genes. In conclusion, the transcriptomic response of A. niger to SBP is influenced by the culturing method, limiting the value of liquid cultures for understanding the behavior of fungi in natural habitats. IMPORTANCE Understanding the interaction between filamentous fungi and their natural and biotechnological environments has been of great interest for the scientific community. Submerged cultures are preferred over solid cultures at a laboratory scale to study the natural response of fungi to different stimuli found in nature (e.g., carbon/nitrogen sources, pH). However, whether and to what extent submerged cultures introduce variation in the physiology of fungi during growth on plant biomass have not been studied in detail. In this study, we compared the transcriptomic responses of Aspergillus niger to growth on liquid and solid cultures containing sugar beet pulp (a by-product of the sugar industry) as a carbon source. We demonstrate that the transcriptomic response of A. niger was highly affected by the culture condition, since the transcriptomic response obtained in a liquid environment could not fully explain the behavior of the fungus in a solid environment. This could partially explain the differences often observed between the phenotypes on plates compared to liquid cultures.

Published
2021

25. Vanillic acid and methoxyhydroquinone production from guaiacyl units and related aromatic compounds using Aspergillus niger cell factories

Author

Lubbers, Ronnie J.M., Dilokpimol, Adiphol, Nousiainen, Paula A., Cioc, Răzvan C., Visser, Jaap, Bruijnincx, Pieter C.A., de Vries, Ronald P., Sub Organic Chemistry and Catalysis, Sub Molecular Plant Physiology, Organic Chemistry and Catalysis, Molecular Plant Physiology, Department of Chemistry, Sub Organic Chemistry and Catalysis, Sub Molecular Plant Physiology, Organic Chemistry and Catalysis, and Molecular Plant Physiology

Subjects
GENE-CLUSTER, 116 Chemical sciences, Lignin, Applied Microbiology and Biotechnology, Mixed Function Oxygenases, Ferulic acid, chemistry.chemical_compound, MOLECULAR CHARACTERIZATION, chemistry.chemical_classification, BIOCONVERSION, 0303 health sciences, biology, 4-Hydroxy-6-methoxy-6-oxohexa-2,4-dienoic acid, Coniferyl alcohol, QR1-502, CATABOLISM, Biochemistry, Vanillin dehydrogenase, 4-Hydroxy-6-methoxy-6-oxohexa-2, Benzaldehydes, Vanillin, Aspergillus niger, Metabolic Networks and Pathways, Biotechnology, Bioengineering, METABOLISM, 4-Oxo-monomethyl adipate, Microbiology, 4-dienoic acid, 03 medical and health sciences, Vanillic acid, 030304 developmental biology, Vanillic Acid, IDENTIFICATION, 030306 microbiology, Research, Veratic acid, DEGRADATION, PERFORMANCE, biology.organism_classification, Fungal cell factory, Hydroquinones, HYDROXYLASE, Metabolic pathway, Enzyme, chemistry
Abstract

Background The aromatic compounds vanillin and vanillic acid are important fragrances used in the food, beverage, cosmetic and pharmaceutical industries. Currently, most aromatic compounds used in products are chemically synthesized, while only a small percentage is extracted from natural sources. The metabolism of vanillin and vanillic acid has been studied for decades in microorganisms and many studies have been conducted that showed that both can be produced from ferulic acid using bacteria. In contrast, the degradation of vanillin and vanillic acid by fungi is poorly studied and no genes involved in this metabolic pathway have been identified. In this study, we aimed to clarify this metabolic pathway in Aspergillus niger and identify the genes involved. Results Using whole-genome transcriptome data, four genes involved in vanillin and vanillic acid metabolism were identified. These include vanillin dehydrogenase (vdhA), vanillic acid hydroxylase (vhyA), and two genes encoding novel enzymes, which function as methoxyhydroquinone 1,2-dioxygenase (mhdA) and 4-oxo-monomethyl adipate esterase (omeA). Deletion of these genes in A. niger confirmed their role in aromatic metabolism and the enzymatic activities of these enzymes were verified. In addition, we demonstrated that mhdA and vhyA deletion mutants can be used as fungal cell factories for the accumulation of vanillic acid and methoxyhydroquinone from guaiacyl lignin units and related aromatic compounds. Conclusions This study provides new insights into the fungal aromatic metabolic pathways involved in the degradation of guaiacyl units and related aromatic compounds. The identification of the involved genes unlocks new potential for engineering aromatic compound-producing fungal cell factories.

Published
2021

26. Far-Red Light-Induced Azolla filiculoides Symbiosis Sexual Reproduction: Responsive Transcripts of Symbiont Nostoc azollae Encode Transporters Whilst Those of the Fern Relate to the Angiosperm Floral Transition

Author

Dijkhuizen, Laura W., Tabatabaei, Badraldin Ebrahim Sayed, Brouwer, Paul, Rijken, Niels, Buijs, Valerie A., Güngör, Erbil, Schluepmann, Henriette, Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, and Molecular Plant Physiology

Subjects
Gametophyte, Nostoc, sexual reproduction, microRNA, dual RNA-sequencing, Lineage (evolution), Plant culture, Plant Science, Biology, biology.organism_classification, Azolla, Azolla filiculoides, Sexual reproduction, SB1-1110, MIKC and GAMYB transcription factors, Symbiosis, Botany, Fern
Abstract

Water ferns of the genus Azolla and the filamentous cyanobacteria Nostoc azollae constitute a model symbiosis that enabled the colonization of the water surface with traits highly desirable for the development of more sustainable crops: their floating mats capture CO2 and fix N2 at high rates using light energy. Their mode of sexual reproduction is heterosporous. The regulation of the transition from the vegetative phase to the spore forming phase in ferns is largely unknown, yet a prerequisite for Azolla domestication, and of particular interest as ferns represent the sister lineage of seed plants. Sporocarps induced with far red light could be crossed so as to verify species attribution of strains from the Netherlands but not of the strain from the Anzali lagoon in Iran; the latter strain was assigned to a novel species cluster from South America. Red-dominated light suppresses the formation of dissemination stages in both gametophyte- and sporophyte-dominated lineages of plants, the response likely is a convergent ecological strategy to open fields. FR-responsive transcripts included those from MIKCC homologues of CMADS1 and miR319-controlled GAMYB transcription factors in the fern, transporters in N. azollae, and ycf2 in chloroplasts. Loci of conserved microRNA (miRNA) in the fern lineage included miR172, yet FR only induced miR529 and miR535, and reduced miR319 and miR159. Phylogenomic analyses of MIKCC TFs suggested that the control of flowering and flower organ specification may have originated from the diploid to haploid phase transition in the homosporous common ancestor of ferns and seed plants.

Published
2021

27. The chimeric GaaR-XlnR transcription factor induces pectinolytic activities in the presence of D-xylose in Aspergillus niger

Author

Kun, Roland S., Garrigues, Sandra, Di Falco, Marcos, Tsang, Adrian, de Vries, Ronald P., Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, and Westerdijk Fungal Biodiversity Institute

Subjects
0106 biological sciences, Aspergillus niger/genetics, Mutant, Transcription Factors/genetics, 01 natural sciences, Applied Microbiology and Biotechnology, Fungal Proteins, 03 medical and health sciences, D-xylose, 010608 biotechnology, Gene Expression Regulation, Fungal, CRISPR, Inducer, Transcription factor, Gene, CRISPR/Cas9, 030304 developmental biology, Applied Genetics and Molecular Biotechnology, chemistry.chemical_classification, 0303 health sciences, Xylose, biology, Cas9, Aspergillus niger, General Medicine, Pectinases, biology.organism_classification, Chimeric transcription factor, Fungal Proteins/genetics, Enzyme, Fungal, Biochemistry, chemistry, Gene Expression Regulation, Transcription Factors, Biotechnology
Abstract

Abstract Aspergillus niger is a filamentous fungus well known for its ability to produce a wide variety of pectinolytic enzymes, which have many applications in the industry. The transcriptional activator GaaR is induced by 2-keto-3-deoxy-L-galactonate, a compound derived from D-galacturonic acid, and plays a major role in the regulation of pectinolytic genes. The requirement for inducer molecules can be a limiting factor for the production of enzymes. Therefore, the generation of chimeric transcription factors able to activate the expression of pectinolytic genes by using underutilized agricultural residues would be highly valuable for industrial applications. In this study, we used the CRISPR/Cas9 system to generate three chimeric GaaR-XlnR transcription factors expressed by the xlnR promoter by swapping the N-terminal region of the xylanolytic regulator XlnR to that of the GaaR in A. niger. As a test case, we constructed a PpgaX-hph reporter strain to evaluate the alteration of transcription factor specificity in the chimeric mutants. Our results showed that the chimeric GaaR-XlnR transcription factor was induced in the presence of D-xylose. Additionally, we generated a constitutively active GaaR-XlnR V756F version of the most efficient chimeric transcription factor to better assess its activity. Proteomics analysis confirmed the production of several pectinolytic enzymes by ΔgaaR mutants carrying the chimeric transcription factor. This correlates with the improved release of D-galacturonic acid from pectin by the GaaR-XlnR V756F mutant, as well as by the increased L-arabinose release from the pectin side chains by both chimeric mutants under inducing condition, which is required for efficient degradation of pectin. Key points • Chimeric transcription factors were generated by on-site mutations using CRISPR/Cas9. • PpgaX-hph reporter strain allowed for the screening of functional GaaR-XlnR mutants. • Chimeric GaaR-XlnR induced pectinolytic activities in the presence of D-xylose.

Published
2021

28. Correction to: 2D morphometric analysis of Arabidopsis thaliana nuclei reveals characteristic profiles of different cell types and accessions (Chromosome Research, (2022), 30, 1, (5-24), 10.1007/s10577-021-09673-2)

Author

Sub Molecular Plant Physiology, Sub Bioinformatics, Molecular Plant Physiology, Theoretical Biology and Bioinformatics, Pavlova, Penka, van Zanten, Martijn, Snoek, Basten L, de Jong, Hans, Fransz, Paul, Sub Molecular Plant Physiology, Sub Bioinformatics, Molecular Plant Physiology, Theoretical Biology and Bioinformatics, Pavlova, Penka, van Zanten, Martijn, Snoek, Basten L, de Jong, Hans, and Fransz, Paul

Published
2022

29. Fungal xylanolytic enzymes: Diversity and applications

Author

Sub Molecular Plant Physiology, Molecular Plant Physiology, Li, Xinxin, Dilokpimol, Adiphol, Kabel, Mirjam A., de Vries, Ronald P., Sub Molecular Plant Physiology, Molecular Plant Physiology, Li, Xinxin, Dilokpimol, Adiphol, Kabel, Mirjam A., and de Vries, Ronald P.

Published
2022

30. Fungal glycoside hydrolase family 44 xyloglucanases are restricted to the phylum Basidiomycota and show a distinct xyloglucan cleavage pattern

Author

Sub Molecular Plant Physiology, Molecular Plant Physiology, Sun, Peicheng, Li, Xinxin, Dilokpimol, Adiphol, Henrissat, Bernard, de Vries, Ronald P, Kabel, Mirjam A, Mäkelä, Miia R, Sub Molecular Plant Physiology, Molecular Plant Physiology, Sun, Peicheng, Li, Xinxin, Dilokpimol, Adiphol, Henrissat, Bernard, de Vries, Ronald P, Kabel, Mirjam A, and Mäkelä, Miia R

Published
2022

31. 2D morphometric analysis of Arabidopsis thaliana nuclei reveals characteristic profiles of different cell types and accessions

Author

Theoretical Biology and Bioinformatics, Sub Molecular Plant Physiology, Sub Bioinformatics, Molecular Plant Physiology, Pavlova, Penka, van Zanten, Martijn, Snoek, Basten L, de Jong, Hans, Fransz, Paul, Theoretical Biology and Bioinformatics, Sub Molecular Plant Physiology, Sub Bioinformatics, Molecular Plant Physiology, Pavlova, Penka, van Zanten, Martijn, Snoek, Basten L, de Jong, Hans, and Fransz, Paul

Published
2022

33. Genetic diversity reveals synergistic interaction between yield components could improve the sink size and yield in rice

Author

Molecular Plant Physiology, Plant-Environment Signaling, Sub Molecular Plant Physiology, Sub Plant-Environment Signaling, Anwar, Khalid, Joshi, Rohit, Morales, Alejandro, Das, Gourab, Yin, Xinyou, Anten, Niels P.R., Raghuvanshi, Saurabh, Bahuguna, Rajeev N., Singh, Madan Pal, Singh, Rakesh K., van Zanten, Martijn, Sasidharan, Rashmi, Singla-Pareek, Sneh L., Pareek, Ashwani, Molecular Plant Physiology, Plant-Environment Signaling, Sub Molecular Plant Physiology, Sub Plant-Environment Signaling, Anwar, Khalid, Joshi, Rohit, Morales, Alejandro, Das, Gourab, Yin, Xinyou, Anten, Niels P.R., Raghuvanshi, Saurabh, Bahuguna, Rajeev N., Singh, Madan Pal, Singh, Rakesh K., van Zanten, Martijn, Sasidharan, Rashmi, Singla-Pareek, Sneh L., and Pareek, Ashwani

Published
2022

36. Unraveling the regulation of sugar beet pulp utilization in the industrially relevant fungus Aspergillus niger

Author

Molecular Plant Physiology, Sub Molecular Plant Physiology, Garrigues, Sandra, Kun, Roland S., Peng, Mao, Bauer, Diane, Keymanesh, Keykhosrow, Lipzen, Anna, Ng, Vivian, Grigoriev, Igor V., de Vries, Ronald P., Molecular Plant Physiology, Sub Molecular Plant Physiology, Garrigues, Sandra, Kun, Roland S., Peng, Mao, Bauer, Diane, Keymanesh, Keykhosrow, Lipzen, Anna, Ng, Vivian, Grigoriev, Igor V., and de Vries, Ronald P.

Published
2022

37. Potential Fungi Isolated From Anti-biodegradable Chinese Medicine Residue to Degrade Lignocellulose

Author

Molecular Plant Physiology, Sub Molecular Plant Physiology, Cheng, Min, Wijayawardene, Nalin N., Promputtha, Itthayakorn, de Vries, Ronald P., Lan, Yongzhe, Luo, Gang, Wang, Meizhu, Li, Qirui, Guo, Xinyao, Wang, Feng, Liu, Yanxia, Kang, Yingqian, Molecular Plant Physiology, Sub Molecular Plant Physiology, Cheng, Min, Wijayawardene, Nalin N., Promputtha, Itthayakorn, de Vries, Ronald P., Lan, Yongzhe, Luo, Gang, Wang, Meizhu, Li, Qirui, Guo, Xinyao, Wang, Feng, Liu, Yanxia, and Kang, Yingqian

Published
2022

38. GalR, GalX and AraR co-regulate d-galactose and l-arabinose utilization in Aspergillus nidulans

Author

Molecular Plant Physiology, Sub Molecular Plant Physiology, Meng, Jiali, Németh, Zoltán, Peng, Mao, Fekete, Erzsébet, Garrigues, Sandra, Lipzen, Anna, Ng, Vivian, Savage, Emily, Zhang, Yu, Grigoriev, Igor V., Mäkelä, Miia R., Karaffa, Levente, de Vries, Ronald P., Molecular Plant Physiology, Sub Molecular Plant Physiology, Meng, Jiali, Németh, Zoltán, Peng, Mao, Fekete, Erzsébet, Garrigues, Sandra, Lipzen, Anna, Ng, Vivian, Savage, Emily, Zhang, Yu, Grigoriev, Igor V., Mäkelä, Miia R., Karaffa, Levente, and de Vries, Ronald P.

Published
2022

39. Detailed analysis of the D-galactose catabolic pathways in Aspergillus niger reveals complexity at both metabolic and regulatory level

Author

Molecular Plant Physiology, Sub Molecular Plant Physiology, Chroumpi, Tania, Martínez-Reyes, Natalia, Kun, Roland S., Peng, Mao, Lipzen, Anna, Ng, Vivian, Tejomurthula, Sravanthi, Zhang, Yu, Grigoriev, Igor V., Mäkelä, Miia R., de Vries, Ronald P., Garrigues, Sandra, Molecular Plant Physiology, Sub Molecular Plant Physiology, Chroumpi, Tania, Martínez-Reyes, Natalia, Kun, Roland S., Peng, Mao, Lipzen, Anna, Ng, Vivian, Tejomurthula, Sravanthi, Zhang, Yu, Grigoriev, Igor V., Mäkelä, Miia R., de Vries, Ronald P., and Garrigues, Sandra

Published
2022

40. Effects of sublethal single, simultaneous and sequential abiotic stresses on phenotypic traits of Arabidopsis thaliana

Author

Molecular Plant Physiology, Environmental Sciences, Sub Plant Ecophysiology, Global Ecohydrology and Sustainability, Sub Molecular Plant Physiology, Sub Developmental Biology, Plant Ecophysiology, Developmental Biology, Morales, Alejandro, De Boer, Hugo J., Douma, Jacob C., Elsen, Saskia, Engels, Sophie, Glimmerveen, Tobias, Sajeev, Nikita, Huber, Martina, Luimes, Mathijs, Luitjens, Emma, Raatjes, Kevin, Hsieh, Chenyun, Teapal, Juliane, Wildenbeest, Tessa, Jiang, Zhang, Pareek, Ashwani, Singla-Pareek, Sneh, Yin, Xinyou, Evers, Jochem, Anten, Niels P.R., Van Zanten, Martijn, Sasidharan, Rashmi, Molecular Plant Physiology, Environmental Sciences, Sub Plant Ecophysiology, Global Ecohydrology and Sustainability, Sub Molecular Plant Physiology, Sub Developmental Biology, Plant Ecophysiology, Developmental Biology, Morales, Alejandro, De Boer, Hugo J., Douma, Jacob C., Elsen, Saskia, Engels, Sophie, Glimmerveen, Tobias, Sajeev, Nikita, Huber, Martina, Luimes, Mathijs, Luitjens, Emma, Raatjes, Kevin, Hsieh, Chenyun, Teapal, Juliane, Wildenbeest, Tessa, Jiang, Zhang, Pareek, Ashwani, Singla-Pareek, Sneh, Yin, Xinyou, Evers, Jochem, Anten, Niels P.R., Van Zanten, Martijn, and Sasidharan, Rashmi

Published
2022

43. Correction to: 2D morphometric analysis of Arabidopsis thaliana nuclei reveals characteristic profiles of different cell types and accessions (Chromosome Research, (2022), 30, 1, (5-24), 10.1007/s10577-021-09673-2)

Author

Pavlova, Penka, van Zanten, Martijn, Snoek, Basten L, de Jong, Hans, Fransz, Paul, Sub Molecular Plant Physiology, Sub Bioinformatics, Molecular Plant Physiology, and Theoretical Biology and Bioinformatics

Subjects
Taverne
Abstract

The original version of this article unfortunately contained a mistake. The Tables 1 and 2 were published erroneously. The corrected Tables 1 and 2 were shown in the next page. The publisher sincerely apologizes for this error and any inconvenience caused to the authors and readers of the journal. The original article has been corrected.

Published
2022

44. Plant thermotropism: an underexplored thermal engagement and avoidance strategy

Author

Zanten, Martijn van, Ai, Haiyue, Quint, Marcel, Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, and Molecular Plant Physiology

Subjects
0106 biological sciences, 0301 basic medicine, Cognitive science, Nastic movements, Plant growth, Functional ecology, Physiology, nastic movements, Plant Science, Biology, Hyponasty, Thermotropism, tropic movements, 01 natural sciences, thermotropism, 03 medical and health sciences, 030104 developmental biology, thermonasty, 010606 plant biology & botany
Abstract

Various strategies evolved in plants to adjust the position of organs relative to the prevailing temperature condition, which allows optimal plant growth and performance. Such responses are classically separated into nastic and tropic responses. During plant thermotropic responses, organs move towards (engage) or away from (avoid) a directional temperature cue. Despite thermotropism being a classic botanical concept, the underlying ecological function and molecular and biophysical mechanisms remain poorly understood to this day. This is in contrast to the relatively well-studied thermonastic movements (hyponasty) of, for example, rosette leaves. In this review, we provide an update on the current knowledge on plant thermotropisms and propose directions for future research and application.

Published
2021

45. Aspergillus niger uses the peroxisomal CoA-dependent β-oxidative genes to degrade the hydroxycinnamic acids caffeic acid, ferulic acid, and p-coumaric acid

Author

Lubbers, R. J.M., Dilokpimol, A., Visser, J., de Vries, R. P., Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, and Westerdijk Fungal Biodiversity Institute

Subjects
Aromatic compounds, Coumaric Acids, Aspergillus niger/genetics, Hydroxycinnamic acids, Peroxisome, 7. Clean energy, Applied Microbiology and Biotechnology, p-Coumaric acid, Ferulic acid, 03 medical and health sciences, chemistry.chemical_compound, Caffeic Acids, Caffeic acid, Coenzyme A, SDG 7 - Affordable and Clean Energy, Fatty acids, Applied Genetics and Molecular Biotechnology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, Fatty acid metabolism, 030306 microbiology, fungi, Fatty Acids, Aspergillus niger, Beta-oxidation, General Medicine, biology.organism_classification, Hydroxycinnamic acid, Oxidative Stress, Metabolic pathway, chemistry, Biochemistry, Biotechnology
Abstract

Abstract Aromatic compounds are important molecules which are widely applied in many industries and are mainly produced from nonrenewable sources. Renewable sources such as plant biomass are interesting alternatives for the production of aromatic compounds. Ferulic acid and p-coumaric acid, a precursor for vanillin and p-vinyl phenol, respectively, can be released from plant biomass by the fungus Aspergillus niger. The degradation of hydroxycinnamic acids such as caffeic acid, ferulic acid, and p-coumaric acid has been observed in many fungi. In A. niger, multiple metabolic pathways were suggested for the degradation of hydroxycinnamic acids. However, no genes were identified for these hydroxycinnamic acid metabolic pathways. In this study, several pathway genes were identified using whole-genome transcriptomic data of A. niger grown on different hydroxycinnamic acids. The genes are involved in the CoA-dependent β-oxidative pathway in fungi. This pathway is well known for the degradation of fatty acids, but not for hydroxycinnamic acids. However, in plants, it has been shown that hydroxycinnamic acids are degraded through this pathway. We identified genes encoding hydroxycinnamate-CoA synthase (hcsA), multifunctional β-oxidation hydratase/dehydrogenase (foxA), 3-ketoacyl CoA thiolase (katA), and four thioesterases (theA-D) of A. niger, which were highly induced by all three tested hydroxycinnamic acids. Deletion mutants revealed that these genes were indeed involved in the degradation of several hydroxycinnamic acids. In addition, foxA and theB are also involved in the degradation of fatty acids. HcsA, FoxA, and KatA contained a peroxisomal targeting signal and are therefore predicted to be localized in peroxisomes. Key points • Metabolism of hydroxycinnamic acid was investigated in Aspergillus niger • Using transcriptome data, multiple CoA-dependent β-oxidative genes were identified. • Both foxA and theB are involved in hydroxycinnamate but also fatty acid metabolism.

Published
2021

46. Revisiting a 'simple' fungal metabolic pathway reveals redundancy, complexity and diversity

Author

Chroumpi, Tania, Peng, Mao, Aguilar-Pontes, Maria Victoria, Müller, Astrid, Wang, Mei, Yan, Juying, Lipzen, Anna, Ng, Vivian, Grigoriev, Igor V, Mäkelä, Miia R, de Vries, Ronald P, Molecular Plant Physiology, Sub Molecular Plant Physiology, Helsinki Institute of Sustainability Science (HELSUS), Department of Microbiology, Fungal Genetics and Biotechnology, Molecular Plant Physiology, Sub Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, and Westerdijk Fungal Biodiversity Institute

Subjects
Pentoses, Pentose, Bioengineering, Applied Microbiology and Biotechnology, Biochemistry, Microbiology, Cell wall, Metabolic engineering, 03 medical and health sciences, Gene, Research Articles, 030304 developmental biology, 11832 Microbiology and virology, chemistry.chemical_classification, 0303 health sciences, Xylose, biology, 030306 microbiology, Catabolism, Aspergillus niger, biology.organism_classification, Arabinose, Metabolic pathway, Enzyme, chemistry, Metabolic Networks and Pathways, TP248.13-248.65, Research Article, Biotechnology
Abstract

Summary Next to d‐glucose, the pentoses l‐arabinose and d‐xylose are the main monosaccharide components of plant cell wall polysaccharides and are therefore of major importance in biotechnological applications that use plant biomass as a substrate. Pentose catabolism is one of the best‐studied pathways of primary metabolism of Aspergillus niger, and an initial outline of this pathway with individual enzymes covering each step of the pathway has been previously established. However, although growth on l‐arabinose and/or d‐xylose of most pentose catabolic pathway (PCP) single deletion mutants of A. niger has been shown to be negatively affected, it was not abolished, suggesting the involvement of additional enzymes. Detailed analysis of the single deletion mutants of the known A. niger PCP genes led to the identification of additional genes involved in the pathway. These results reveal a high level of complexity and redundancy in this pathway, emphasizing the need for a comprehensive understanding of metabolic pathways before entering metabolic engineering of such pathways for the generation of more efficient fungal cell factories., A detailed investigation of the fungal pentose catabolic pathway revealed that additional enzymes are involved in nearly all steps of the pathways. This stresses the importance of a good understanding of the genes and enzymes involved in metabolic pathways to be able to successfully perform metabolic engineering for the construction of cell factories.

Published
2021

47. Characterization of d-xylose reductase, XyrB, from Aspergillus niger

Author

Terebieniec, Agata, Chroumpi, Tania, Dilokpimol, Adiphol, Aguilar-Pontes, Maria Victoria, Mäkelä, Miia R., de Vries, Ronald P., Sub Molecular Plant Physiology, Molecular Plant Physiology, Department of Microbiology, Helsinki Institute of Sustainability Science (HELSUS), Sub Molecular Plant Physiology, Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, and Westerdijk Fungal Biodiversity Institute

Subjects
0106 biological sciences, CtXR, Candida tenuis xylose reductase, NADP, nicotinamide adenine dinucleotide phosphate, IPTG, isopropyl β-D-1-thiogalactopyranoside, GCY1/YPR1, yeast glycerol dehydrogenases, Pentose, Pentose Catabolic Pathway, Reductase, 01 natural sciences, Applied Microbiology and Biotechnology, Transcriptome, PCR, polymerase chain reaction, NAD, nicotinamide adenine dinucleotide, XyrA, XyrB, d-xylose reductase, chemistry.chemical_classification, 0303 health sciences, biology, d-xylose reductase, PRD1, pentose reductase, 3. Good health, GldB, filamentous fungal glycerol dehydrogenase, Biochemistry, Aspergillus niger, PPP, Pentose Phosphate Pathway, Biotechnology, Research Article, LxrA, LxrB, l-xylulose reductase, LarA, l-arabinose reductase, education, XkiA, d-xylulose kinase, SdhA, sorbitol dehydrogenase, LadA, l-arabitol dehydrogenase, XdhA, xylitol dehydrogenase, 03 medical and health sciences, PBS, phosphate buffered saline, D-xylose reductase, 010608 biotechnology, 030304 developmental biology, Xylose Reductase, LB, Luria Bertani, Catabolism, AKR, aldo-keto reductase, biology.organism_classification, 11831 Plant biology, NADPH, reduced, PCP, Pentose Catabolic Pathway, Enzyme, chemistry, TP248.13-248.65
Abstract

Highlights • XyrB is involved in conversion of d-xylose and l-arabinose in A. niger. • The xyrB expression is induced both by d-xylose and l-arabinose. • XyrB expression is controlled by xlnR and araR regulators., d-xylose reductase is a member of the aldo-keto reductase family, and is involved in d-xylose and l-arabinose conversion through the Pentose Catabolic Pathway (PCP) in fungi. In this study, we biochemically characterized a newly identified second d-xylose reductase (XyrB) from Aspergillus niger. This NADPH-dependent reductase is able to efficiently convert d-xylose and l-arabinose, and it has the highest affinity for these sugars of all currently known fungal pentose reductases. A combination of biochemical data, transcriptomics and phylogenetic analysis further illustrated the role of XyrB in the PCP. Enzymes: D-xylose reductase (EC 1.1.1.307), L-arabinose reductase (EC 1.1.1.21).

Published
2021

48. Discovery and Functional Analysis of a Salicylic Acid Hydroxylase from Aspergillus niger

Author

Lubbers, Ronnie J M, Dilokpimol, Adiphol, Visser, Jaap, Hildén, Kristiina S, Mäkelä, Miia R, de Vries, Ronald P, Sub Molecular Plant Physiology, Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, Sub Molecular Plant Physiology, and Molecular Plant Physiology

Subjects
Muconic acid, Carboxy-Lyases, chemical building block, Decarboxylation, salicylic acid metabolism, 7. Clean energy, Applied Microbiology and Biotechnology, Mixed Function Oxygenases, platform chemical, Fungal Proteins, 03 medical and health sciences, chemistry.chemical_compound, SDG 7 - Affordable and Clean Energy, Phylogeny, 030304 developmental biology, 2. Zero hunger, chemistry.chemical_classification, 0303 health sciences, Ecology, biology, 030306 microbiology, catechol-dioxygenase, fungi, 2,3-Dihydroxybenzoic acid, Aspergillus niger, biology.organism_classification, Catechol 1,2-Dioxygenase, Metabolic pathway, Enzyme, chemistry, Biochemistry, biology.protein, Salicylic Acid, intradiol ring fission, Salicylic acid, Catechol dioxygenase, Food Science, Biotechnology
Abstract

Salicylic acid plays an important role in the plant immune response, and its degradation is therefore important for plant-pathogenic fungi. However, many nonpathogenic microorganisms can also degrade salicylic acid. In the filamentous fungus Aspergillus niger, two salicylic acid metabolic pathways have been suggested. The first pathway converts salicylic acid to catechol by a salicylate hydroxylase (ShyA). In the second pathway, salicylic acid is 3-hydroxylated to 2,3-dihydroxybenzoic acid, followed by decarboxylation to catechol by 2,3-dihydroxybenzoate decarboxylase (DhbA). A. niger cleaves the aromatic ring of catechol catalyzed by catechol 1,2-dioxygenase (CrcA) to form cis,cis-muconic acid. However, the identification and role of the genes and characterization of the enzymes involved in these pathways are lacking. In this study, we used transcriptome data of A. niger grown on salicylic acid to identify genes (shyA and crcA) involved in salicylic acid metabolism. Heterologous production in Escherichia coli followed by biochemical characterization confirmed the function of ShyA and CrcA. The combination of ShyA and CrcA demonstrated that cis,cis-muconic acid can be produced from salicylic acid. In addition, the in vivo roles of shyA, dhbA, and crcA were studied by creating A. niger deletion mutants which revealed the role of these genes in the fungal metabolism of salicylic acid. IMPORTANCE Nonrenewable petroleum sources are being depleted, and therefore, alternative sources are needed. Plant biomass is one of the most abundant renewable sources on Earth and is efficiently degraded by fungi. In order to utilize plant biomass efficiently, knowledge about the fungal metabolic pathways and the genes and enzymes involved is essential to create efficient strategies for producing valuable compounds such as cis,cis-muconic acid. cis,cis-Muconic acid is an important platform chemical that is used to synthesize nylon, polyethylene terephthalate (PET), polyurethane, resins, and lubricants. Currently, cis,cis-muconic acid is mainly produced through chemical synthesis from petroleum-based chemicals. Here, we show that two enzymes from fungi can be used to produce cis,cis-muconic acid from salicylic acid and contributes in creating alternative methods for the production of platform chemicals.

Published
2021

49. Protein kinase and phosphatase control of plant temperature responses

Author

Praat, Myrthe, De Smet, Ive, van Zanten, Martijn, Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, and Molecular Plant Physiology

Subjects
STRESS TRANSCRIPTION FACTORS, Heat Stress, Physiology, Phosphatase, SIGNAL-TRANSDUCTION, Cold acclimation, Kinases, Plant Science, Biology, COLD STRESS, Temperature Acclimation, thermomorphogenesis, heat stress, FREEZING TOLERANCE, SHADE AVOIDANCE, ARABIDOPSIS INFLORESCENCE ARCHITECTURE, STOMATAL DEVELOPMENT, Protein phosphorylation, phosphatases, Protein kinase A, GENE-EXPRESSION, CLIMATE-CHANGE, Kinase, Phosphatases, Biology and Life Sciences, Heat stress, Cell biology, kinases, temperature acclimation, Cold Acclimation, Thermomorphogenesis, Signalling pathways, Function (biology), HEAT-STRESS
Abstract

Plants must cope with ever-changing temperature conditions in their environment. Suboptimal high and low temperatures and stressful extreme temperatures induce adaptive mechanisms that allow optimal performance and survival, respectively. These processes have been extensively studied at the physiological, transcriptional, and (epi)genetic level. Cellular temperature signalling cascades and tolerance mechanisms also involve post-translational modifications (PTMs), particularly protein phosphorylation. Many protein kinases are known to be involved in cold acclimation and heat stress responsiveness, but the role and importance of kinases and phosphatases in triggering responses to mild changes in temperature, such as thermomorphogenesis, are inadequately understood. In this review, we summarize current knowledge on the roles of kinases and phosphatases in plant temperature responses. We discuss how kinases can function over a range of temperatures in different signalling pathways and provide an outlook to the application of PTM-modifying factors for the development of thermotolerant crops.

Published
2021

50. Re-routing of Sugar Catabolism Provides a Better Insight Into Fungal Flexibility in Using Plant Biomass-Derived Monomers as Substrates

Author

Chroumpi, Tania, Peng, Mao, Markillie, Lye Meng, Mitchell, Hugh D, Nicora, Carrie D, Hutchinson, Chelsea M, Paurus, Vanessa, Tolic, Nikola, Clendinen, Chaevien S, Orr, Galya, Baker, Scott E, Mäkelä, Miia R, de Vries, Ronald P, Molecular Plant Physiology, Sub Molecular Plant Physiology, Molecular Plant Physiology, Sub Molecular Plant Physiology, Westerdijk Fungal Biodiversity Institute - Fungal Physiology, Westerdijk Fungal Biodiversity Institute, Department of Microbiology, Fungal Genetics and Biotechnology, and Helsinki Institute of Sustainability Science (HELSUS)

Subjects
0301 basic medicine, Histology, lcsh:Biotechnology, 030106 microbiology, Biomedical Engineering, Pentose, Biomass, Bioengineering, Polysaccharide, 03 medical and health sciences, chemistry.chemical_compound, lcsh:TP248.13-248.65, sugar beet pulp, Monosaccharide, L-rhamnose catabolic pathway, Sugar, pentose catabolic pathway, Original Research, 2. Zero hunger, chemistry.chemical_classification, biology, lignocellulosic substrates, Aspergillus niger, Bioengineering and Biotechnology, food and beverages, 15. Life on land, biology.organism_classification, 220 Industrial biotechnology, Xyloglucan, 030104 developmental biology, chemistry, Biochemistry, D-galacturonic acid catabolic pathway, Sugar beet, wheat bran, CAZymes, Biotechnology
Abstract

The filamentous ascomycete Aspergillus niger has received increasing interest as a cell factory, being able to efficiently degrade plant cell wall polysaccharides as well as having an extensive metabolism to convert the released monosaccharides into value added compounds. The pentoses D-xylose and L-arabinose are the most abundant monosaccharides in plant biomass after the hexose D-glucose, being major constituents of xylan, pectin and xyloglucan. In this study, the influence of selected pentose catabolic pathway (PCP) deletion strains on growth on plant biomass and re-routing of sugar catabolism was addressed to gain a better understanding of the flexibility of this fungus in using plant biomass-derived monomers. The transcriptome, metabolome and proteome response of three PCP mutant strains, ΔlarAΔxyrAΔxyrB, ΔladAΔxdhAΔsdhA and ΔxkiA, grown on wheat bran (WB) and sugar beet pulp (SBP), was evaluated. Our results showed that despite the absolute impact of these PCP mutations on pure pentose sugars, they are not as critical for growth of A. niger on more complex biomass substrates, such as WB and SBP. However, significant phenotypic variation was observed between the two biomass substrates, but also between the different PCP mutants. This shows that the high sugar heterogeneity of these substrates in combination with the high complexity and adaptability of the fungal sugar metabolism allow for activation of alternative strategies to support growth.

Published
2021

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