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1	A study of the sporangia and gametophytes of Selaginella apus and Selaginella rupestris ... Lyon, Florence May. January 1901 (has links) Thesis (Ph. D.)--University of Chicago. / From the Botanical gazette, Aug., Sept., 1901. Bibliography: p. 186-187. Selaginella. Plant embryology.
2	Zur Biologie von Selaginella Seyd, Willy. January 1910 (has links) Inaugural dissertation (Ph. D.)--Universität Jena. / Includes bibliographical references.
3	Growth and development of the megagametophyte of the vascular plant Selaginella (Lycopsida) on defined media Koller, Alan Leonard January 1982 (has links) Megagametophytes of the heterosporous lower vascular plant, Selaginella, were cultured on a variety of types and concentrations of carbon sources (glucose, sucrose, trehalose, and sorbitol), with and without B vitamins, in an attempt to induce apogamy. Without B vitamins growth was enhanced on glucose and trehalose, but not on sucrose. With B vitamins growth was enhanced on all types and concentrations of carbon sources. Enhanced growth involved the production of greater numbers of cells in the tissue. Chlorophyll-a was present in megagametophytes cultured on many of the treatments, including control treatments without supplemental carbon. Apogamy was not induced. / Master of Science LD5655.V855 1982.K675 Selaginella
4	Leaf Morphology of Selaginella P. Beauv. and its Taxonomic Significance in Taiwan Chao, Shu-chih 29 July 2008 (has links) Microphyll morphology of 16 Taiwanese species of Selagienlla was observed under light microscopy and scanning electron microscopy. Features studied include microphyll arrangement, epidermal cell morphology, stomal distribution, shape arrangement and distribution silica body on microphyll surface. Microphyll are dimorphic and 4-ranked arrangement, with ventral microphylls larger than the dorsal microphylls. The epidermal cells at dorsal side of dorsal microphylls and at ventral side of ventral microphylls are similar, which are tetragonal or oblong in shape and sinuolate or sinuate in anticlinal cell walls. The epidermis at ventral side of dorsal microphylls and dorsal side of ventral microphylls are similar, which are sub-square or rectangular in shape and straight or sinuolate in anticlinal walls. Stomata are mainly distributed on dorsal side of dorsal microphylls and ventral side of ventral microphylls. Four distribution patterns of are found on microphyll silica body, which are microphyll margin, midrib, homogeneity and nil patterns. Four types of arrangement of silica body on epidermal cells were recognized, namely single row, multi-row, mixed and globulate types. In Taiwan, the characters appeared in epidermal cell morphology and stomal distribution of microphyll are useful for species identification in Selaginella, while those of distribution at patterns and arrangement types of silica bodies on epidermal cells are valuable for the species identification under subgenus. Taiwan ventral dorsal silica body Selaginella
5	Spikemoss patterns : Systematics and historical biogeography of Selaginellaceae / Mosslummermönster : Systematik och historisk biogeografi hos Selaginellaceae Weststrand, Stina January 2016 (has links) Selaginellaceae, spikemosses, is a heterosporous plant family belonging to the lycophytes. With an estimated age of some 350 million years, the family is historically important as one of the oldest known groups of vascular plants. Selaginellaceae is herbaceous with a worldwide distribution. However, the majority of the ca. 750 species in the single genus Selaginella are found in the tropics and subtropics. This thesis aims at elucidating the systematics and historical biogeography of Selaginellaceae. The evolutionary relationships of the family were inferred from DNA sequence data (plastid and single-copy nuclear) of one-third of the species richness in the group. Attention was paid to cover the previously undersampled taxonomic, morphological, and geographical diversity. Morphological features were studied and mapped onto the phylogeny. The results show an overall well-supported phylogeny and even more complex morphological patterns than previously reported. Despite this, many clades can be distinguished by unique suites of morphological features. With the phylogeny as a basis, together with the thorough morphological studies, a new subgeneric classification with seven subgenera, representing strongly supported monophyletic groups, is presented for Selaginella. By mainly using gross morphological features, easily studied by the naked eye or with a hand lens, the intention is that the classification should be useful to a broader audience. During the work with species determinations, it was revealed that the correct name for an endemic Madagascan Selaginella species is S. pectinata Spring, not S. polymorpha Badré as previously proposed. The robust phylogeny of Selaginellaceae allowed for a historical biogeographical analysis of the group. A time-calibrated phylogeny, together with extant species distribution data, formed the basis. The results show pre-Pangean diversification patterns, Gondwanan vicariance, and more recent Cenozoic long-distance dispersals. The many inferred transoceanic dispersals during the last 50 million years are surprising considering Selaginella’s large megaspores that are thought to have a negative effect on dispersal. In conclusion, this thesis presents a well-founded hypothesis of the evolutionary history of Selaginellaceae including its phylogeny, morphology, and historical biogeography. The thesis forms a firm basis for further studies on Selaginellaceae in particular, and gives us a better understanding of early land plant evolution in general. classification historical biogeography lycophytes nomenclature phylogeny Selaginella Selaginellaceae systematics fylogeni historisk biogeografi klassifikation lummerväxter nomenklatur Selaginella Selaginellaceae systematik
6	Evolution of phage-type RNA polymerases in higher plants Yin, Chang 14 February 2011 (has links) In mono- und eudikotylen Pflanzen kodiert eine Genfamilie (RpoT, RNA-Polymerase des T3/T7-Typs) mitochondriale und plastidäre RNA-Polymerasen (RNAP), die den ungeraden T-Phagen-Polymerasen ähneln. RpoT-Gene von Angiospermen sind gut charakterisiert, während aus tiefer abzweigenden Pflanzenspecies bisher lediglich die Gene aus dem Moos Physcomitrella beschrieben wurden. Um einen Beitrag zur Aufklärung der molekularen Evolution der RpoT-Polymerasen im Pflanzenreich zu liefern und um Erkenntnisse über die potentielle Bedeutung von multiplen Phagen-Typ (RNAP) in Pflanzen zu gewinnen, wurden die RpoT-Gene aus dem Lycophyten Selaginella moellendorffii und aus dem basalen Angiosperm Nuphar advena identifiziert und charakterisiert. Selaginella moellendorffii (Moosfarn)-Trace-Sequenzdaten mit hoher Ähnlichkeit zu RpoT-Sequenzen von Angiospermen wurden benutzt, um das full-length SmRpoT-Gen und die entsprechende cDNA zu isolieren. Die SmRpoT-mRNA ist 3542 nt lang und weist einen offenen Leserahmen von 3006 nt auf, der für ein putatives Protein aus 1002 Aminosäuren mit einer molekularen Masse von 113 kDa kodiert. Das SmRpoT-Gen besteht aus 19 Exons und 18 Introns, die in ihren Positionen mit denen aus den Angiosperm- und Physcomitrella-Genen konserviert sind. Mittels Southernblot-Analyse wurde nachgewiesen, dass S. moellendorffii ein single-copy RpoT-Gen kodiert. Für das N-terminale Transitpeptid von SmRpoT konnte gezeigt werden, dass es bei transienter Expression in Arabidopsis- und Selaginella-Protoplasten den Transport von GFP (green fluorescent protein) exclusiv in Mitochondrien vermittelt. In N. advena wurden mittels Screening einer BAC-Bibliothek drei RpoT-Gene identifiziert. Sowohl die genomischen als auch die cDNA-Sequenzen wurden aufgeklärt. Die NaRpoT-mRNAs kodieren putative Polypeptide von 996, 990 und 985 Aminosären. Alle drei Gene besitzen 19 Exons und 18 Introns, die in ihren Positionen mit denen der RpoT-Gene aus Selaginella und allen anderen Landpflanzen konserviert sind. Die kodierten Proteine weisen auf Aminosäureebene einen hohen Konservierungsgrad auf, einschließlich aller essentiellen Regionen und Aminosäurereste, die für die T7-RNAP bekannt sind. Die N-terminalen Transitpeptide zweier der kodierten RNAP, NaRpoTm1 und NaRpoTm2, vermittelten den Import von GFP exclusiv in Mitochondrien, während die dritte Polymerase, NaRpoTp, in Chloroplasten importiert wurde. Interessanterweise muß die Translation der NaRpoTp-mRNA an einem CUG-Codon initiiert werden, um ein funktionelles Protein mit plastidärem Transitpeptid zu erhalten. Die N. advena RpoTp-RNAP ist somit neben AGAMOUS aus Arabidopsis und der RpoTp-RNAP aus Nicotiana, ein weiteres Beispiel für jene selten vorkommenden pflanzlichen mRNAs, deren Translation exclusiv an nicht-AUG-Codons initiiert wird. Die Rekonstruktion von phylogenetischen Bäumen resultierte in unterschiedlichen Positionen für die Selaginella- und Nuphar-Polymerasen: Im Gegensatz zu der RpoT-Polymerase aus S. moellendorffii und denen aus Physcomitrella, die in den phylogenetischen Analysen Schwesterpositionen zu allen anderen Phagentyp-RNAP der Angiospermen einnehmen, clusterten die Nuphar-RpoTs zusammen mit den deutlich separierten mitochondrialen (NaRpoTm1 und NaRpoTm2) und plastidären (NaRpoTp) Polymerasen. Selaginella kodiert eine einzige mitochondriale RNAP, während Nuphar zwei mitochondriale und eine plastidäre RNAP besitzt. Die Identifizierung einer Plastiden-lokalisierten Phagentyp-RNAP in diesem basalen Eudikotylen, die ortholog zu allen anderen RpoT-Enzymen der Blütenpflanzen ist, läßt darauf schließen, daß die Acquisition einer nukleär kodierten plastidären RNAP, die noch in den Lycopoden fehlt, nach der Trennung der Leucopoden von allen anderen Tracheophyten erfolgte. Eine “dual-targeting” RNAP (mitochondrial und plastidär lokalisiert), wie sie in Eudikotylen, nicht jedoch in Monokotylen vorkommt, wurde weder in Selaginella noch in Nuphar nachgewiesen, vermutlich ist sie ein evolutionäres Novum von eudikotylen Pflanzen wie Arabidopsis. / In mono- and eudicot plants, a small nuclear gene family (RpoT, RNA polymerase of the T3/T7 type) encodes mitochondrial as well as chloroplast RNA polymerases homologous to the T-odd bacteriophage enzymes. RpoT genes from angiosperms are well characterized, whereas data from deeper branching plant species until recently were limited to the moss Physcomitrella. To elucidate the molecular evolution of the RpoT polymerases in the plant kingdom and to get more insight into the potential importance of having more than one phage-type RNA polymerase (RNAP) available, we identified and characterized RpoT genes in the lycophyte Selaginella moellendorffii and the basal eudicot Nuphar advena. Selaginella moellendorffii (spikemoss) sequence trace data encoding a polypeptide highly similar to angiosperm and moss phage-type organelle RNA polymerases were used to isolate a BAC clone containing the full-length gene SmRpoT as well as the corresponding cDNA. The SmRpoT mRNA comprises 3452 nt with an open reading frame of 3,006 nt, encoding a putative protein of 1,002 amino acids with a molecular mass of 113 kDa. The SmRpoT gene comprises 19 exons and 18 introns, conserved in their position with those of the angiosperm and Physcomitrella RpoT genes. Using Southern blot analysis, it was shown that S. moellendorffii encodes a single RpoT gene. The N-terminal transit peptide of SmRpoT was shown to confer targeting of green fluorescent protein (GFP) exclusively to mitochondria after transient expression in Arabidopsis and Selaginella protoplasts. In Nuphar advena three RpoT genes were identified by BAC library screening. Both genomic gene sequences and full-length cDNAs were determined. The NaRpoT mRNAs specify putative polypeptides of 996, 990 and 985 amino acids, respectively. All three genes comprise 19 exons and 18 introns, conserved in their positions with those from S. moellendorffii and the RpoT genes of other land plants. The encoded proteins show a high degree of conservation at the amino acid sequence level, including all functional crucial regions and residues known from the phage T7 RNAP. The N-terminal transit peptides of two of the encoded polymerases, NaRpoTm1 and NaRpoTm2, conferred targeting of GFP exclusively to mitochondria, whereas the third polymerase, NaRpoTp, was targeted to chloroplasts. Remarkably, translation of NaRpoTp mRNA has to be initiated at a CUG codon to generate a functional plastid transit peptide. Thus, besides AGAMOUS in Arabidopsis and the Nicotiana RpoTp polymerase, N. advena RpoTp provides another example for a plant mRNA that is exclusively translated from a non-AUG codon. Reconstruction of phylogenetic trees revealed different positions of the RpoTs from the lycophyte Selaginella and the basal eudicot Nuphar. In contrast to the RpoTs of S. moellendorffii and those of the moss Physcomitrella, which are according to the phylogenetic analyses in sister positions to all other phage-type polymerases of angiosperms, the Nuphar RpoTs clustered with the well separated clades of mitochondrial (NaRpoTm1 and NaRpoTm2) and plastid (NaRpoTp) polymerases. Selaginella encodes a single mitochondrial RNAP, whereas Nuphar harbors two mitochondrial and one plastid phage-type polymerases. Identification of a plastid localized phage-type RNAP in this basal eudicot, orthologous to all other RpoTp enzymes of flowering plants, suggests that the acquisition of a nuclear encoded plastid RNA polymerase, not present in lycopods, took place after the split of lycopods from all other tracheophytes. A dual-targeted mitochondrial and plastid RNA polymerase (RpoTmp), as present in eudicots but not monocots, was not detected in Nuphar or Selaginella suggesting that its occurrence is an evolutionary novelty of eudicotyledoneous plants like Arabidopsis. Selaginella moellendorffii Nuphar advena Phage-Typ RNA Polymerasen Gene Duplikation phage-type RNA polymerase Selaginella moellendorffii Nuphar advena gene duplication 570 Biowissenschaften, Biologie 32 Biologie WG 1840 ddc:570
7	Origin & Evolution of the C3HDZ-ACL5-SACL Regulatory Module in Land Plants Solé Gil, Anna 07 September 2023 (has links) [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

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