Biological fabrication of cellulose fibers with tailored properties

Natálio, Filipe; Fuchs, Regina; Cohen, Sidney R.; Leitus, Gregory; Fritz‐Popovski, Gerhard; Paris, Oskar; Kappl, Michael; Butt, Hans‐Jürgen

doi:10.1126/science.aan5830

Cited by 40 publications

(44 citation statements)

References 33 publications

(34 reference statements)

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“…The analysis showed identified selection signatures at 670 and 232 PSGs in the G. australe and G. arboretum genomes, respectively (Figure S6, Data S1). Subsequent KEGG pathway analysis indicated that statistically significant ( P < 0.05) enrichment among the G. australe PSGs for the ‘Other types of O‐glycan biosynthesis’ (ko00514) pathway (Figure S7), which was associated with cotton fibre strength in studies of in G. arboreum (Hernandez‐Gomez et al ., ; Natalio et al ., ). There was also significant enrichment among the G. australe PSGs for ‘Riboflavin metabolism’ (ko00740) (Asai et al ., ; Boubakri et al ., ; Deng et al ., ) and GPI (Shen et al ., ) (Figure S7), pathways which have been implicated in plant responses to biotic stresses.…”

Section: Resultsmentioning

confidence: 97%

Genome sequencing of the Australian wild diploid species Gossypium australe highlights disease resistance and delayed gland morphogenesis

Cai

Wang

et al. 2019

Plant Biotechnology Journal

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Summary The diploid wild cotton species Gossypium australe possesses excellent traits including resistance to disease and delayed gland morphogenesis, and has been successfully used for distant breeding programmes to incorporate disease resistance traits into domesticated cotton. Here, we sequenced the G. australe genome by integrating PacBio, Illumina short read, BioNano (DLS) and Hi‐C technologies, and acquired a high‐quality reference genome with a contig N50 of 1.83 Mb and a scaffold N50 of 143.60 Mb. We found that 73.5% of the G. australe genome is composed of various repeat sequences, differing from those of G. arboreum (85.39%), G. hirsutum (69.86%) and G. barbadense (69.83%). The G. australe genome showed closer collinear relationships with the genome of G. arboreum than G. raimondii and has undergone less extensive genome reorganization than the G. arboreum genome. Selection signature and transcriptomics analyses implicated multiple genes in disease resistance responses, including GauCCD7 and GauCBP1, and experiments revealed induction of both genes by Verticillium dahliae and by the plant hormones strigolactone (GR24), salicylic acid (SA) and methyl jasmonate (MeJA). Experiments using a Verticillium‐resistant domesticated G. barbadense cultivar confirmed that knockdown of the homologues of these genes caused a significant reduction in resistance against Verticillium dahliae. Moreover, knockdown of a newly identified gland‐associated gene GauGRAS1 caused a glandless phenotype in partial tissues using G. australe. The G. australe genome represents a valuable resource for cotton research and distant relative breeding as well as for understanding the evolutionary history of crop genomes.

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Section: Resultsmentioning

confidence: 97%

Genome sequencing of the Australian wild diploid species Gossypium australe highlights disease resistance and delayed gland morphogenesis

Cai

Wang

et al. 2019

Plant Biotechnology Journal

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“…Furthermore, most chemical modification approaches are carried out on the commercial papers, resulting in the poor uniformity of structure due to artificial operation [29]. To improve the poor uniformity of structure, new paper modification approaches based on the papermaking process, such as addition of chemical reagents during the pulping process [142], can be used to produce special functional papers. Finally, hydrophobic patterning and barrier modification approaches will be further developed for integration with paperbased electronic chips [143].…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

A review on advances in methods for modification of paper supports for use in point-of-care testing

et al. 2019

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Paper is a widely used support for use in devices for point-of-care testing (POCT) in clinical diagnosis, food safety monitoring and environmental pollution. Paper is inexpensive, biocompatible, biodegradable and allows a sample fluid to flow by capillary force. Numerous method have been developed recently for chemical modification of papers in order to introduce different functionalities. This review (with 148 refs.) summarizes the recent progress in paper-based POCT devices. The introduction summarizes the state of the art of paper-based POCT devices and the physicochemical properties of existing unmodified materials (including cellulose, cellulose-based composites, cotton fibers, glass fibers, nitrocellulose, thread). Methods for paper modification for sample pretreatment are summarized next, with subsections on sample storage and collection, sample separation, nucleic acid extraction and sample preconcentration. Another main section covers approaches for paper modification for improving POCTs, with subsections on assays for proteins, nucleic acids, drugs, ion and organic molecules. The advantages and disadvantages of these approaches are compared. Several tables are presented that summarize the various modification techniques. A concluding section summarizes the current status, addresses challenges and gives an outlook on future perspectives of POCTs.

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“…Our very initial studies were aimed at studying the biological selectivity uptake of different classes of organic dyes by the intermembranar glucose/sucrose transporter(s) (GLUT) using an in vitro culture of cotton . For this purpose, the cotton flowers were collected on the second day postanthesis and sterilized; the ovules were then carefully removed and floated in a Beasley and Ting medium (in a Petri dish) .…”

Section: Methodological Approach To Tailoring Functionalities Of Cottmentioning

confidence: 99%

“…After exposing the fibers to UV light, the fibers became fluorescent. To ensure the coloration/fluorescence was biologically integrated and not merely a redeposition of the dye due to evaporation inside the Petri dish, we performed a small‐angle X‐ray scattering (SAXS), wide‐Angle X‐ray scattering (WAXS), and single fiber mechanical tensile analysis . The SAXS and WAXS showed an increased structural amorphization and the fiber mechanical tensile analysis revealed a decrease in the fiber's mechanical properties.…”

Section: Methodological Approach To Tailoring Functionalities Of Cottmentioning

confidence: 99%

Future Perspectives on Biological Fabrication and Material Farming

Natálio

2018

Small Methods

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What is biological fabrication? It is combining the ability of designing bioinspired molecules (chemistry) with nature's complexity and ingenious paths (biology) in order to produce new composite materials with emergent properties while being able to tailor the said materials' end‐functionality or functionalities. And what is material farming? It is the possibility to implement alternative and sustainable methodologies of biological fabrication toward larger scales, real‐life applications, and marketable products. The proof‐of‐principle is recently demonstrated for biological fabrication of fibers with tailored properties using an in vitro cotton culture and designed glucose derivatives yielding fluorescent and supermagnetic cotton fibers. This new “fabrication approach” will allow, in the future, to sustainably transform abundant raw materials into an innovative new class of composite functional materials, such as a new generation of smart textiles in the above case of cotton. This essay provides a very brief overview of the research done in cotton, the methodology used for the biological fabrication of cotton fibers with tailored properties and, finally, showcases perspectives on the future of this new and exciting research field that challenges the present fabrication methodologies that heavily rely on an old mindset toward bio‐based fabrication strategies.

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Biological fabrication of cellulose fibers with tailored properties

Cited by 40 publications

References 33 publications

Genome sequencing of the Australian wild diploid species Gossypium australe highlights disease resistance and delayed gland morphogenesis

Genome sequencing of the Australian wild diploid species Gossypium australe highlights disease resistance and delayed gland morphogenesis

A review on advances in methods for modification of paper supports for use in point-of-care testing

Future Perspectives on Biological Fabrication and Material Farming

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