Understanding and Engineering Chemically Activated Ubiquitin Ligases for High-throughput Detection, Quantification, and Control of Molecules in Yeast

Chaisupa, Patarasuda

10 June 2024

Fungi, diverse and impactful organisms, exert both beneficial and harmful effects on plants, animals, and humans. Certain fungi produce auxin or indole-3-acetic acid (IAA), a crucial plant growth hormone that influences various aspects of plant growth and defense mechanisms. Conversely, pathogenic fungi can produce auxin and manipulate auxin signaling in their host plant to promote fungal virulence and infection progression. Targeting the auxin signaling pathway in pathogenic fungi offers a novel strategy for combating fungal infections in both plants and humans. Nevertheless, the auxin biosynthesis pathway and the role of auxin in fungal symbioses is not fully understood, in part, due to the lack of a tool for measuring intracellular auxin with high spatial and temporal resolution. This dissertation presents the first genetically encoded biosensor engineered from the E3 ubiquitin ligase to detect and quantify intracellular auxin in a Saccharomyces cerevisiae model. The biosensor has been applied to begin studying auxin metabolism and biosynthesis in yeast as well as better understand the plant auxin co-receptor proteins from which it is built. Additionally, the biosensor is re-engineered for application in inducible protein degradation, controlled by auxin. This tool could be applied to identify novel protein targets for disrupting pathogenic fungal species. Overall, this research offers valuable tool and platform for studying auxin biosynthesis pathway, plant protein and auxin signaling as well as intracellular proteins in fungi. / Doctor of Philosophy / Fungi affect plants, animals, and humans, in both beneficial and harmful ways. Some fungi aid other organisms, while others cause illness. Certain fungi produce a hormone called auxin, or indole-3-acetic acid (IAA), which is essential for plant growth and many environmental responses. Auxin can also assist plants in defending against harmful fungi. Conversely, fungi that infect plants can utilize auxin to promote their own growth and spread. Some fungi even produce auxin, possibly aiding in their colonization of plants. In human fungal infection, it is suggested that auxin may be involved in virulent traits and disease progression. Targeting the auxin signaling pathway in harmful fungi presents an innovative approach to combat fungal infections in both plants and humans. However, our understanding of fungal auxin biosynthesis pathways and their role in fungal infections are not fully understood due to the lack of tools to measure auxin in cells efficiently and accurately. This study introduces the first biological tool, called a biosensor, engineered from auxin responsive proteins from plants, to detect and measure intracellular auxin in Baker's yeast. The biosensor has been used to investigate auxin production by yeast. Additionally, the biosensor has been re-engineered for application in inducible protein degradation, controlled by auxin. This tool could be applied to identify novel protein targets for disrupting pathogenic fungal species. Overall, this research provides useful tool and platform to study auxin production, plant protein function and particular proteins in fungi.

biosensors

F-box protein

auxin

protein degradation

toolkit

metabolic engineering

synthetic biology

Synthetic Auxin Engineering: Building a Biofoundry Platform

Bryant Jr, John Alexander

03 June 2024

Genetic regulatory circuits control metabolism, development, and environmental response across all kingdoms of life. Genetic circuit engineering facilitates sustainable and efficient production of biopharmaceutical, chemical, fiber, and food products that keep humans healthy, nourished, and clothed. However, the complexity of most genetic regulatory circuits, particularly in the context of multicellular eukaryotes, often prevents them from being leveraged as tools or applied technologies with bioeconomic relevance. However, synthetic biology enables the transfer of genes, circuits, networks, and even whole chromosomes between organisms. This approach can be leveraged to port genetic circuits into simple model organisms to control existing and engineer new cellular functions. Still, porting genes to non-native contexts can affect circuit function due to unknown factors. For this reason, iterative design-build-test-learn (DBTL) cycles are necessary for optimizing circuits in new contexts. To facilitate the DBTL cycle, automation approaches can be deployed for streamlining synthetic genetic circuits optimization. Here, I provide a case study for how using synthetic biology and automation – a biofoundry approach – has facilitated engineering of the auxin signaling pathway in a synthetic yeast system. Auxin is a phytohormone involved in nearly every aspect of plant growth and development, and this striking versatility designates it as a target for biotechnology development and a candidate for engineering. First, I provide a literature review of the history of synthetic auxin engineering in yeast, a survey of tools available for expanding yeast synthetic biology, and a summary of applicable automation tools and platforms. Next, I describe and validate a platform called AssemblyTron, which deploys liquid handling robotics for DNA assembly and can serve as the foundation of a biofoundry platform. I then introduce TidyTron, which is a protocol library for automated wash and reuse of single use lab plastics to promote biofoundry sustainability. Next, I expand the AssemblyTron package by providing protocols for mutant and modular indexed plasmid library assembly. Finally, I describe a modular indexed plasmid library (toolkit) for rapid assembly of auxin circuit variants and validate it by building and optimizing an auxin circuit. / Doctor of Philosophy / Genetic mechanisms allow humans, plants, and microbes to grow, breathe, speak, and survive. The DNA that encodes these genetic mechanisms produces protein machines that make chemicals, transfer them, and respond to them in other cells. This process is called signaling, and the protein machines involved make a circuit. In biotechnology, we harness natural genetic circuits to create important products like biopharmaceuticals, food, and clothes. However, the genetic circuits that make valuable proteins/chemicals are usually located on chromosomes along with every other gene involved in building an advanced, multicellular organism (called the genome). Synthetic biology allows us to choose just the DNA that encodes a genetic circuit of interest and put it into the chromosome of a simpler organism with faster growth, smaller genome, etc., which allow us to engineer it more easily. However, transferring a gene circuit to a new organism can cause problems, and it is usually necessary to try many versions of gene circuits to find one that works. Using robots to do synthetic biology can make it faster and less error-prone, which enables more versions of the genetic circuit to be tested. Here, I describe a biofoundry approach where I combined synthetic biology and robotics to speed up the process of building and optimizing the auxin plant hormone signaling pathway. Auxin is a small molecule that plants produce and transfer throughout their leaves, stems, and roots to turn growth on or off (e.g., auxin causes plants to do things like bend towards the sun). I focus on auxin because my goal is to manipulate the auxin pathway to rationally control plant growth. First, I provide a recap of existing work in the field of auxin synthetic biology, tools for transferring auxin circuits into simpler organisms, and available robotics that can speed up auxin synthetic biology. Next, I introduce a software called AssemblyTron, which I developed for building and modifying genes (a process called DNA assembly) with a robot. Next, I discuss how I used the same robot to wash and reuse plastic pipette tips and plates to improve lab sustainability. I then discuss an extended version of AssemblyTron that can be used for more advanced DNA assembly applications like making 10s – 100000s of versions of gene circuits at the same time. Finally, I introduce a collection of auxin circuit DNA parts that can be assembled interchangeably for rapid synthetic auxin engineering.

synthetic biology

liquid handling robotics

lab automation

auxin signaling

modular cloning

sustainability

Molecular Characterization of Arabidopsis thaliana Snf1-Related Kinase 1

Hess, Jenna E.

09 June 2011

Plants have molecular mechanisms for nutrient-related stress responses; however, their exact regulation remains unclear. For example, the integral myo-inositol (inositol) signal transduction pathway allows Arabidopsis thaliana to sense and respond to changes in environmental stimuli, such as water, light availability, and nutrient stress. The inositol signaling pathway relies on dynamic changes in second messenger levels of inositol(1,4,5)P3 (InsP3) and is regulated by myo-inositol polyphosphate 5-phosphatases (5PTases). The 5PTses keep balance between InsP3 signal transduction and termination. Previous work has identified the Sucrose non-fermenting (Snf) 1-related kinase (SnRK1.1) as a binding partner to 5PTase13, a potential InsP3 regulator, and a novel protein called P80, a predicted component of the Cullin4 (CUL4) E3 Ubiquitin ligase complex. In plants, SnRK1.1 is a central integrator of metabolism, stress responses, and developmental signals. Moreover, SnRK1.1 is conserved with the eukaryotic AMP-activated protein (AMPK) and Snf1 kinases—enzymes fundamental to transcriptional regulation and metabolic balance. Studying SnRK1.1 regulation may reveal mechanisms for agricultural sustainability and may offer valuable links to understanding metabolic diseases and lifespan in humans. Therefore, the research presented here centered on characterizing the regulation of SnRK1 gene expression and steady-state protein levels in plants. I show developmental and nutrient-related regulation of spatial expression patterns of SnRK1 genes and SnRK1.1 protein. Further, I present a model for regulation of SnRK1.1 protein stability in vivo based on SnRK1.1 steady-state protein levels in p80 and cul4 co-suppressed (cs) mutants. My results indicate SnRK1.1 regulation is dynamic, and dependent on the timing of particular cues from development and the environment. / Master of Science

transcriptional reprogramming

auxin

stress sensor

nutrient

snrk1

P80

proteasome

inositol signaling

antibody

Arabidopsis thaliana

Functional studies on the transmembrane protein encoded by the TM20 gene in maize / Funktionelle Studien des Transmembranproteins, das codiert wird durch das Gen TM20

Jahrmann, Torben

24 April 2002

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Zea mays

Mais

Auxin

transmembran

dek mutante

Zea mays

maize

auxin

transmembrane

dek mutants

42.59 Botanik: Sonstiges

WVH 000

Studien zur Ansamitocin-Biosynthese sowie Sekundärstoffproduktion durch mikrobielle Interaktion / Investigations on the Biosynthesis of Ansamitocin and Production of Secondary Metabolites by microbial Interaction

Czempinski, Nadine

31 October 2007

No description available.

540 Chemie

Mathematics and Computer Science

Ansamitocin

Biosynthese

PKS

Auxin

Nigericin

Diketide

mikrobielle Interaktion

ansamitocin

biosynthesis

PKS

auxin

nigericin

diketide

microbial interaction

35.50 Organische Chemie: Allgemeines

RA 000: Allgemeine Naturwissenschaften

Leaf margin morphogenesis in crucifer plants

Bilsborough, G. D.

January 2011

A key question in developmental biology is how form is generated. The model species Arabidopsis thaliana produces simple leaves with marginal outgrowths termed serrations. Serration development in A. thaliana requires both the transcription factor CUP-SHAPED COTYLEDON2 (CUC2) and the auxin efflux facilitator PIN-FORMED1 (PIN1), which regulates polar auxin transport by forming convergence points (Hay et al., 2006; Nikovics et al., 2006; Scarpella et al., 2006). In Chapter 3, I investigate how CUC2, PIN1 and auxin interact to control serration development. I demonstrate that CUC2 promotes PIN1 convergence point and auxin activity foci formation along the margin of the leaf, whilst high auxin activity represses CUC2 expression. Furthermore, interspersed peaks of CUC2 and auxin activity pattern serration development along the proximo-distal axis of the leaf. Thus, auxin, PIN1 and CUC2 form a negative feedback loop that patterns serration development. CUC genes and PIN1 are required for leaflet development in Cardamine hirsuta (Barkoulas et al., 2008; Blein et al., 2008), a close relative of A. thaliana that produces compound leaves subdivided into units termed leaflets. However, it is unclear how CUC and PIN1 interact to control leaflet development. In Chapter 4, I demonstrate that similar to A. thaliana, CUC genes promote PIN1 convergence point and auxin activity foci formation at the C. hirsuta leaf margin, whilst high auxin activity represses CUC2 expression. These genetic interactions likely create interspersed peaks of CUC2 and auxin activity that pattern leaflet development. Thus, the same negative feedback loop between CUC, PIN1 and auxin patterns both leaflet development in C. hirsuta and serration development in A. thaliana. KNOTTED1-LIKE HOMEOBOX (KNOX) genes are expressed in C. hirsuta leaves, and interact with ChCUC and PIN1 in positive and negative feedback loops, respectively, to control leaflet development (Barkoulas et al., 2008; Blein et al., 2008). KNOX genes are not expressed in A. thaliana leaves, but deeply lobed margins reminiscent of leaflets develop in association with ectopic KNOX expression in leaves (Chuck et al., 1996; Hay et al., 2006). However, it is unclear whether regulatory interactions of PIN1, CUC and KNOX which occur in C. hirsuta leaflets are employed during KNOX-induced lobe development in A. thaliana. In Chapter 5, I demonstrate that CUC2 and polar auxin transport are required for ectopic KNOX expression. Conversely, I show that KNOX misexpression up-regulates CUC2 expression in A. thaliana leaves. Thus, interactions between KNOX, CUC and PIN1 that occur in leaflet development in C. hirsuta also occur in association with KNOX-induced lobe development in A. thaliana. In addition to investigating the regulatory interactions between known components of leaf development pathways, I sought to identify novel genes that mediate CUC2-dependent serration development in A. thaliana. In Chapter 6, I identify a suppressor of the smooth margin phenotype of cuc2 leaves that partially restores PIN1 localisation in the absence of functional CUC2. Finally, in the General Discussion I evaluate how interlinking feedback loops between CUC, KNOX and auxin pattern serration and leaflet development. I then discuss why interlinking feedback loops may have been deployed to control outgrowths in both plant and animal systems.

581.35

Rôles fonctionnels des gènes CUC et MIR164A au cours du développement foliaire chez Arabidopsis thaliana et sa proche relative Cardamine hirsuta / Functional role of the CUC and MIR164A genes during leaf development of Arabidopsis thaliana and its relative Cardamine hirsuta

Hasson, Alice

04 May 2012

Une grande diversité de formes foliaires caractérise le monde végétal. Cette diversité s'étend des feuilles simples avec des marges lisses aux feuilles composées, avec des marges disséquées. Cependant, les dentelures des marges de ces feuilles simples ou composées se développent en suivant un mécanisme similaire. Ce mécanisme repose sur l'action des gènes NO APICAUX MERISTEM/ CUP-SHAPED COTYLEDONS (NAM/CUC) ainsi que sur la voie auxinique. Chez Arabidopsis, qui possède des feuilles simples, un équilibre entre les expressions de CUC2 et de son répresseur, miR164, est nécessaire au bon développement des dents. Nous avons montré qu'un autre membre de la famille CUC, CUC3, contribue également au développement de ces dents chez Arabidopsis. Bien que son action soit principalement dépendante de CUC2, il agit également plus tard au cours du développement foliaire. En outre, nous avons démontré qu'une boucle de rétro-contrôle entre CUC2 et la voie auxinique permet le développement de dents avec plus ou moins marquées. Nous avons également montré qu'un modèle d'expression temporelle existe entre l'auxine et le module CUC2-miR164. En outre, la production de plantes transgéniques de Cardamine hirsuta, un proche parent d' Arabidopsis, qui possède des feuilles composées, a mis en évidence l'importance des éléments cis-régulateurs dans le promoteur de CUC1 de Cardamine hirsuta. En effet, la divergence de ces éléments cis-régulateurs entre les promoteurs de CUC1 de Cardamine hirsuta et d' Arabidopsis pourrait expliquer que CUC1 soit fortement exprimé dans les feuilles de Cardamine hirsuta alors qu'il est faiblement exprimé dans celles d' Arabidopsis. / A wide diversity of leaf shapes characterises the plant world. This diversity ranges from simple leaves with smooth margins to compound leaves with dissected margins. However, all serrations of simple or compound leaf margins are developed using a similar mechanism. This mechanism includes the action of the NO APICAL MERISTEM/CUP-SHAPED COTYLEDON (NAM/CUC) genes as well as the auxin pathway. In Arabidopsis simple leaves, a balanced expression of CUC2 and its repressor miR164 is controlling the serrations development. We have shown that another member of the CUC family, CUC3, also contributes to the serration development in Arabidopsis simple leaves. While its action is mainly dependent of the one of CUC2, it also acts later during leaf development. Additionally, we have demonstrated that a feed-back loop was regulating the CUC2 and auxin pathways, in order to form leaves with more or less incisions. We also shown that a temporal expression pattern was established between the auxin and the CUC2-miR164 module. Moreover, generation of transgenic Cardamine hirsuta plants, a close relative of Arabidopsis, that possesses compound leaves, has enlighten the importance of cis-regulatory elements in the promoter of CUC1 from Cardamine hirsuta. Indeed, the divergence of cis-regulatory elements between promoters of CUC1 from Cardamine hirsuta and Arabidopsis could explain that CUC1 is expressed strongly in Cardamine hirsuta leaves whereas it is weakly expressed in Arabidopsis leaves.

Forme foliaire

Gènes NAM/CUC

Auxine

Évo-dévo

Cardamine hirsuta

Leaf shape

NAM/CUC genes

Auxin

Evo-devo

Cardamine hirsuta

Análise do papel da via miR156/SQUAMOSA Promoter-Binding Protein-Like (SPL) na organogênese in vitro a partir de raízes de Arabidopsis thaliana / Role of the miR156/SQUAMOSA Promoter-Binding Protein-Like (SPL) pathway in the in vitro shoot regeneration from root of Arabidopsis thaliana

Rocha, Gabriel Henrique Braga

12 April 2016

Os microRNAs (miRNAs) são pequenos RNAs endógenos não codantes de 21-24 nucleotídeos (nt) que regulam a expressão gênica de genes-alvos. Eles estão envolvidos em diversos aspectos de desenvolvimento da planta, tanto na parte aérea, quanto no sistema radicular. Entre os miRNAs, o miRNA156 (miR156) regula a família de fatores de transcrição SQUAMOSA Promoter-Binding Protein-Like (SPL) afetando diferentes processos do desenvolvimento vegetal. Estudos recentes mostram que a via gênica miR156/SPL apresenta efeito positivo tanto no aumento da formação de raízes laterais, quanto no aumento de regeneração de brotos in vitro a partir de folhas e hipocótilos em Arabidopsis thaliana. Devido ao fato de que a origem da formação de raiz lateral e a regeneração in vitro de brotos a partir de raiz principal compartilham semelhanças anatômicas e moleculares, avaliou-se no presente estudo se a via miR156/SPL, da mesma forma que a partir de explantes aéreos, também é capaz de influenciar na regeneração de brotos in vitro a partir de explantes radiculares. Para tanto foram comparados taxa de regeneração, padrão de distribuição de auxina e citocinina, análises histológicas e histoquímicas das estruturas regeneradas em plantas com via miR156/SPL alterada, incluindo planta mutante hyl1, na qual a produção desse miRNA é severamente reduzida. Além disso, foi avaliado o padrão de expressão do miR156 e específicos genes SPL durante a regeneração de brotos in vitro a partir da raiz principal de Arabidopsis thaliana. No presente trabalho observou-se que a alteração da via gênica miR156/SPL é capaz de modular a capacidade de regeneração de brotos in vitro a partir de raiz principal de Arabidopsis thaliana e a distribuição de auxina e citocinina presente nas células e tecidos envolvidos no processo de regeneração. Plantas superexpressando o miR156 apresentaram redução no número de brotos regenerados, além de ter o plastochron reduzido quando comparado com plantas controle. Adicionalmente, plantas contento o gene SPL9 resistente à clivagem pelo miR156 (rSPL9) apresentaram severa redução na quantidade de brotos, além de terem o plastochron alongado. Interessantemente, plantas mutantes hyl1-2 e plantas rSPL10 não apresentaram regeneração de brotos ao longo da raiz principal, mas sim intensa formação de raízes laterais e protuberâncias, respectivamente, tendo essa última apresentado indícios de diferenciação celular precoce. Tomados em conjunto os dados sugerem que o miR156 apresenta importante papel no controle do processo de regeneração de brotos in vitro. Entretanto, esse efeito é mais complexo em regeneração in vitro a partir de raízes do que a partir de cotilédones ou hipocótilos. / MicroRNAs (miRNAs) are endogenous small non-coding RNAs of 21-24 nucleotides (nt) in length that regulate target gene expression. They are involved in many aspects of plant development, both in the shoot and in the root systems. Among miRNAs, miRNA156 (miR156) regulates SQUAMOSA Promoter Binding-Like (SPL) transcription factor family affecting different plant development processes. Recent studies have shown that the miR156/SPL pathway has a positive effect both in the increase of lateral root formation and regeneration of shoots from leaves and hypocotyls in Arabidopsis thaliana. Because the origin of lateral root formation and in vitro shoot regeneration from primary root share similar anatomical and molecular features, in the present study was evaluated whether the miR156/SPL pathway, in the same manner that from aerial explants, is also able to influence the in vitro shoot regeneration from root explants. For this, it was compared regeneration rates, distribution pattern of auxin and cytokinin, histological and histochemical analyses of the structures regenerated in plants in with the miR156/SPL pathway is modified, including the mutant hyl1-1, in which the biosynthesis of this miRNA is severely reduced. Besides that, it was evaluated the expression pattern of miR156 and specific SPL target genes during in vitro shoot regeneration from primary roots of Arabidopsis it was observed that the alteration on the miR156/SPL pathway is capable to modulate in vitro shoot regeneration from the primary root of Arabidopsis and the distribution of auxin and cytokinin at the tissues and cells involved in the regeneration process. Plants overexpressing the miR156a have shown reduction in the number of regenerated shoots, and displayed a reduction in plastochron when compared with wild type plants. Additionally, plants expressing cleavage-resistant form of SPL9 (rSPL9) presented severe reduction in the amount of shoots, and extended plastochron. Interestingly, mutant hyl1-2 and plants rSPL10 did not show any shoot regeneration along the root, but high formation of lateral roots and protuberances, respectively, having rSPL10 presented evidence of precocious cell differentiation. Taken together, these data suggest that de miR156 and SPLs have an important role in the control the in vitro shoot regeneration process. However, its effect is somehow more complex in roots than in cotyledons or hypocotyls.

in vitro shoot regeneration

SPLs

SPLs

Auxin and cytokinin

Auxina e citocinina

Explante radicular

mir156

miR156

Regeneração de brotos in vitro

Root explants

Cultura de tecidos e regeneração de plantas transgênicas a partir de calos embriogênicos e de folhas imaturas de cana-de-açúcar / Plant tissue culture and regeneration of transgenic plants from embryogenic callus and immature leaves of sugarcane

Barbosa, André Luiz

18 May 2010

A cana-de-açúcar é uma monocotiledônea poliplóide, alógama que possui baixa taxa reprodutiva devido a dificuldade de florescimento. Devido estas características genéticas e fisiológicas os programas de melhoramento são longos e laboriosos. Alternativamente, modernas aplicações da biotecnologia visam contribuir com o desenvolvimento de novos cultivares. Neste trabalho estudou-se a metodologia de cultura de tecidos a partir de discos de folhas imaturas para o estabelecimento da cultura de calos embriogênicos e regeneração de plantas a partir dos calos embriogênicos e diretamente, a partir de folhas imaturas. O objetivo principal foi contribuir para o desenvolvimento de métodos eficientes para produção de plantas transgênicas a partir de calos e folhas imaturas, considerando-se a crescente necessidade de produção de novos cultivares com características agronômicas específicas. Diversas concentrações de 2,4-D e cinetina em meio MS foram testadas para o estabelecimento de calos altamente embriogênicos e para a indução da desdiferenciação celular nos discos foliares antecedendo a regeneração de plantas. Meios de cultura sem reguladores de crescimento (MS) e com a adição de BAP e ANA foram testados para a regeneração de plantas a partir de discos foliares. Calos embriogênicos com 12 a 20 semanas de cultivo produziram em média 3 a 5 plantas, em meio de regeneração MS. Folhas imaturas apresentaram elevado potencial de regeneração de plantas quando se utilizou 2,4-D em concentrações de 5 e 8 mg/L nos períodos de 5 e 8 dias no escuro. Houve indução a formação de embriões somáticos que resultaram em média 12 a 16 plantas por explante no período total de 7 a 10 semanas. Além disso, foi testado o pré-tratamento dos discos foliares em meio MS3K, contendo 2,4-D (3mg/L) e cinetina (0,1 mg/L), antes da transferência do discos para meio de regeneração MS. Os discos submetidos a este pré-tratamento durante 14, 21 e 28 dias apresentaram aumento significativo na eficiência de regeneração de plantas, variando em média de 41 a 50 plantas por disco foliar nas variedades RB835089 e RB855156. A redução no tempo para obtenção de plantas aliado ao aumento na média de plantas obtidas é a base para aumentar a eficiência de transformação genética de plantas. Experimentos de cotransformação dos genes neo e comt(AS), foram realizados por biolística. Em plantas regeneradas a partir de folhas imaturas da variedade RB835486, as análises de PCR confirmaram a incorporação do gene marcador neo em 57 e 90% das plantas em meio seletivo com geneticina (30 mg/L), sendo que a maior eficiência de regeneração de transgênicos (90%) foi obtida no pré-tratamento com o meio MS3K. Das plantas transgênicas para o gene neo, 7 e 38% também foram confirmadas para a incorporação do gene comt(AS). Nas plantas regeneradas a partir de calos embriogênicos em meio seletivo, as análises de PCR detectaram somente a incorporação do gene neo, o que ocorreu em 52% das plantas analisadas. Os resultados obtidos mostram que a cultura de discos de folhas imaturas para o processo de transformação genética por biolística é uma metodologia viável, rápida e menos onerosa, quando comparada com a cultura de calos embriogênicos. / Sugarcane is a polyploidy monocot and allogamous species that has low reproductive rate due to the difficulty of flowering. Because of these genetic and physiological characteristics breeding program takes long time and demand hard labor. Alternatively, modern biotechnology approaches contribute to the development of new cultivars. In this work we studied the methodology of plant tissue culture from immature leaf discs to establish callus culture and plant regeneration from those calli and from immature leaves, directly. The main objective was to contribute to the development of efficient methods to produce transgenic plants from callus and immature leaves, due to the growing need to produce new cultivars with specific agronomics traits. MS medium with different concentrations of 2,4-D and kinetin were tested to obtain highly embryogenic calli and to induce cellular dedifferentiation in the immature leaf discs prior to plant regeneration. Culture media without growth regulators (MS) and with the addition of BAP and NAA were tested for plant regeneration from leaf discs. Callus culture with 12 to 20 weeks resulted on average 3 to 5 plants on regeneration medium designed as MS. Immature leaves showed a high potential for plant regeneration when 2,4-D at concentrations of 5 and 8 mg/L in periods of 5 and 8 days in the dark. There were inducing of somatic embryos that resulted in average 12 to 16 plants per explant in the total period of 7 to 10 weeks. In addition, we tested the pre-treatment of leaf discs in MS3K medium which contain 2,4-D (3 mg/L) and kinetin (0.1 mg/L) before transfering to plant regeneration MS medium . The discs submitted to this pretreatment for 14, 21 and 28 days showed significant increase in the efficiency of plant regeneration, with on average of 41 to 50 plants per leaf disc in varieties RB835089 and RB855156. The reduction of time to obtain plants coupled with the increase of plants obtained is the basis for increasing the efficiency of plant genetic transformation. Co-transformation with genes neo and comt(AS), were performed by biolistics. Plants regenerated from immature leaves of the variety RB835486, PCR analysis confirmed the incorporation of the neo selection marker gene in 57 and 90% of the plants on selective medium with geneticin (30 mg/L), the higher efficiency of transgenic plants (90%) was obtained on pre-treatment in MS3K medium. Transgenic plants for the neo gene, 7 and 38% were also confirmed for the incorporation of comt (AS). PCR analysis of candidates transgenic plants from callus growing on selective medium, revelled only the insertion of the neo gene, which occurred in 52% of the analyzed plants. The results of this work showed that the approach of using immature leaf discs to obtain plant genetic transformation by biolistics methodology is a viable, cheaper and faster than using embryogenic callus.

Auxin

Biolística

Biolistics.

Caffeic acid-O-methyltransferase

Cana-de-açúcar

COMT

Cotransformation

Cytokinin

Genes

Growth regulators

Polimorfismo

Reguladores de crescimento vegetal.

Flower evolution in species of Croton L. (Euphorbiaceae): ontogeny and global profile of gene expression / Evolução floral em espécies de Croton L. (Euphorbiaceae): ontogênese e perfil global da expressão gênica

Gagliardi, Karina Bertechine

27 July 2018

The Euphorbiaceae are notable for floral and inflorescence diversity and evolutionary complexity. Croton, is the second largest genus in the family and exhibits particular diversity in its flowers, especially regarding perianth and number of stamens, besides the inflorescences, which are also very diverse. Considering Croton\'s great variability in the reproductive structures, the aim of this thesis was to study flowers and inflorescences with an evolutionary approach, including morphology, ontogeny, vasculature, auxin regulation and genetic expression. Flowers in several stages of development were analyzed using light microscopy and scanning electron microscopy. Inflorescences were analyzed in stereomicroscope and the traits were plotted on the most recent phylogeny of the genus. The genetic expression was tested using RNAseq. In the first chapter the flowers showed similarity in the initiation of sepals and the presence of filamentous, petaloid structures in Croton lundianus (Didr.) Müll. Arg., interpreted here as staminodes. In Croton sphaerogynus Baill., staminodes were described for the first time. The staminodes reported here could be interpreted as transitional structures that we considered as evolutionary reductions. In the second chapter, the staminate flowers showed polystemonous androecium and the delay in petals\' initiation and the antesepalous nectaries development interfered in the development of the stamens, characterizing obdiplostemony. Vasculature corroborated obdiplostemony and revealed a central stamen in C. fuscescens with carpelar features, interpreted here as a homeosis case. Glandular staminodes were registered and interpreted as a heterotopy case. The obdiplostemony may be related to modulation of the free IAA concentrations during floral developmental steps and Croton flowers can be used as good models for obdiplostemony, homeosis and heterotopy. In the third and fourth chapter we studied Croton inflorescences, which showed 17 patterns with differences on the organization and distribution of pistillate flowers. The inflorescence traits analyzed were very homoplastic, most likely determined by convergent evolution in distantly related lineages distributed in similar habitats. The genetic expression of C. fuscescens was particularly analyzed and the transcriptome showed that the different zones have their development guided through the same transcripts set. Each zone has different expression level and these variations and gradient could be interpreted as the boundary between each inflorescence zone. The floral developmental novelties and evolutionary links identified here raise the importance of future floral studies with the genus, what would bring a better understanding on how the reproductive structures evolved in the history of the group / Euphorbiaceae é uma família que recebe destaque quanto à diversidade de flores e inflorescências, além de sua complexidade evolutiva. Croton L. é o segundo maior gênero da família e exibe particular diversidade floral, em especial quanto a o perianto e número de estames, além das inflorescências, que também se apresentam muito diversas. Considerando a grande variação nas estruturas reprodutivas de Croton, o objetivo desta tese foi estudar as flores e inflorescências com abordagem evolutiva, incluindo morfologia, ontogênese, vascularização, regulação hormonal e expressão gênica. Flores em diversos estágios de desenvolvimento foram analisadas em microscopia der luz e varredura. Inflorescências foram estudadas em estereomicroscópio e os caracteres observados foram analisados nas filogenias mais recentes do grupo. A expressão gênica foi analisada com a técnica RNAseq. No primeiro capítulo as flores apresentaram semelhanças na iniciação das sépalas e presença de filamentos, estruturas petaloides em Croton lundianus (Didr.) Müll. Arg., interpretadas como estaminódios. Em Croton sphaerogynus Baill., estaminódios foram descritos pela primeira vez. Estas estruturas podem ser interpretadas como estruturas de transição evolutiva e reduções florais. No segundo capítulo as flores estaminadas apresentaram androceu polistêmone e o retardo na iniciação das pétalas e o desenvolvimento antessépalo dos nectários foram considerados como fatores chave para o desenvolvimento do androceu como obdiplostêmone. A vascularização corroborou a obdiplostemonia e revelou um estame central com características carpelares em C. fuscescens, interpretado aqui como um caso de homeose. Nectários glandulares foram registrados e interpretados como uma mudança heterotópica. A obdiplostemonia pode estar relacionada com as diferentes concentrações de auxina ao longo das etapas de desenvolvimento e as flores de Croton podem ser consideradas como bons modelos de obdiplostemonia, homeose e heterotopia. No terceiro e quarto capítulo nós investigamos as inflorescências de Croton, que apresentaram 17 padrões com diferenças na organização e distribuição das flores pistiladas especialmente. Os caracteres das inflorescências se mostraram homoplásticos e provavelmente determinados por evolução convergente em linhagens distantes distribuídas em habitats semelhantes. A expressão gênica de C. fuscescens foi particularmente analisada e o transcriptoma demonstrou que o desenvolvimento das diferentes zonas é regulado pelo mesmo conjunto gênico. Cada zona, pistilada ou estaminada, apresenta níveis distintos de expressão diferencial e o gradiente na expressão pode ser o delimitador entre as zonas. Os novos relatos quanto ao desenvolvimento floral em Croton e os links evolutivos identificados nesta tese levanta a importância de estudos para uma melhor compreensão sobre a evolução das estruturas reprodutivas neste grupo tão importante

Auxin

Desenvolvimento floral

Estaminódio

Estruturas reprodutivas

Flower development

Nectário

Nectary

Reproductive structure

RNAseq

RNAseq

Staminodes

Vascularização

Vasculature