Diatoms as potential “green” nanocomposite and nanoparticle synthesizers: challenges, prospects, and future materials applications

Pytlik, Nathalie, Brunner, Eike

02 June 2020

Diatoms are unicellular, eukaryotic microalgae inhabiting nearly all aquatic habitats. They are famous for their micro- and nanopatterned silicabased cell walls, which are envisioned for various technologic purposes. Within this review article, we summarize recent in vivo modifications of diatom biosilica with respect to the following questions: (i) Which metals are taken up by diatoms and eventually processed into nanoparticles (NPs)? (ii) Are these NPs toxic for the diatoms and––if so––what factors influence toxicity? (iii) What is the mechanism underlying NP synthesis and subsequent metabolism? (iv) How can the obtained materials be useful for materials science?

info:eu-repo/classification/ddc/670

ddc:670

Studies on the roles of 4-coumarate:coenzyme A ligase and 4-coumarate 3-hydroxylase in lignin biosynthesis in rice / イネのリグニン生合成における4-coumarate:coenzyme A ligase 及び 4-coumarate 3-hydroxylaseの役割

Afifi, Osama Ahmed Gamaleldin Abdou Ahmed

23 March 2023

京都大学 / 新制・課程博士 / 博士(農学) / 甲第24670号 / 農博第2553号 / 新制||農||1099(附属図書館) / 学位論文||R5||N5451(農学部図書室) / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授 梅澤 俊明, 教授 矢﨑 一史, 教授 森 直樹 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DGAM

Grasses

Lignin

Plant cell walls

Genome editting

4-coumarate:coenzyme A ligase

ascorbate peroxidase

4-coumarate 3-hydroxylase

610

Identification and Characterization of Galactosyltransferases and Fucosyltransferases Involved in Arabinogalactan-Protein Glycosylation

Liang, Yan

11 September 2012

No description available.

Biochemistry

Biology

Cellular Biology

Molecular Biology

Physiology

Plant Biology

Arabinogalactan-proteins

galactosyltransferase

fucosyltransferase

hydroxyproline-rich glycoproteins

plant cell walls

Impact of lignification of corn stover fractions on cell wall degradation by rumen microorganisms and response to ammonia treatment

Sewalt, Vincent Johannes Hendrikus

24 October 2005

Changes in cell wall composition and in vitro degradation of corn stover fractions (leaf, upper stem and lower stem) with advancing maturity and in response to NH; treatment were determined, and possible inhibitory mechanisms of lignin were evaluated. With advancing maturity, IVDMD decreased (P<.001), associated with decreases (P<.001) in CP and water soluble carbohydrates (WSC), and increases (P<.001) in NDF and ADF. The IVDMD of leaf was higher (P<.001) than of stems, associated with higher CP, hemicellulose:cellulose, and arabinan:xylan, and lower lignin methoxyl content. A hypothesis of formation of reactive quinone methide intermediates from lignin during rumen fermentation was tested in vitro by incubating corn stover fractions with S-containing reducing agents. Sulphur incorporation into residual fiber occurred (P<.05), indicative of nucleophilic addition to quinone methide intermediates. Degradation of NDF was highly correlated with lignin methoxyl content. The impact of lignin on cellulose degradation was studied using lignocellulosic hydrogels, in which hydroxypropylated or unmodified hardwood lignin was blended with cellulose. In vitro cellulose degradation of lignocellulose blends was higher (P<.01) than of control. Addition of lignin at incubation depressed (P<.01) cellulose degradation. Hydroxypropylation enhanced (P<.001) the increase in cellulose degradation with lignin blending, and reduced (P<.001) the inhibitory effect of lignin addition at incubation. Treatment of drought-stressed corn stover with 3% aqueous NH₃ decreased (P<.05) NDF, compared to isonitrogenous NH₃ addition and control, associated with solubilization of hemicellulose. Esterified phenolic acids were released (P<.05) by NH₃ treatment in upper stem. The IVDMD and NDF degradation increased (P <.001) after ammoniation, with higher (P<.05) values for NH₃ treatment than NH₃ added in leaf. The in vitro response to ammoniation of fractions of drought-stressed and non-drought stressed corn stover harvested in subsequent years was compared, using N-sufficient and N-limiting buffers. Response was highest (P<.001) for non-drought stressed stover fractions, and in N-limiting medium. Response appeared to be affected by high concentration of WSC in lower stalks of drought-stressed stover. / Ph. D.

LD5655.V856 1993.S482

Cell fractionation

Cellulose -- Biodegradation

Corn as feed

Lignin

Plant cell walls

Rumen -- Microbiology

Programmed Cell Death in Xylem Development

Courtois-Moreau, Charleen, Laetitia

January 2008

Concerns about climate changes and scarcity of fossil fuels are rising. Hence wood is becoming an attractive source of renewable energy and raw material and these new dimensions have prompted increasing interest in wood formation in trees, in both the scientific community and wider public. In this thesis, the focus is on a key process in wood development: programmed cell death (PCD) in the development of xylem elements. Since secondary cell wall formation is dependent, inter alia, upon the life time of xylem elements, the qualitative features of wood will be affected by PCD in xylem, about which there is little information. This thesis focuses on the anatomical, morphological and transcriptional features of PCD during xylem development in both the stem of hybrid aspen, Populus tremula (L.) x tremuloides (Michx.) and the hypocotyl of the herbaceous model system Arabidopsis thaliana (L. Heynh.). In Populus, the progressive removal of organelles from the cytoplasm before the time of death (vacuolar bursts) and the slowness of the cell death process, illustrated by DNA fragmentation assays (such as TUNEL and Comet assays), have been ascertained in the xylem fibres by microscopic analyses. Furthermore, candidate genes for the regulation of fibre cell death were identified either from a Populus EST library obtained from woody tissues undergoing fibre cell death or from microarray experiments in Populus stem, and further assessed in an in silico comparative transcriptomic analysis of Arabidopsis thaliana. These candidate genes were either putative novel regulators of fibre cell death or members of previously described families of cell death-related genes, such as autophagy-related genes. The induction of the latter and the previous microscopic observations suggest the importance of autophagy in the degradation of the cytoplasmic contents specifically in the xylem fibres. Vacuolar bursts in the vessels were the only previously described triggers of PCD in the xylem, which induce the very rapid degradation of the nuclei and surrounding cytoplasmic contents, therefore unravelling a unique previously unrecorded type of PCD in the xylem fibres, principally involving autophagy. Arabidopsis is an attractive alternative model plant for exploring some aspects of wood formation, such as the characterisation of negative regulators of PCD. Therefore, the anatomy of Arabidopsis hypocotyls was also investigated and the ACAULIS5 (ACL5) gene, encoding an enzyme involved in polyamine biosynthesis, was identified as a key regulator of xylem specification, specifically in the vessel elements, though its negative effect on the cell death process. Taken together, PCD in xylem development seems to be a highly specific process, involving unique cell death morphology and molecular machinery. In addition, the technical challenges posed by the complexity of the woody tissues examined highlighted the need for specific methods for assessing PCD and related phenomena in wood. / Oron för klimatförändringar och brist på fossila bränslen har ökat påtagligt under de senaste åren. De enorma möjligheter som skogsråvaran erbjuder som alternativ källa för förnyelsebar energi och råmaterial har väckt ett stort intresse också för den biologiska processen bakom vedbildning i träd. Denna avhandling fokuserar på en viktig process i vedbildning: programmerad celldöd (PCD) i xylemet. Xylemcellernas livstid påverkar bildningen av sekundära cellväggar, vilket i sin tur påverkar vedens kvalitativa egenskaperna, så som veddensitet. Trots dess betydelse för viktiga egenskaper hos vedråvaran existerar fortfarande väldigt lite information om xylem PCD på cellulär eller molekylär nivå. I den här avhandlingen belyses de anatomiska, morfologiska och genetiska aspekterna av PCD i xylemutveckling i både stam av hybridasp, Populus tremula (L.) x tremuloides (Michx.) och hypokotyl av det örtartade modellsystemet Arabidopsis thaliana (L. Heynh.). Xylemet i både Populus och Arabidopsis består av två olika celltyper; de vattentransporterade kärlen och de stödjande fibrerna. Det är känt att celldöd i kärlen pågår mycket snabbt efter att den centrala vakuolen brister och de hydrolytiska enzymer släpps in i cytoplasman. I den här avhandlingen ligger fokus på fibrerna i Populus xylemet. Med hjälp av mikroskopianalyser av cellmorfologin (elektronmikroskopi) och DNA-fragmentering i cellkärnan (TUNEL- och Comet-analyser) kunde vi konstatera att till skillnad från kärlen så uppvisar fibrerna en långsam och progressiv nedbrytning av organellerna och cellkärnans DNA före vakuolbristning. Dessutom har kandidatgener för reglering av fibercelldöd identifierats antingen från ett Populus EST bibliotek från vedartade vävnader som genomgår fibercelldöd eller från mikroarray experiment i Populus stam. Dessa kandidatgener är antingen potentiella nya regulatorer av fibercelldöd eller medlemmar av tidigare beskrivna familjer av celldödsrelaterade gener. Bland de sistnämnda finns autofagi-relaterade gener, vilket stöder funktionen av autofagi i samband med autolys av cellinnehållet i xylemfibrerna. Dessa studier pekar därför på en typ av PCD som har inte tidigare beskrivits för xylemet. Arabidopsis är ett alternativt växtmodellsystem för studier av vissa aspekter av vedbildningen, såsom karakteriseringen av negativa regulatorer av PCD. Därför har också hypokotylanatomin analyserats, och ACAULIS5 (ACL5) genen, som kodar för ett enzym i biosyntesen av polyaminer, har visats vara en viktig regulator av xylemspecifikation genom dess negativa effekt på kärlens celldöd. Sammantaget visar denna avhandling att PCD i xylemutvecklingen verkar involvera unika morfologiska och molekylära mekanismer. Vi visar dessutom att komplexiteten hos de vedartade vävnaderna leder till ett behov av bättre anpassade verktyg för att djupare kunna bedöma PCD och liknande fenomen i veden. / Även med namnet Moreau-Courtois, Charleen L. samt Moreau, Charleen.

PCD (Programmed Cell Death)

Xylem

Apoptosis

Autophagy

Secondary Cell Walls

Microscopy

Microarrays

Comet Assay

TUNEL Assay

Cell and molecular biology

Cell- och molekylärbiologi

Cell wall sulfur distribution in sulfonated southern pine latewood

Heazel, Thomas Edward

11 June 1988

No description available.

Southern pines

Cell walls

Chemical pulping

Diffusion

Digestion

Kinetics

Lignins

Mass loss

Mathematical models

Mechanical properties

Physical properties

Pulps

Sulfite pulping process

Sulfonation

Sulfur distribution

Molecular characterization of the fepA-fes bidirectional promoter in escherichia coli

Morris, Terry Lynn,

January 2001

Thesis (Ph. D.)--University of Missouri--Columbia, 2001. / Typescript. Vita. Includes bibliographical references (leaves 135-149). Also available on the Internet.

Identification of the role of [methyl]glucuronic acid on arabinogalactan polysaccharides in Arabidopsis thaliana

López Hernández, Federico

January 2018

Arabinogalactan proteins (AGPs) are proteoglycans heavily substituted by arabinogalactan polysaccharides. These are composed of arabinose and galactose, and minor sugars such as glucuronic acid (GlcA), fucose and xylose. The arabinogalactan polysaccharides do not decorate classical AGPs exclusively, but they can also be found decorating a wide range of proteins. Arabinogalactan proteins have been implicated in many processes of plant development. Recently, AGPs were proposed to bind and store calcium at the plasma membrane. They are extracellular, and are localised mainly at the plasma membrane via a GPI-anchor. They can also be soluble in the apoplast. Their low abundance, chemical similarity and high functional redundancy have hindered their study. My strategy to overcome these difficulties was to study knock-out Arabidopsis thaliana plants of glycosyltransferases that transfer sugars specifically onto AG-polysaccharides. Glucuronic acid makes up about 10% of the arabinogalactan polysaccharide structure in Arabidopsis thaliana cell culture AGPs. Previously, the glucuronic acid transferase A TGLCA T14A, a member of the CAZy Glycosyl Transferase 14 family, was shown to transfer GlcA specifically onto AGPs, and knock-out Arabidopsis plants showed a 30% reduction in [Me]GlcA substitution in AGP-enriched preparations. However, no clear growth phenotype was observed. The characterisation of knock-out plants of other GT14 family members and combinations thereof is described here. Based on previous studies (Lamport and Várnai, 2013), I assayed in vitro the calcium binding capacity of AGP extracts from WT and knock-out plants. The results showed that AGP extracts from knock-out plants can hold less calcium than WT plants in vitro. A wide range of plant growth phenotypes were identified. Growth phenotypes can be explained by changes in the cytoskeleton and deficiencies in calcium signaling. Our evidence suggests links between structural deficiencies of extracellular proteoglycans to extracellular calcium and cytoskeleton. This research has the potential to create a new model system for the study of molecular mechanisms dependent on calcium that drive cell expansion, division and differentiation in plants.

Etude de l’impact de l’Esca sur la qualité des raisins par une approche protéomique / Study of the impact of Esca on grape quality by a proteomic approach

Pasquier, Grégory

29 October 2012

La vigne est sensible à de nombreuses maladies cryptogamiques qui vont altérer la qualité des raisins et des vins. Depuis plusieurs années, l’Esca est devenue un fléau pour la viticulture moderne, car elle est responsable de la mort des pieds de vigne lorsqu’elle se présente sous forme apoplectique. Sa forme chronique est liée à la présence d’un cortège de champignons pathogènes dans le tronc et les bras, qui vont provoquer le plus souvent des symptômes foliaires. L’altération de la photosynthèse que cela provoque, va avoir des conséquences sur la maturation du fruit. Cependant, peu de travaux de recherche ont été menés pour caractériser précisément l’impact de cette maladie sur le métabolisme et la composition chimique des baies de raisin. Notre étude avait pour but d’apprécier, grâce à une approche protéomique, les conséquences de cette maladie sur la qualité des raisins. Nos travaux ont permis de mettre en évidence que l’expression de symptômes foliaires d’Esca provoque une modification d’abondance des protéines liées aux mécanismes de défense et de stress oxydatif de la pellicule du raisin. Il est également observé un changement de capacité antioxydante par modulation des teneurs en peroxyde d’hydrogène, en glutathion ou en pyridoxine. Les concentrations en molécules d’intérêt œnologique comme les acides aminés, les amines biogènes ou les tannins sont également modifiées en présence de symptômes foliaires d’Esca. / The vine is susceptible to many fungal diseases that will affect the quality of grapes and wines. For several years, Esca has become the bane of modern viticulture because it is responsible for the death of the vines when presented in the form apoplectic. Its chronic form is associated with the presence of a procession of pathogenic fungi in the trunk and arms that will most often cause leaf symptoms. The alteration of photosynthesis that this causes will affect fruit ripening. However, little research has been conducted to characterize precisely the impact of this disease on the metabolism and chemical composition of grape berries. Our study aimed to assess, using a proteomic approach the disease's impact on the quality of grapes and get specific markers. Our work allowed us to demonstrate that the expression of foliar symptoms of Esca causes a change in abundance of proteins related to defense mechanisms and oxidative stress in the grape skin. It is also observed a change in antioxidant capacity by modulating levels of hydrogen peroxide, glutathione or pyridoxine. The concentrations of molecules of oenological interest such as amino acids, biogenic amines or tannins are also modified in the presence of foliar symptoms of Esca.

Composition chimique

Esca

Métabolomique

Parois cellulaires

Protéomique

Raisin

Stress oxydant

Vignes

Qualité

Chemical composition

Esca

Metabolomics

Cell walls

Proteomics

Grapes

Oxidative stress

Vines

Quality

Functional role of the TLR4 signaling pathway in the bone marrow response to sepsis

Zhang, Huajia

31 March 2015

Indiana University-Purdue University Indianapolis (IUPUI) / Sepsis is a clinical syndrome due to a systemic inflammatory response to severe microbial infection. Little is known about the changes in the bone marrow (BM) and how they affect the hematopoietic response to bacterial infection. Using an animal model of severe sepsis induced by Pseudomonas aeruginosa, we have previously reported that hematopoietic stem cells (HSC) undergo a significant expansion in the BM accompanied with myeloid suppression. This bone marrow response was Toll-like Receptor 4 (TLR4)-dependent. TLR4 is activated by bacterial lipopolysaccharide (LPS) and signals through two major independent downstream molecules: TRIF and MyD88. In the present study, I found that the TLR4/TRIF and the TLR4/MyD88 pathways contribute in a distinct manner to the BM response to P. aeruginosa's LPS. TRIF plays a major role in the expansion of the HSC pool, whereas MyD88 is required for myeloid suppression. Following LPS stimulation, HSCs enter in the cell cycle, expand and exhaust when transplanted in healthy mice. Loss of TRIF rescued completely the long-term engraftment and multilineage reconstitution potential of septic HSCs, but did not affect myeloid differentiation. Conversely, MyD88 deficiency prevented completely the myeloid suppression in the myeloid progenitors, but conferred limited protective effects on the HSC function. It is of great therapeutic value to identify the downstream molecules involved in TLR4/MyD88 dependent myeloid suppression. I found miR-21, a microRNA that is involved in inflammation, was up-regulated upon LPS challenge in a MyD88-dependent manner. However, deletion of miR-21 in the BM did not rescue LPS-induced bone marrow dysfunction, demonstrating that miR-21 is not a critical regulator in these processes. Further studies are warranted to determine the precise molecular mechanisms involved in the complex pathogenesis of BM response to sepsis. Taken together, my results show for the first time that the TLR4/TRIF signaling as a key mediator of HSC damage during acute LPS exposure and that activation of the TLR4/MyD88 signaling pathway play a dominant role in myeloid suppression. These results provide novel insights into our understanding of the molecular mechanisms underlying bone marrow injury during severe sepsis and may lead to the development of new therapeutic approaches in this disease.

Septicemia

Septicemia -- Treatment

Bone marrow -- Histopathology

Nosocomial infections -- Epidemiology

Transplantation immunology

Bacterial cell walls

Peptidoglycans

Immune response -- Regulation

Immunosuppresion

Immune System -- Physiology