Xylem cells cooperate in the control of lignification and cell death during plant vascular development

Escamez, Sacha

January 2016

The evolutionary success of land plants was fostered by the acquisition of the xylem vascular tissue which conducts water and minerals upwards from the roots. The xylem tissue of flowering plants is composed of three main types of cells: the sap-conducting tracheary elements (TE), the fibres which provide mechanical support and the parenchyma cells which provide metabolic support to the tissue. Both the TEs and the fibres deposit thick polysaccharidic secondary cell walls (SCWs), reinforced by a rigid phenolic polymer called lignin. The cell walls of TEs form efficient water conducting hollow tubes after the TEs have undergone programmed cell death (PCD) and complete protoplast degradation as a part of their differentiation. The work presented in this thesis studied the regulation of TE PCD by characterizing the function of the candidate PCD regulator METACASPASE 9 (MC9) in Arabidopsis thaliana xylogenic cell suspensions. These cell suspensions can be externally induced to differentiate into a mix of TEs and parenchymatic non-TE cells, thus representing an ideal system to study the cellular processes of TE PCD. In this system, TEs with reduced expression of MC9 were shown to have increased levels of autophagy and to trigger the ectopic death of the non-TE cells. The viability of the non-TE cells could be restored by down-regulating autophagy specifically in the TEs with reduced MC9 expression. Therefore, this work showed that MC9 must tightly regulate the level of autophagy during TE PCD in order to prevent the TEs from becoming harmful to the non-TEs. Hence, this work demonstrated the existence of a cellular cooperation between the TEs and the surrounding parenchymatic cells during TE PCD. The potential cooperation between the TEs and the neighbouring parenchyma during the biosynthesis of lignin was also investigated. The cupin domain containing protein PIRIN2 was found to regulate TE lignification in a non-cell autonomous manner in Arabidopsis thaliana. More precisely, PIRIN2 was shown to function as an antagonist of positive transcriptional regulators of lignin biosynthetic genes in xylem parenchyma cells. Part of the transcriptional regulation by PIRIN2 involves chromatin modifications, which represent a new type of regulation of lignin biosynthesis. Because xylem constitutes the wood in tree species, this newly discovered regulation of non-cell autonomous lignification represents a potential target to modify lignin biosynthesis in order to overcome the recalcitrance of the woody biomass for the production of biofuels.

Xylem

Arabidopsis

programmed cell death

tracheary element

xylem vessel

autophagy

metacaspase

lignin

secondary cell wall

chromatin

gene expression

Perfil transcricional da xilogênese em Eucalyptus grandis / Transcriptional profile of xylogenesis in Eucalyptus grandis

Pinto, Ana Paula Chiaverini

27 April 2017

O eucalipto (Eucalyptus spp.) é a arbórea comercial mais importante do Brasil, tendo um papel marcante na indústria de papel e celulose. O aumento no rendimento da extração da polpa celulósica e a redução nos custos de produção são os principais objetivos dos programas de melhoramento genético de eucalipto. Como o processo de deslignificação é fundamental para a extração da celulose, é suma importante compreender a biossíntese e deposição da parede celular secundária durante a xilogênese. A diferenciação dos elementos traqueais é caracterizada pela deposição da parede celular secundária, logo estudos de expressão gênica envolvendo essas células xilemáticas é uma estratégia interessante. Foi realizado o sequenciamento do transcriptoma de células em suspensão em diferentes fases de desenvolvimento (células meristemáticas, células alongadas e elementos traqueais) gerando 348 milhões de leituras paired-end com 100 pb cada uma, com a maioria das leituras (80 %) alinhada e mapeada contra genoma de referência. A análise dos genes diferencialmente expressos (GDEs) identificou um total de 3426, 1044 e 4665 GDEs nas comparações M vs. A, A vs. T e M vs. T, respectivamente. Sendo 1316, 567, 2637 genes up-regulated e 2110, 476, 2028 genes down-regulated nas comparações M/A, T/A, T/M, respectivamente. Um total de 4229 genes foram anotados funcionalmente e mapeados em 310 rotas identificadas pelo KEGG, obtendo-se 40 sequências relacionadas à rota dos fenilpropanoides, a quinta rota mais representativa. Quando foram considerados os GDEs com log2 fold change ≤ -1,5 e log2 fold change ≥ 1,5, 34 rotas metabólicas foram identificadas, destas, a principal foi a rota dos fenilpropanoides, com 14 sequências relacionadas a enzima lactoperoxidase. Foi realizado o enriquecimento dos termos GO e nas redes a biossíntese de celulose e xiloglucanos, rotas de sinalização de etileno, rotas de biogênese e organização da parede celular vegetal e de morte celular, entre outras, foram destaque. Identificaram-se 31 fatores de transcrição, sendo 3 fatores de transcrição MYB, 2 fatores de transcrição NAC e 10 fatores de transcrição WRKY. Além disso, 21, 7 e 23 genes da rota da celulose e hemiceluloses e 24, 8 e 21 genes da rota de síntese dos monômeros da lignina foram constatados nas comparações M vs. A, A vs. T e M vs. T, respectivamente. Assim como, foram encontrados genes codificadores de lacases e peroxidases, participantes da polimerização dos monômeros da lignina. Os resultados possibilitaram uma compreensão mais ampla da regulação transcricional da biossíntese da parede celular secundária nas células xilemáticas de eucalipto e revelou novos genes participantes da xilogênese. Este conjunto de dados transcricionais ajudará na realização de manipulações genéticas visando à obtenção de plantas de eucalipto com características de extratibilidade aspiradas pela indústria. / Eucalyptus (Eucalyptus spp.) is the most important commercial tree in Brazil, playing a significant role in the pulp and paper industry. An increase in the yield of cellulosic pulp extraction and a reduction of production cost are the main objectives of the eucalyptus breeding programs. As the delignification process is fundamental for the extraction of cellulose, it is highly important to understand the biosynthesis and deposition of the secondary cell wall during xylogenesis. The differentiation of the tracheary elements is characterized by the deposition of the secondary cell wall, so studies of gene expression involving these xylem cells is an interesting strategy. Sequencing of the transcriptome of cells in suspension at different stages of development (meristematic cells, elongated cells and tracheal elements) was performed generating 348 million paired-end reads with 100 bp each, with most readings (80%) aligned and mapped against reference genome. The analysis of differentially expressed genes (DEG) identified a total of 3426, 1044 and 4665 DEGs in the comparisons M vs. A, A vs. T and M vs. T, respectively. Being 1316, 567, 2637 up-regulated genes and 2110, 476, 2028 down-regulated genes in the M/A, T/A, T/M, respectively. A total of 4229 genes were functionally annotated and mapped in 310 routes identified by the KEGG, yielding 40 sequences related to the phenylpropanoid route, the fifth most representative route. When DEGs with log2 fold change ≤ - 1.5 e log2 fold change ≥ 1.5 were considered, 34 metabolic routes were identified. From these, the main route was the phenylpropanoids pathway, with 14 sequences correlated to the enzyme lactoperoxidase. The GO terms enrichment was carried out and the networks of cellulose and xyloglucans biosynthesis, ethylene signaling routes, biogenesis routes and the plant cell wall organization and cell death, among others, were highlighted. Thirty-one transcription factors were identified, being 3 MYB transcription factors, 2 NAC transcription factors and 10 WRKY transcription factors. In addition, 21, 7 and 23 genes of the cellulose and hemicelluloses pathway and 24, 8 and 21 genes of lignin monomer synthesis route were found in the M vs. A, A vs. T and M vs. T comparisons, respectively. Besides this, encoding genes laccases and peroxidases were found, participating in the polymerization of lignin monomers. The results allowed a broader understanding of the transcriptional regulation of secondary cell wall biosynthesis in eucalyptus xylem cells and revealed new genes participating in xylogenesis. This set of transcriptional data will help in the accomplishment of genetic manipulations in order to obtain eucalyptus plants with extractability characteristics aspired by the industry.

Elementos traqueais

Expressão gênica

Gene expression

Parede celular secundária

RNA-seq

RNA-seq

Secondary cell wall

Tracheary elements

Cultura de células em suspensão como ferramenta para estudos em parede celular secundária em gramí­neas C4 / Suspension cell culture as a tool for secondary cell wall studies in C4 grasses

Simões, Marcella Siqueira

04 December 2017

As características físico-químicas da parede celular constituem um grande gargalo na obtenção dos açúcares fermentáveis a partir dos polissacarídeos de parede celular presentes na biomassa, fato conhecido como recalcitrância da biomassa vegetal. A utilização da biomassa na produção de biocombustíveis requer um melhor entendimento sobre os mecanismos que permeiam os processos de deposição de parede celular e metabolismo de lignina. Nesse contexto, a maior parte do conhecimento foi gerado em espécies eudicotiledôneas, havendo uma significativa lacuna para gramíneas, apesar do seu grande potencial para acúmulo de biomassa. Portanto, há uma necessidade de se estabelecer ferramentas-modelos que permitam elucidar características exclusivas da parede celular secundária de gramíneas C4, cujo conhecimento não pode ser extrapolado a partir de eudicotiledôneas. O presente trabalho propôs estabelecer um sistema de células em suspensão como ferramenta-modelo em estudos sobre parede celular secundária em gramíneas C4. Para tal, três espécies foram inclusas: Sorghum bicolor, Setaria viridis e cana-de-açúcar. Devido às características recalcitrantes do sorgo, apenas as suspensões celulares de S. viridis e cana-de-açúcar foram estabelecidas. Subsequentemente, estas culturas foram utilizadas na tentativa de se desenvolver duas aplicações para o estudo de parede secundária: i) culturas xilogênicas, em que as células em suspensão são induzidas a se transdiferenciar em elementos traqueais; e ii) sistema de protoplastos para ensaios de transativação para testar o potencial papel de fatores de transcrição na regulação transcricional da deposição de parede celular. Somente as culturas de cana-de-açúcar responderam aos tratamentos testados para indução da transdiferenciação de elementos traqueais, baseados em protocolos estabelecidos para outras gramíneas. Análises de expressão gênica por RT-qPCR foram utilizadas para caracterizar a variação da expressão de genes-alvo durante este processo. Ademais, as paredes celulares das células em suspensão de cana-de-açúcar foram digeridas com um coquetel de hidrolases para a produção de protoplastos. A cultura de células em suspensão de cana-de-açúcar e suas aplicações aqui estabelecidas poderão ser utilizadas na elucidação de aspectos únicos do processo de deposição de parede celular secundária em gramíneas C4 / The physicochemical features of the cell wall represent a major bottleneck for the processing of cell wall polysaccharides present in biomass into fermentable sugars, a fact known as plant biomass recalcitrance. Biofuels production from biomass requires a better understanding on the molecular mechanisms underlying secondary cell wall deposition and lignin metabolism. In this context, most of the current knowledge has been generated in eudicots species, whereas significantly less is known for grasses, despite of their great potential for biomass accumulation. Therefore, the development of tools that allow the discovery of specific aspects of C4 grasses secondary cell walls is of great interest, because this knowledge cannot be extrapolated from data generated for eudicots. In the present work, we aimed to develop suspension cell cultures as a tool for the study of secondary cell wall metabolism in C4 grasses. For this purpose, three species were employed: Sorghum bicolor, Setaria viridis and sugarcane. Because of the recalcitrant nature of sorghum, only suspensions cells of S. viridis and sugarcane were successfully established. Subsequently, these cultures were used in an attempt to develop two applications to study secondary cell walls: i) xylogenic cultures, in which the suspension cells are induced to transdifferentiate into tracheary elements; and ii) a protoplast system to be used in transactivation assays to test the potential role of transcriptional factors in the regulation of secondary wall deposition. Only the suspension cultures of sugarcane showed a positive response to the tested treatments for the induction of tracheary elements formation, which were based on modifications of previous protocols established for other grasses. Gene expression analysis by RT-qPCR was used to characterize the variation of the expression of target genes during this process. Moreover, the cell walls of sugarcane suspension cells were digested with a cocktail of hydrolases to produce protoplasts, which were used in transactivation assays between transcriptional factors known to be involved in secondary cell wall deposition and their putative target genes, as a proof-of-concept. The sugarcane suspension cells and their applications established in this work might be used to further elucidate unique aspects of secondary cell wall deposition in C4 grasses

C4 grasses

Cultura de tecidos

Gramíneas C4

Lignin

Lignina

Parede celular secundária

Secondary cell wall

Tissue culture

Xilogênese

Xylogenic culture

Perfil transcricional da xilogênese em Eucalyptus grandis / Transcriptional profile of xylogenesis in Eucalyptus grandis

Ana Paula Chiaverini Pinto

27 April 2017

O eucalipto (Eucalyptus spp.) é a arbórea comercial mais importante do Brasil, tendo um papel marcante na indústria de papel e celulose. O aumento no rendimento da extração da polpa celulósica e a redução nos custos de produção são os principais objetivos dos programas de melhoramento genético de eucalipto. Como o processo de deslignificação é fundamental para a extração da celulose, é suma importante compreender a biossíntese e deposição da parede celular secundária durante a xilogênese. A diferenciação dos elementos traqueais é caracterizada pela deposição da parede celular secundária, logo estudos de expressão gênica envolvendo essas células xilemáticas é uma estratégia interessante. Foi realizado o sequenciamento do transcriptoma de células em suspensão em diferentes fases de desenvolvimento (células meristemáticas, células alongadas e elementos traqueais) gerando 348 milhões de leituras paired-end com 100 pb cada uma, com a maioria das leituras (80 %) alinhada e mapeada contra genoma de referência. A análise dos genes diferencialmente expressos (GDEs) identificou um total de 3426, 1044 e 4665 GDEs nas comparações M vs. A, A vs. T e M vs. T, respectivamente. Sendo 1316, 567, 2637 genes up-regulated e 2110, 476, 2028 genes down-regulated nas comparações M/A, T/A, T/M, respectivamente. Um total de 4229 genes foram anotados funcionalmente e mapeados em 310 rotas identificadas pelo KEGG, obtendo-se 40 sequências relacionadas à rota dos fenilpropanoides, a quinta rota mais representativa. Quando foram considerados os GDEs com log2 fold change ≤ -1,5 e log2 fold change ≥ 1,5, 34 rotas metabólicas foram identificadas, destas, a principal foi a rota dos fenilpropanoides, com 14 sequências relacionadas a enzima lactoperoxidase. Foi realizado o enriquecimento dos termos GO e nas redes a biossíntese de celulose e xiloglucanos, rotas de sinalização de etileno, rotas de biogênese e organização da parede celular vegetal e de morte celular, entre outras, foram destaque. Identificaram-se 31 fatores de transcrição, sendo 3 fatores de transcrição MYB, 2 fatores de transcrição NAC e 10 fatores de transcrição WRKY. Além disso, 21, 7 e 23 genes da rota da celulose e hemiceluloses e 24, 8 e 21 genes da rota de síntese dos monômeros da lignina foram constatados nas comparações M vs. A, A vs. T e M vs. T, respectivamente. Assim como, foram encontrados genes codificadores de lacases e peroxidases, participantes da polimerização dos monômeros da lignina. Os resultados possibilitaram uma compreensão mais ampla da regulação transcricional da biossíntese da parede celular secundária nas células xilemáticas de eucalipto e revelou novos genes participantes da xilogênese. Este conjunto de dados transcricionais ajudará na realização de manipulações genéticas visando à obtenção de plantas de eucalipto com características de extratibilidade aspiradas pela indústria. / Eucalyptus (Eucalyptus spp.) is the most important commercial tree in Brazil, playing a significant role in the pulp and paper industry. An increase in the yield of cellulosic pulp extraction and a reduction of production cost are the main objectives of the eucalyptus breeding programs. As the delignification process is fundamental for the extraction of cellulose, it is highly important to understand the biosynthesis and deposition of the secondary cell wall during xylogenesis. The differentiation of the tracheary elements is characterized by the deposition of the secondary cell wall, so studies of gene expression involving these xylem cells is an interesting strategy. Sequencing of the transcriptome of cells in suspension at different stages of development (meristematic cells, elongated cells and tracheal elements) was performed generating 348 million paired-end reads with 100 bp each, with most readings (80%) aligned and mapped against reference genome. The analysis of differentially expressed genes (DEG) identified a total of 3426, 1044 and 4665 DEGs in the comparisons M vs. A, A vs. T and M vs. T, respectively. Being 1316, 567, 2637 up-regulated genes and 2110, 476, 2028 down-regulated genes in the M/A, T/A, T/M, respectively. A total of 4229 genes were functionally annotated and mapped in 310 routes identified by the KEGG, yielding 40 sequences related to the phenylpropanoid route, the fifth most representative route. When DEGs with log2 fold change ≤ - 1.5 e log2 fold change ≥ 1.5 were considered, 34 metabolic routes were identified. From these, the main route was the phenylpropanoids pathway, with 14 sequences correlated to the enzyme lactoperoxidase. The GO terms enrichment was carried out and the networks of cellulose and xyloglucans biosynthesis, ethylene signaling routes, biogenesis routes and the plant cell wall organization and cell death, among others, were highlighted. Thirty-one transcription factors were identified, being 3 MYB transcription factors, 2 NAC transcription factors and 10 WRKY transcription factors. In addition, 21, 7 and 23 genes of the cellulose and hemicelluloses pathway and 24, 8 and 21 genes of lignin monomer synthesis route were found in the M vs. A, A vs. T and M vs. T comparisons, respectively. Besides this, encoding genes laccases and peroxidases were found, participating in the polymerization of lignin monomers. The results allowed a broader understanding of the transcriptional regulation of secondary cell wall biosynthesis in eucalyptus xylem cells and revealed new genes participating in xylogenesis. This set of transcriptional data will help in the accomplishment of genetic manipulations in order to obtain eucalyptus plants with extractability characteristics aspired by the industry.

Elementos traqueais

Expressão gênica

Parede celular secundária

RNA-seq

Gene expression

RNA-seq

Secondary cell wall

Tracheary elements

Cultura de células em suspensão como ferramenta para estudos em parede celular secundária em gramí­neas C4 / Suspension cell culture as a tool for secondary cell wall studies in C4 grasses

Marcella Siqueira Simões

04 December 2017

As características físico-químicas da parede celular constituem um grande gargalo na obtenção dos açúcares fermentáveis a partir dos polissacarídeos de parede celular presentes na biomassa, fato conhecido como recalcitrância da biomassa vegetal. A utilização da biomassa na produção de biocombustíveis requer um melhor entendimento sobre os mecanismos que permeiam os processos de deposição de parede celular e metabolismo de lignina. Nesse contexto, a maior parte do conhecimento foi gerado em espécies eudicotiledôneas, havendo uma significativa lacuna para gramíneas, apesar do seu grande potencial para acúmulo de biomassa. Portanto, há uma necessidade de se estabelecer ferramentas-modelos que permitam elucidar características exclusivas da parede celular secundária de gramíneas C4, cujo conhecimento não pode ser extrapolado a partir de eudicotiledôneas. O presente trabalho propôs estabelecer um sistema de células em suspensão como ferramenta-modelo em estudos sobre parede celular secundária em gramíneas C4. Para tal, três espécies foram inclusas: Sorghum bicolor, Setaria viridis e cana-de-açúcar. Devido às características recalcitrantes do sorgo, apenas as suspensões celulares de S. viridis e cana-de-açúcar foram estabelecidas. Subsequentemente, estas culturas foram utilizadas na tentativa de se desenvolver duas aplicações para o estudo de parede secundária: i) culturas xilogênicas, em que as células em suspensão são induzidas a se transdiferenciar em elementos traqueais; e ii) sistema de protoplastos para ensaios de transativação para testar o potencial papel de fatores de transcrição na regulação transcricional da deposição de parede celular. Somente as culturas de cana-de-açúcar responderam aos tratamentos testados para indução da transdiferenciação de elementos traqueais, baseados em protocolos estabelecidos para outras gramíneas. Análises de expressão gênica por RT-qPCR foram utilizadas para caracterizar a variação da expressão de genes-alvo durante este processo. Ademais, as paredes celulares das células em suspensão de cana-de-açúcar foram digeridas com um coquetel de hidrolases para a produção de protoplastos. A cultura de células em suspensão de cana-de-açúcar e suas aplicações aqui estabelecidas poderão ser utilizadas na elucidação de aspectos únicos do processo de deposição de parede celular secundária em gramíneas C4 / The physicochemical features of the cell wall represent a major bottleneck for the processing of cell wall polysaccharides present in biomass into fermentable sugars, a fact known as plant biomass recalcitrance. Biofuels production from biomass requires a better understanding on the molecular mechanisms underlying secondary cell wall deposition and lignin metabolism. In this context, most of the current knowledge has been generated in eudicots species, whereas significantly less is known for grasses, despite of their great potential for biomass accumulation. Therefore, the development of tools that allow the discovery of specific aspects of C4 grasses secondary cell walls is of great interest, because this knowledge cannot be extrapolated from data generated for eudicots. In the present work, we aimed to develop suspension cell cultures as a tool for the study of secondary cell wall metabolism in C4 grasses. For this purpose, three species were employed: Sorghum bicolor, Setaria viridis and sugarcane. Because of the recalcitrant nature of sorghum, only suspensions cells of S. viridis and sugarcane were successfully established. Subsequently, these cultures were used in an attempt to develop two applications to study secondary cell walls: i) xylogenic cultures, in which the suspension cells are induced to transdifferentiate into tracheary elements; and ii) a protoplast system to be used in transactivation assays to test the potential role of transcriptional factors in the regulation of secondary wall deposition. Only the suspension cultures of sugarcane showed a positive response to the tested treatments for the induction of tracheary elements formation, which were based on modifications of previous protocols established for other grasses. Gene expression analysis by RT-qPCR was used to characterize the variation of the expression of target genes during this process. Moreover, the cell walls of sugarcane suspension cells were digested with a cocktail of hydrolases to produce protoplasts, which were used in transactivation assays between transcriptional factors known to be involved in secondary cell wall deposition and their putative target genes, as a proof-of-concept. The sugarcane suspension cells and their applications established in this work might be used to further elucidate unique aspects of secondary cell wall deposition in C4 grasses

Cultura de tecidos

Gramíneas C4

Lignina

Parede celular secundária

Xilogênese

C4 grasses

Lignin

Secondary cell wall

Tissue culture

Xylogenic culture

Investigation of genes and proteins involved in xylan biosynthesis

Winzell, Anders

January 2010

Wood formation or xylogenesis is a fundamental process for so diverse issues as industry, shelter and a sustainable environment. Wood is comprised of secondary xylem, rigid large cells with thick cell walls that are lignified. The basis for the sturdy cells is an advanced composite made up of cellulose fibers cross-linked by hemicelluloses and finally embedded in lignin. This fiber-composite is the secondary cell walls of woody plants. Cell division and differentiation is regulated by switching on and off genes. Proteins encoded by these genes execute the major functions in the cells. They steer the entire machinery operating the structure and function of the cells, maintaining growth and synthesising essential products such as the cell wall carbohydrates.   Here we describe the investigation of genes and proteins involved in xylan formation as well as the development of a model system that will aid the functional analysis of wood formation. Xylan is the main hemicellulose or cross linking glycan in dicot wood and thereby one of the most abundant carbohydrates on earth. We demonstrate that hybrid aspen cell suspension cultures can be used as a model system for secondary cell wall formation. We have also examined glycosyltransferases from CAZy family 43 that play a part in secondary cell wall formation. We have focused on one of these, Pt×tGT43A, a likely ortholog of Arabidopsis IRX9, which plays a crucial role in xylan formation. The protein was transiently expressed in Nicotiana benthamiana and its function and localization is described. Also, we investigate a glycoside hydrolase, Pt×tXyn10A, involved in wood formation. Its role is not clear but it most likely modifies xylan as it gets incorporated into the secondary cell wall after secretion from the Golgi. This influences the interaction between cellulose, xylan and lignin in the finished wood cell. We have also cloned a transcription factor, Pt×tMYB021, a likely ortholog of Arabidopsis MYB46 and we show that it activates GT43A, GT43B and Xyn10A. By analysis of the promoter sequences we identify a CA-rich motif putatively important for xylem-specific genes.   By mastering proteins involved in xylogenesis we will acquire the tools to improve and develop the wood product market. Xylan is an immense unexploited source of renewable carbohydrate. New products envisioned include e.g. faster growing trees, changed fiber characteristics, optimised utilization of wood carbohydrates for biofuels and biomaterials as well as invention of intelligent materials by biomimetic engineering. / Vedbildning, eller xylogenes, är en grundläggande mekanism för så skilda områden som industri, boende och en hållbar miljö. Ved består av sekundärt xylem som är starka, stora celler med tjocka cellväggar som är lignifierade. Grunden för de starka cellerna är en avancerad komposit bestående av cellulosafibrer tvärbundna av hemicellulosa och slutligen ingjutet i lignin. Denna fiberkomposit är den sekundära cellväggen i vedartade växter. Celldelning och differentiering regleras genom att sätta igång och stänga av gener. Proteiner som kodas av dessa gener utför de viktigaste funktionerna i cellerna. De styr hela maskineriet som upprätthåller cellernas struktur och funktion, underhåller tillväxt samt tillverkar nödvändiga produkter såsom cellväggskolhydraterna. Här beskriver vi utforskningen av gener och proteiner som är inblandade i xylanbildning liksom utvecklandet av ett modellsystem som kommer vara en hjälp i den funktionella analysen av vedbildning. Xylan är den vanligaste hemicellulosan, eller korsbindande glykanen, i lövträd och därför en av de vanligaste kolhydraterna på jorden. Vi demonstrerar att hybridaspcellkulturer i suspension kan användas som ett modellsystem för sekundär cellväggsbildning. Vi har också undersökt glykosyltransferaser från CAZy-familj 43 som tycks spela en viktig roll i bildandet av sekundär cellvägg. Vi har fokuserat på en av dessa, Pt×tGT43A, en trolig ortolog till Arabidopsis IRX9 som spelar en viktig roll i xylanbildning. Proteinet har uttryckts övergående i Nicotiana benthamiana och dess funktion och lokalisering beskrivs. Dessutom undersöker vi ett glykosidhydrolas, Pt×tXyn10A, involverad i vedbildning. Dess roll är oklar men högst sannolikt modifierar det xylan medan det inkorporeras i sekundära cellväggen efter sekretion från Golgi. Detta influerar interaktionen mellan cellulosa, hemicellulosa och lignin i den slutliga vedcellen. Vi har också klonat en transkriptionsfaktor, Pt×tMYB021, en trolig ortolog till Arabidopsis MYB46 och vi visar att den aktiverar GT43A, GT43B och Xyn10A. Genom analys av promotorsekvenserna har vi identifierat ett CA-rikt motiv förmodat viktigt för xylemspecifika gener.Genom att bemästra proteinerna som är ansvariga för vedbildning får vi verktyg att utveckla skogsproduktsmarknaden. Xylan är en ofantligt stor outnyttjad källa till förnyelsebara kolhydrater. En vision är nya produkter som till exempel snabbväxande träd, ändrade fiberegenskaper, optimerat användande av vedkolhydrater för biobränsle och biomaterial såväl som utvecklandet av intelligenta material genom biomimetisk ingenjörskonst. / QC20100730

Populus

xylan biosynthesis

hemicellulose

glycosyltransferase

GT43

IRX

glycoside hydrolase

GH10

Xyn10A

CAZy

transcription factor

MYB

wood formation

secondary cell wall

Arabidopsis

Molecular biology

Molekylärbiologi

Etude fonctionnelle de trois facteurs de transcription impliqués dans la formation de la paroi secondaire chez le peuplier / Functional study of three transcription factors involved in secondary cell wall formation in poplar

Lakhal, Wassim

18 December 2013

Les facteurs de transcription (FT) de la famille R2R3-MYB chez les plantes jouent un rôle important dans la formation de la paroi secondaire des cellules de bois, que ce soit en activant ou en réprimant leurs gènes cibles au sein d’un réseau régulationnel complexe. Dans ce travail, nous avons utilisé la transgénèse et l’immunoprécipitation de chromatine associée à un séquençage haut-débit (ChIP-SEQ) pour déterminer la fonction de 3 FT R2R3-MYB chez le peuplier. Les peupliers surexprimant MYB090 ont des rayons moins lignifiés ; les tiges présentent une réduction de croissance et de teneurs en lignines. MYB090 régule ses cibles à l’aide d’un motif très conservé, similaire au motif Gamyb. Ses cibles sont impliquées notamment dans la biosynthèse des lignines, cellulose et xylanes, constituants principaux des parois. Les plantes surexprimant MYB221-SRDX et MYB156 présentent une nette réduction de la lignification des parois de leurs fibres, associée à une réduction de croissance. MYB221 semble avoir pour cibles des gènes codant pour des enzymes du métabolisme, ainsi qu’un autre FT de type R2R3-MYB, dont la régulation passe par un motif conservé de type SMRE (Secondary wall MYB-Responsive Element). En conclusion, la combinaison des approches ChIP-SEQ et de transgénèse montre que MYB090 semble être un répresseur transcriptionnel de la lignification, notamment dans les rayons, et de la formation de la paroi secondaire. De même, MYB156 et MYB221 seraient également des répresseurs de la lignification, dans les fibres et les rayons. Cette thèse ouvre des perspectives sur l’établissement de réseaux de régulation transcriptionnelle de la formation de la paroi secondaire. / Plant R2R3-MYB transcription factors (TF) play an important role in secondary cell wall formation in wood cells, by activating or repressing their target genes within a complex regulatory network. Here, we used genetic engineering and chromatin immunoprecipitation technique, associated to next-generation sequencing (ChIP-SEQ) to determine the function of 3 R2R3-MYB TF in poplar. Plants overexpressing MYB090 had less lignified parenchyma rays. The stem growth and total lignin content were reduced. MYB090 regulates target genes through a highly conserved motif, similar to Gamyb. Its target genes are involved in lignin, cellulose and xylan biosynthesis, which are the major components of secondary cell wall. Poplars overexpressing MYB221-SRDX and MYB156 showed a decrease in fiber cell wall lignification, and a reduced growth. MYB221 have targets encoding for metabolic enzymes but also for another R2R3-MYB TF. MYB221 recognizes its target genes, most probably through SMRE (Secondary wall MYB-Responsive Element) conserved motif. In conclusion, the combination of ChIP-SEQ and genetic engineering approaches shows that MYB090 seems to be a transcriptional repressor of lignification, especially in parenchyma rays. MYB156 and MYB221 are also negative regulators of secondary cell wall lignification, in fibers and parenchyma rays. This work opens new avenues on the building of transcriptional regulatory networks involved in secondary cell wall formation.

Facteur de transcription

Lignines

Paroi secondaire

Cellulose

Xylanes

ChIP-SEQ

Peuplier

Transcription factor

Lignins

Secondary cell wall

Cellulose

Xylanes

ChIP-SEQ

Poplar

Advancing understanding of secondary cell wall polymer binding and synthesis in S-layers of Gram-Positive bacteria

Legg, Max

21 April 2022

Self-assembling protein surface layers (S-layers) are ubiquitous prokaryotic cell-surface structures involved in structural maintenance, nutrient diffusion, host adhesion, virulence, and many additional processes, which makes them appealing targets for therapeutics and biotechnological applications, including live vaccines, liposome drug delivery and biosensors. Unlocking this potential requires expanding our understanding of S-layer properties, especially the details of surface-attachment. S-layers of Gram-positive bacteria often are attached through the interaction of specialized S-layer homology (SLH) domain trimers with peptidoglycan-linked secondary cell wall polymers (SCWPs). Characterization of this interaction in the Gram-positive model organism Paenibacillus alvei CCM 2051T reveals that, remarkably, binding-site switches can occur between two distinct SLH-domain SCWP receptor-site grooves in the S-layer protein SpaA, possibly as part of a mechanism to alleviate strain in the S-layer. To date, however, analysis of this novel mechanism has been limited to the terminal SCWP monosaccharide and the internal SCWP repeat disaccharide ligand analogues, leaving open the role of subsequent SCWP sugar residues in binding, as well as whether the two receptor sites are also suited to accommodate longer SCWP ligands that better approximate the biological target at the surface of P. alvei. To address this, the objective of this work aims to uncover and characterize the details of the SpaA SLH-domain (SpaASLH¬) SCWP-interaction by determining the co-crystal structures of SpaASLH¬, and single (SpaASLH/G109A) and the corresponding double (SpaASLH/G46A/G109A) mutants in complex with synthetic terminal disaccharide and trisaccharide analogues of the P. alvei CCM 2051T SCWP target. These structural characterizations have been supplemented with disaccharide and trisaccharide binding data, which was obtained through thermodynamic ITC analyses carried out by collaborators. The co-crystal structures of P. alvei SpaASLH with synthetic, terminal SCWP disaccharide and trisaccharide analogues, together with previously published monosaccharide-bound SpaASLH structures, reveal that while the SLH trimer accommodates longer biologically relevant SCWP ligands within both its primary (G2) and secondary (G1) binding sites, the terminal pyruvylated ManNAc moiety serves as the nearly-exclusive SCWP anchoring point. Binding is accompanied by displacement of a flexible loop adjacent to the receptor site that enhances the complementarity between protein and ligand, including electrostatic complementarity with the terminal pyruvate moiety. Remarkably, binding of the pyruvylated monosaccharide SCWP fragment alone is sufficient to cause rearrangement of the receptor binding sites in a manner necessary to accommodate longer SCWP fragments. The observation of multiple conformations for longer oligosaccharides bound to the protein, together with the demonstrated functionality of two of the three SCWP receptor binding sites, reveals how the SpaASLH-SCWP interaction has evolved to accommodate longer SCWP ligands and alleviate the strain inherent to bacterial S-layer adhesion during growth and division. In addition, to further clarify the steps involved in SCWP biosynthesis, we present a crystal structure of the unliganded UDP-GlcNAc 2-epimerase enzyme MnaA, which catalyzes the interconversion of UDP-GlcNAc into UDP-ManNAc—an essential building block of the P. alvei SCWP target. The P. alvei MnaA epimerase adopts a GT-B fold that is consistent with the architecture of previously published structures of other bacterial non-hydrolyzing UDP-GlcNAc 2-epimerase enzymes for which substrate binding is observed in the cleft located between the two domains. Characterization of this structure, coupled with an analysis of the sequence of the MnaA protein, reveals the presence of conserved residues that define the catalytic and allosteric sites in homologous enzymes from different organisms. These residues are positioned to accommodate substrate within the MnaA binding cleft in much the same manner as the published enzyme homologues, suggesting that allosteric regulation as a mechanism for enzyme regulation is conserved in P. alvei MnaA. These investigations are part of a greater effort toward understanding SLH domain-mediated SCWP-interactions in Gram-positive organisms, and provide insight into the structure and putative function of this SCWP biosynthetic enzyme. By understanding these processes, this knowledge may contribute to providing a platform for the rational design of Gram-positive inhibitors. Such inhibitors could selectively target, for example, the bacterial S-layer SCWP-binding interaction, or perhaps the essential biosynthetic enzymes involved in producing the exclusive targets that these S-layer proteins recognize and bind, and would thus represent a new class of antimicrobial therapeutics. / Graduate

S-layer

SLH domain

Secondary cell wall polymer

X-ray crystallography

Paenibacillus alvei

Cell wall anchoring

UDP-GlcNAc 2-epimerase

MnaA

SCWP

Transcriptional regulation of wood formation in eucalyptus : Role of MYB transcription factors and protein-protein interactions / Régulation transcriptionnelle de la formation du bois chez l'eucalyptus : rôle des facteurs de transcription MYB et des interactions protéines-protéines

Plasencia Casadevall, Anna

15 December 2015

Notre objectif était de mieux comprendre la régulation de la biosynthèse des parois secondaires lors de la formation du bois chez l'Eucalyptus, le feuillu le plus planté au monde et le deuxième dont le génome est séquencé. Nous avons caractérisé trois facteurs de transcription de la famille MYB-R2R3 et montré que EgMYB137 était un nouveau régulateur de la biosynthèse des parois secondaires. Nous avons aussi démontré que l'activité transcriptionnelle de EgMYB1, un répresseur de la biosynthèse des lignines, était régulée par une interaction protéine-protéine impliquant une histone linker (EgH1.3). Enfin, nous avons mis au point une méthode de transformation homologue chez l'Eucalyptus via A. rhizogenes. Les " hairy roots " transgéniques sont adaptées à la caractérisation fonctionnelle de gènes reliés à la formation du xylème. Nos résultats ont permis de découvrir de nouveaux acteurs impliqués dans la régulation des parois secondaires, mettant en lumière la complexité de ce processus mais aussi offrant de nouvelles perspectives pour l'amélioration du bois pour des applications industrielles comme la production de bioéthanol de deuxième génération. / Our objective was to better understand the regulation of the biosynthesis of the lignified secondary cell walls during wood formation in Eucalyptus, the most planted hardwood tree, and the second whose genome has been sequenced. We functionally characterized three Eucalyptus transcription factors of the R2R3-MYB family and identified EgMYB137 as a new regulator of secondary cell wall deposition. We also showed that the transcriptional activity of EgMYB1, a repressor of lignin biosynthesis was modulated by protein-protein interactions involving a linker histone (EgH1.3). Finally, we set up a homologous transformation system for Eucalyptus using Agrobacterium rhizogenes. The transgenic hairy roots are suitable for high throughput functional characterization of cell wall-related genes. Our findings not only allowed getting new insights into the complexity of the network regulating secondary cell walls but also open new avenues to improve wood quality for industrial applications such as second-generation bioethanol.

Eucalyptus

Formation du bois

Xylème

Paroi secondaire

Lignine

Facteurs de transcription MYB

Histone linker

Hairy roots

Métabolites secondaires

Bioéthanol de deuxième génération

Eucalyptus

Wood formation

Xylem

Secondary cell wall

Lignin

MYB transcription factor

Linker histone

Hairy roots

Secondary metabolites

Second-generation bioethanol