Liverwort control in container-grown nursery crops

Newby, Adam Franklin,

January 2006

Thesis(M.S.)--Auburn University, 2006. / Abstract. Vita. Includes bibliographic references.

Evolution of bHLH transcription factors that control epidermal cell development in plants

Catarino, Bruno

January 2017

The colonization of the arid continental surface by plants was one of the milestones in Earth's history. Morphological innovations, such as the origin of complex 3D tissues, allowed the successful colonization and radiation of plants on land. The epidermis is the outermost plant tissue that constitutes the interface between the plant and the environment. Thus, the evolution of epidermal cells was crucial for the adaptation of plants on the terrestrial arid environment. I undertook a combined approach that aims to understand the evolutionary trends that drove land plant colonization and the genetic mechanisms that underlie the development of the epidermis. This approach includes: 1) analyses of plant transcription factors (TFs) families distribution and diversification, with a particular focus on the basic Helix-Loop-Helix (bHLH) TF family, and 2) functional characterization of a putatively conserved bHLH TF subfamily involved in epidermal cell development in land plants. Here, I showed that there was a stepwise increase in the number of transcription factor (TF) families and bHLH subfamilies that predated the colonization of the terrestrial surface by plants. The subsequent increase in TF number on land was through duplication within pre-existing TF families and subfamilies. Moreover, a similar trend occurred in metazoan bHLH TF, suggesting that the majority of innovation in plant and metazoan TF families occurred in the Precambrian before the Phanerozoic radiation of land plants and metazoans. Furthermore, I demonstrated that the function of IIIf bHLH TFs in controlling the development of the epidermal cell layer is conserved between liverworts and angiosperms. This suggests that IIIf bHLH TFs are ancient and conserved regulators of epidermal cell development since the early colonization of the land by plants. Moreover, these bHLH TFs were recruited during the evolution of land plants to control the development of seemingly unrelated morphological characters in specific lineages of extant land plants. The recruitment of ancient developmental regulators to control distinct and unrelated developmental processes in land plants might underlie the huge morphological and taxonomic radiation of plants on land.

Exploring the biosynthesis and physiological function of gibberellin-related compounds in the liverwort Marchantia polymorpha / 苔類ゼニゴケにおけるジベレリン関連化合物の生合成と生理機能に関する研究

SUN, Rui

24 November 2023

京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24982号 / 生博第511号 / 新制||生||68(附属図書館) / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授 河内 孝之, 教授 荒木 崇, 教授 中野 雄司 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

Land plant evolution

Marchantia polymorpha

Gibberellin biosynthesis

Far-red light response

460

The Impact of Abiotic Stress on Alternative Splicing in Lipid Transfer Protein in Marchantia polymorpha

Fredén, Linnéa

January 2018

All plants have a protection against the surrounding environment called a cuticle coating. When this cuticle coating is constructed it is believed that the family of protein called lipid transfer proteins (LTPs) is involved. The LTPs are small and cysteine rich. In Marchantia polymorpha the groups of LTPs called LTPd and LTPg can be found. 8 and 4 in each group respectively. In the genes of LTPd there is an intron placed downstream of the start codon. Firstly, a sequence database search was performed and LTPd2 and LTPd3 were chosen for further experiments in this study. Secondly, a control that the intron was present in the samples were done by preforming a PCR reaction of cDNA from isolated RNA taken from untreated Marchantia polymorpha. A gel electrophoresis of the product was also performed. Lastly, the amount of alternative splicing in LTPd2 and LTPd3 from Marchantia polymorpha after treated with cold and dehydration were studied using quantitative PCR. For the qPCR MpACT and the exon of respective gene were used as references. The ΔCt values and the expression fold (2ΔΔCt) calculated from the qPCR results showed that most of the transcript with introns preserved were upregulated after subjected to stress. Only the intron in MpLTPd2 and MpLTPd3 with MpACT as reference showed a small downregulation after the cold treatment. The intron in MpLTPd3 with MpLTPd3s exon as reference didn’t show any difference. None of the intron transcript in any of the genes on the other hand showed any significant difference in the alternative splicing. This could be because of small sample groups when the test was performed. In conclusion, there were no significant difference in intron expression between treated and control samples. Therefore, nothing can be said about the change in alternative splicing in MpLTPds after cold and dehydration treatments.

Abiotic stress

Marchantia polymorpha

alternative splicing

intron

non-specific lipid transfer proteins

drought

cold

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

The Effects of Abiotic Stress on Alternative Splicing in Non-specific Lipid Transfer Proteins in Marchantia polymorpha

Ahlsén, Hanna

January 2018

Due to global warming, our planet will experience more extreme weather conditions. Plants can protect themselves against these abiotic stress conditions with their stress response, which includes alternative splicing of certain genes. Alternative splicing is a post-transcriptional process where a single gene gives rise to different mRNAs, which in turn produces different proteins. In plants, this is usually done by intron retention. One type of protein that may be involved in this stress response are the non-specific lipid transfer proteins (LTPs). Indeed, evidence of intron retention has been found in the LTP genes in the liverwort Marchantia polymorpha, called MpLTPd. To investigate whether this alternative splicing is caused by abiotic stress or not, I subjected the moss to two different types of stress trials, drought and cold, and compared the general expression of the intron in MpLTPd2 and MpLTPd3 from the stressed samples to samples from a moss grown under normal conditions. I found that the expression of the intron did change in the stressed moss, but none of the differences were significant. This suggests that alterative splicing in MpLTPd2 and MpLTPd3 is not caused by cold and drought and that the intron-containing protein plays no role in the protection of M. polymorpha against abiotic stress.

abiotic stress

alternative splicing

cold

drought

Marchantia polymorpha

non-specific lipid transfer proteins

LTP

Biological Sciences

Biologiska vetenskaper

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Frameworks for reprogramming early diverging land plants

Pollak Williamson, Bernardo

January 2018

Plant form is a product of emergent processes of cell division, patterning and morphogenesis. These fundamental processes remain poorly characterised in plants. However, engineering approaches can provide new tools and frameworks for the study and manipulation of plant development. This dissertation describes the development of engineering frameworks for reprogramming of the early diverging land plant Marchantia polymorpha (Marchantia). I describe the generation of genomic and transcriptomic datasets for Marchantia, which has provided the basis for the compilation of a gene-centric registry of DNA parts for engineering (MarpoDB). I describe the development of Loop assembly, an efficient and standardised DNA assembly system based on Type IIS restriction enzymes for recursive fabrication of DNA circuits with high efficiency. MarpoDB was used to mine new DNA parts compatible with Loop assembly which were used to generate plant transformation vectors for labelling of cellular features to study aspects of growth and development. I performed image analysis of genetic markers for segmentation and quantification of cellular properties in germinating gemmae. I implemented high-efficiency Cas9-mediated mutagenesis in Marchantia for use in functional molecular genetics studies. Furthermore, I produced inducible systems for expression of heterologous elements by transactivation which showed negligible levels of basal activity. It was possible to use this system for induction of gene expression in single cells. Finally, these new frameworks were applied to study the gametophytic meristem in Marchantia gemmae. I mapped the expression of several putative candidate homologues for higher plant meristem regulators, performed overexpression and loss-of-function studies for homologues of WUSCHEL, CLAVATA3 and SHOOT MERISTEMLESS. A strategy for misregulation of endogenous genes was developed using inducible transactivation, and was used with cellular markers for WUSCHEL and CLAVATA3 homologues in Marchantia.

Ancestral Functions of DELLA Proteins

Hernández García, Jorge

16 July 2021

[ES] Las plantas necesitan acomodar su crecimiento a las condiciones ambientales. Con el objetivo de ajustar su desarrollo a las señales externas, usan una serie de mecanismos moleculares. Uno de estos son las rutas de señalización hormonal, que participan en integrar la información externa con programas de desarrollo propios. Una de las hormonas más relevantes en la biología vegetal son las giberelinas (GAs). La señalización por GAs se inicia con la percepción de la hormona a través del receptor GID1, y continúa por la degradación de las reguladoras transcripcionales DELLA. Sin embargo, solo las plantas vasculares tienen un sistema de percepción de GAs completo. Entender la relevancia de la señalización por GAs requiere estudiar cómo se ensambló la ruta y qué funciones atribuidas a las GAs estaban ya codificadas en las proteínas DELLA ancestrales. Aquí mostramos mediante análisis filogenéticos y bioquímicos que las proteínas DELLA emergieron inequívocamente en un ancestro común de las plantas terrestres, y que el reclutamiento de las DELLAs al módulo de percepción de GAs depende de la presencia de un dominio de transactivación conservado que fue co-optado por el receptor GID1 ancestral para actuar como un degrón dependiente de GAs. Este dominio de transactivación parece regular la co-activación transcripcional de genes concretos por las DELLAs en todas las plantas terrestres mediante el reclutamiento de complejos Mediator a través de su subunidad MED15. Por último, nos hemos centrado en entender las funciones de las proteínas DELLA en briófitas, un clado sin señalización por GAs. Hemos descubierto el rol de la DELLA de Marchantia polymorpha como coordinadora entre las respuestas de crecimiento y estrés, sugiriendo que dicha función estaba ya codificada en proteínas DELLA del ancestro común de plantas terrestres y se ha mantenido durante más de 450 millones de años. / [CA] Les plantes necessiten acomodar el seu creixement a les condicions ambientals. Amb l'objectiu d'ajustar el seu desenvolupament als senyals externs, usen una sèrie de mecanismes moleculars. Un d'aquests són les rutes de senyalització hormonal, que participen en integrar la informació externa amb programes de desenvolupament propis. Una de les hormones més rellevants en la biologia vegetal són les giberel·lines (GAs). La senyalització per GAs s'inicia amb la percepció de l'hormona a través del receptor GID1, i continua per la degradació de les reguladores transcripcionals DELLA. No obstant això, només les plantes vasculars tenen un sistema complet de percepció de GAs. Entendre la rellevància de la senyalització per GAs requereix estudiar com es va assemblar la ruta i quines funcions atribuïdes a les GAs estaven ja codificades en les proteïnes DELLA ancestrals. Ací mostrem mitjançant anàlisis filogenètiques i bioquímiques que les proteïnes DELLA van emergir inequívocament en un ancestre comú de les plantes terrestres, i que el reclutament de les DELLAs al mòdul de percepció de GAs depén de la presència d'un domini de transactivació conservat que va ser co-optat pel receptor GID1 ancestral per a actuar com un degró dependent de GAs. Aquest domini de transactivació sembla regular la co-activació transcripcional de gens concrets per les DELLAs en totes les plantes terrestres mitjançant el reclutament de complexos Mediator a través de la seua subunitat MED15. Finalment, ens hem centrat en entendre les funcions de les proteïnes DELLA en briòfites, un clade sense senyalització per GAs. Hem descobert el rol de la DELLA de Marchantia polymorpha com a coordinadora entre les respostes de creixement i estrés, suggerint que aquesta funció estava ja codificada en proteïnes DELLA de l'ancestre comú de plantes terrestres i s'ha mantingut durant més de 450 milions d'anys. / [EN] Plants need to accommodate their growth habits to environmental conditions. For this aim, several mechanisms are used to adjust developmental responses to exogenous signals. Among them, hormonal signalling pathways participate by integrating external information with endogenous programs. One of the most relevant hormones in plant biology are gibberellins (GAs). GA signalling involves perception of the hormone by the GA receptor GID1 and subsequent degradation of the DELLA transcriptional regulators. However, only vascular plants possess a full GA perception system. Understanding the relevance of GA signalling requires elucidating how this pathway was assembled and which of the functions attributed to GAs were encoded in the ancestral DELLA proteins. Here we show by phylogenetic and biochemical analyses that DELLA proteins emerged unequivocally in a land plant common ancestor and that their recruitment into the GA-perception module relies in the presence of a conserved transactivation domain co-opted by an ancestral GID1 receptor to act as a GA-dependent degron. Moreover, this transactivation domain seems to regulate DELLA-dependent transcriptional co-activation of selected target genes by recruitment of Mediator complexes through the MED15 subunit in all land plants. Finally, we have focused on understanding the functions of DELLA proteins in bryophytes, a clade with no GA signalling. We have uncovered the role of Marchantia polymorpha DELLA protein as a coordinator between growth and stress responses, suggesting that this function was already present in the DELLA protein of a land plant common ancestor and has been maintained for over 450 millions of years. / La realización de esta tesis doctoral ha sido posible gracias a una ayuda para contratos predoctorales FPU (FPU15/01756), dos Ayudas para Estancias Breves FPU (EST17/00237, IPS2, París; EST18/00400, WUR, Wageningen), una ayuda EMBO Short-Term (ASTF 8239, WUR, Wageningen), y la financiación MSCA H2020 RISE para desplazamientos en el contexto del proyecto SIGNAT (RISE Action 644435, PUC, Santiago). Así mismo, el grueso del trabajo experimental incluido ha sido financiado por el proyecto HUBFUN del MINECO (BFU2016-80621-P) / Hernández García, J. (2021). Ancestral Functions of DELLA Proteins [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/169370

Respuesta al estrés

Desarrollo vegetal

Proteínas DELLA

Señalización hormonal

Factor de transcripción

Marchantia polymorpha

Señalización de plantas

Giberelinas

Plant signaling

Stress responses

Gibberellins

Plant development

Mediator complex

DELLA proteins

Hormone signaling

Transcription factor

Origin & Evolution of the C3HDZ-ACL5-SACL Regulatory Module in Land Plants

Solé Gil, Anna

07 September 2023

[ES] El correcto desarrollo de tejidos vasculares depende del ajuste preciso entre la proliferación de células vasculares y la diferenciación celular. En Arabidopsis thaliana, la proliferación de células vasculares en el cambium es potenciada por la citoquinina, la síntesi de la cual está promovida por la actividad dependiente de auxina de un heterodímero de factores de transcripción (TF) formado por LONESOME HIGHWAY (LHW) y por TARGET OF MONOPTEROS 5 (TMO5). Como mecanismo de seguridad, las auxinas también activan un módulo inhibidor que implica la inducción precisa de la Termospermina (Tspm) sintasa ACAULIS5 (ACL5) en células vasculares proliferantes por acción conjunta de las auxinas y del TF Class III HD-ZIP (C3HDZ) AtHB8. Entonces, la Tspm permite la traducción de las proteínas SACL de forma celular autónoma, que perjudican la actividad de LHW. Sin embargo, la observación de que estos elementos están presentes en los genomas de todas las plantas terrestres - y no sólo de las plantas vasculares - plantea dos preguntas desde una perspectiva evolutiva: (i) ¿cuál es la función de estos genes en las plantas terrestres no vasculares? y (ii) ¿cuándo se creó el módulo regulador concreto? En esta Tesis, mediante la combinación de análisis filogenéticos, celulares y moleculares con la hepática Marchantia polymorpha, proponemos que la auxina y C3HDZ son reguladores ancestrales de la expresión de ACL5, y que esta conexión se mantiene en las traqueófitas y las briófitas existentes. Por el contrario, la traducción dependiente de Tspm de SACL parece ser específica de las traqueófitas, basado en la aparición de un uORF conservado en la secuencia 5' líder de los tránscritos de SACL y en evidencia experimental basada en ensayos transitorios para la traducción de SACL. De acuerdo con estas observaciones, las funciones de MpACL5 y MpSACL son diferentes en M. polymorpha. MpACL5 se expresa en "notches" apicales y modula la bifurcación de los meristemos. Por otro lado, la expresión de MpSACL está mayoritariamente excluida de los "notches" apicales y su actividad afecta negativamente la producción de gemas y rizoides mediante la interacción con MpRSL1. Finalmente, la hibridación de ARN in situ de ortólogos de C3HDZ, ACL5 y SACL en la gimnosperma Ginkgo biloba, el helecho Ceratopteris richardii y la licófita Selaginella kraussiana indican que la expresión de los tres genes se solapa en los tejidos vasculares. Nuestros resultados sugieren que la función de C3HDZ, ACL5 y SACL ha seguido trayectorias evolutivas divergentes en briófitas y traqueófitas, para controlar, finalmente, diferentes funciones específicas dentro de cada linaje. Sólo en las traqueófitas se formó el módulo regulador y se asoció con la restricción de la proliferación de células vasculares. / [CA] El correcte desenvolupament dels teixits vasculars depèn del precís ajust entre la proliferació de cèl·lules vasculars i la diferenciació cel·lular. En Arabidopsis thaliana, la proliferació de cèl·lules vasculars al càmbium és potenciada per la citoquinina, la síntesi de la qual està promoguda per l'activitat dependent d'auxina d'un heterodímer de factors de transcripció (TF) format per LONESOME HIGHWAY (LHW) i TARGET OF MONOPTEROS 5 (TMO5). Com a mecanisme de seguretat, l'auxina també activa un mòdul inhibidor que implica la inducció precisa de la Termospermina (Tspm) sintasa ACAULIS5 (ACL5) en cèl·lules vasculars proliferants per l'acció conjunta de l'auxina i del TF Class III HD-ZIP (C3HDZ) AtHB8. Llavors, la Tspm permet la traducció de les proteïnes SACL de forma autònoma cel·lular, que perjudiquen l'activitat de LHW. Tanmateix, l'observació de que aquests elements estan presents en els genomes de totes les plantes terrestres - i no només de les plantes vasculars - planteja dues preguntes des d'una perspectiva evolutiva: (i) quina és la funció d'aquests gens en les plantes terrestres no vasculars? i (ii) quan es va crear el mòdul regulador complet? En aquesta Tesi, mitjançant la combinació d'anàlisis filogenètics, cel·lulars i moleculars amb la hepàtica Marchantia polymorpha, proposem que l'auxina i C3HDZ són reguladors ancestrals de l'expressió d'ACL5, i que aquesta connexió es mantén en els traqueòfits i briòfits existents. Per contra, la traducció depenent de Tspm de SACL sembla ser específica dels traqueòfits, basat en l'aparició d'un uORF conservat a la seqüència 5' líder dels trànscrits de SACL i en evidència experimental basada en assajos transitoris per a la traducció de SACL. D'acord amb aquestes observacions, les funcions de MpACL5 i MpSACL són diferents a M. polymorpha. MpACL5 s'expressa en "notch" apicals i modula la bifurcació dels meristems. D'altra banda, l'expressió de MpSACL està majoritàriament exclosa dels "notch" apicals i la seva activitat afecta negativament la producció de gemmes i rizoids mitjançant la interacció amb MpRSL1. Finalment, la hibridació d'ARN in situ d'ortòlegs de C3HDZ, ACL5 i SACL a la gimnosperma Ginkgo biloba, la falguera Ceratopteris richardii i el licòfit Selaginella kraussiana indica que l'expressió dels tres gens es solapa als teixits vasculars. Els nostres resultats suggereixen que la funció de C3HDZ, ACL5 i SACL va seguir trajectòries evolutives divergents en briòfits i traqueòfits, per controlar, finalment, diferents funcions específiques dins de cada llinatge. Només en els traqueòfits es va formar el mòdul regulador i es va associar amb la restricció de la proliferació de cèl·lules vasculars. / [EN] The correct development of vascular tissues depends on the precise adjustment between vascular cell proliferation and cell differentiation. In Arabidopsis thaliana, vascular cell proliferation in the cambium is enhanced by cytokinin, whose synthesis is promoted by the auxin-dependent activity of a transcription factor (TF) heterodimer formed by LONESOME HIGHWAY (LHW) and TARGET OF MONOPTEROS 5 (TMO5). As a safety mechanism, auxin also deploys a negative feedforward regulatory module which involves the precise induction of the Thermospermine (Tspm) synthase ACAULIS5 (ACL5) in proliferating vascular cells by the joint action of auxin and the class-III HD-ZIP (C3HDZ) AtHB8 TF. Tspm then allows the cell-autonomous translation of the SACL proteins, which impair the activity of LHW. However, the observation that these elements are present in the genomes of all land plants -and not only vascular plants- poses two questions from an evolutionary perspective: (i) what is the function of these genes in non-vascular land plants? and (ii) when was the full regulatory module assembled? In this Thesis, through the combination of phylogenetic, cellular, and molecular genetic analyses with the liverwort Marchantia polymorpha, we propose that auxin and C3HDZ are ancestral regulators of ACL5 expression, and that this connection is maintained in extant tracheophytes and bryophytes. On the contrary, thermospermine-dependent translation of SACL seems to be specific of tracheophytes, based on the appearance of a conserved uORF in the 5' leader sequence of SACL transcripts and on experimental evidence using transient assays for SACL translation. In agreement with these observations, the functions of MpACL5 and MpSACL are different in M. polymorpha. MpACL5 is expressed in apical notches and modulates meristem bifurcation. On the other hand, MpSACL expression is mostly excluded from apical notches and its activity negatively affects gemmae and rhizoid production through the interaction with MpRSL1. Finally, in situ RNA hibridization of C3HDZ, ACL5 and SACL orthologs in the gymnosperm Ginkgo biloba, the fern Ceratopteris richardi and the lycophyte Selaginella kraussiana indicates that the expression of the three genes overlaps in vascular tissues. Our results suggest that the function of C3HDZ, ACL5 and SACL followed divergent evolutionary trajectories in bryophytes and tracheophytes, to ultimately control different lineage-specific functions. Only in tracheophytes was the regulatory module assembled and associated with the restriction of vascular cell proliferation. / Solé Gil, A. (2023). Origin & Evolution of the C3HDZ-ACL5-SACL Regulatory Module in Land Plants [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/196681

ACAULIS5 (ACL5)

Plantas terrestres

Plantas vasculares

Briofitas

Termospermina

Desarrollo vascular

Xilema

Biología molecular

Biotecnología

Red de regulación génica

Auxina

Citoquinina

Poliaminas

Evolution

Land Plants

Vascular Plants

Bryophytes

C3HDZ

SACL

Thermospermine

Marchantia polymorpha

Arabidopsis thaliana

Ginkgo biloba

Ceratopteris richardii

Selaginella kraussiana

Vascular development

Xylem

Molecular Biology

Biotechnology

Gene regulatory network

Auxin

Cytokinin

Polyamines

upstream Open Reading Frame (uORF)

FISIOLOGIA VEGETAL

Gene expression control for synthetic patterning of bacterial populations and plants

Boehm, Christian Reiner

January 2017

The development of shape in multicellular organisms has intrigued human minds for millenia. Empowered by modern genetic techniques, molecular biologists are now striving to not only dissect developmental processes, but to exploit their modularity for the design of custom living systems used in bioproduction, remediation, and regenerative medicine. Currently, our capacity to harness this potential is fundamentally limited by a lack of spatiotemporal control over gene expression in multicellular systems. While several synthetic genetic circuits for control of multicellular patterning have been reported, hierarchical induction of gene expression domains has received little attention from synthetic biologists, despite its fundamental role in biological self-organization. In this thesis, I introduce the first synthetic genetic system implementing population-based AND logic for programmed hierarchical patterning of bacterial populations of Escherichia coli, and address fundamental prerequisites for implementation of an analogous genetic circuit into the emergent multicellular plant model Marchantia polymorpha. In both model systems, I explore the use of bacteriophage T7 RNA polymerase as a gene expression engine to control synthetic patterning across populations of cells. In E. coli, I developed a ratiometric assay of bacteriophage T7 RNA polymerase activity, which I used to systematically characterize different intact and split enzyme variants. I utilized the best-performing variant to build a three-color patterning system responsive to two different homoserine lactones. I validated the AND gate-like behavior of this system both in cell suspension and in surface culture. Then, I used the synthetic circuit in a membrane-based spatial assay to demonstrate programmed hierarchical patterning of gene expression across bacterial populations. To prepare the adaption of bacteriophage T7 RNA polymerase-driven synthetic patterning from the prokaryote E. coli to the eukaryote M. polymorpha, I developed a toolbox of genetic elements for spatial gene expression control in the liverwort: I analyzed codon usage across the transcriptome of M. polymorpha, and used insights gained to design codon-optimized fluorescent reporters successfully expressed from its nuclear and chloroplast genomes. For targeting of bacteriophage T7 RNA polymerase to these cellular compartments, I functionally validated nuclear localization signals and chloroplast transit peptides. For spatiotemporal control of bacteriophage T7 RNA polymerase in M. polymorpha, I characterized spatially restricted and inducible promoters. For facilitated posttranscriptional processing of target transcripts, I functionally validated viral enhancer sequences in M. polymorpha. Taking advantage of this genetic toolbox, I introduced inducible nuclear-targeted bacteriophage T7 RNA polymerase into M. polymorpha. I showed implementation of the bacteriophage T7 RNA polymerase/PT7 expression system accompanied by hypermethylation of its target nuclear transgene. My observations suggest operation of efficient epigenetic gene silencing in M. polymorpha, and guide future efforts in chassis engineering of this multicellular plant model. Furthermore, my results encourage utilization of spatiotemporally controlled bacteriophage T7 RNA polymerase as a targeted silencing system for functional genomic studies and morphogenetic engineering in the liverwort. Taken together, the work presented enhances our capacity for spatiotemporal gene expression control in bacterial populations and plants, facilitating future efforts in synthetic morphogenesis for applications in synthetic biology and metabolic engineering.

572.8