Histochemical expressing genes as ultrasensitive markers for micrometastasis studies

Lin, Wen-chang

January 1992

No description available.

Biology, Molecular

Histochemical marker genes

Micrometastasis

Klasifikace bakterií pomocí markerových genů / Bacteria Classification Based on Marker Genes

Pelantová, Lucie

January 2020

The aim of this work is proposal of new method for bacteria classification based on sequences of marker genes. For this purpose was chosen 10 marker genes. Resulting MultiGene classifier processes data set by dividing it in several groups and choosing gene for each group which can distinguish this group with best results. This work describes implementation of MultiGene classifier and its results in comparison with other bacteria classifiers and with classification based entirely on gene 16S rRNA.

A bifunctional selectable marker gene for T-DNA tagging of plant promoters

Bauer, Brigitte J.

01 January 2000

Plant promoters are the principle cis-acting regulatory sequences responsible for the temporal and spatial expression of genes. One method for isolating plant promoters is based on the ability of a common soil bacterium, <i> Agrobacterium tumefaciens </i>, to transfer a specific segment of DNA (T-DNA) into plant cells. This specific T-DNA has been shown to integrate stably into the recipient plant genome. If the T-DNA contains a promoterless marker gene, then T-DNA integration events occurring adjacent and downstream to a promoter region can be detected by the activation of the marker gene. These T-DNA-mediated gene fusions, consisting of an unknown plant promoter sequence and the coding sequence of a marker gene, can be isolated using the marker gene as a promoter tag. The key objective of this work was to develop a novel, bifunctional selectable marker gene and assess its use as: a selectable marker gene in bacterial and plant transformation systems, and as a promoter tag for T-DNA promoter-tagging studies in dicots. A bifunctional fusion gene was produced between phosphinothricin acetyltransferase and neomycin phosphotransferase (PAT::NPT II), by fusing an NPT II coding sequence to the 3' terminus of the PAT gene. The PAT gene product confers tolerance to a non-selective herbicide L-phosphinothricin (Ignite, Hoechst AG). The neomycin phosphotransferase ('npt II') gene allows for direct selection of transformed cells with the antibiotic, kanamycin. Using an <i>in vivo Escherichia coli </i> selection system, a translational fusion gene between these two reporter genes was achieved. The resulting protein had activities of both parent enzymes. This was demonstrated both in transformed <i>Escherichia coli</i> and in transformed <i>Nicotiana tabacum</i> and <i>Brassica napus</i> plants. Using this bifunctional selectable marker gene, a T-DNA promoter tagging vector, pBAU2, was constructed and its utility was demonstrated in <i>Nicotiana tabacum</i>. One of the <i>N. tabacum</i> promoter tagged events was selected for subsequent promoter isolation studies. The promoter from this regenerant was isolated by screening a Lambda subgenomic library and also by thermal asymmetric interlaced (TAIL-)PCR. The isolated upstream regulatory sequence was fused to a reporter gene, â-glucuronidase ('gus'), and subjected to a preliminary evaluation in <i> Nicotiana tabacum</i> and in <i>Brassica napus</i>.

pat::nptII

plant promoters

marker genes

fusion genes

transgenic plants

crop science

phosphinothricin acetyltransferase

neomycin phosphotransferase II

T-DNA tagging In Brassica carinata with a promoterless gus : NPTII gene fusion vector

Babic, Vivijan

01 January 1998

An efficient system for or 'Agrobacterium'-mediated transformation of <i>Brassica carinata</i> was used together with a promoterless <i> gus</i>::<i>nptII</i> gene fusion to isolate putative promoter sequences. Cotyledonary petioles were transformed using the promoterless gene fusion construct. Only transformation events in which the promoterless gene fusion had integrated downstream from plant regulatory sequences were expected to produce viable tissue under kanamycin selection. Forty-two transgenic plants were recovered. Transformation efficiency was approximately 0.6%. Regenerated plants were screened for GUS expression in different tissues and organs by histological and fluorometric assays. Tissue-specific GUS expression was detected (stigmas, seed coat, leaf edges and vascular tissue) in some plants, while strong constitutive GUS expression was detected in others (based on GUS histological assays). Using subgenomic libraries, putative promoter fragments were isolated from the plants which exhibited GUS expression in stigmas, leaf edges and constitutively. A putative promoter fragment from a plant which exhibited GUS expression only in the stigma was fused with the gus gene and reintroduced by <i>Agrobacterium </i> -mediated transformation into <i>B. napus, B. carinata, Arabidopsis' and tobacco </i>. GUS expression was observed in the stigma of <i>B. napus </i> but not in ' B. carinata'. In <i>Arabidopsis </i> and tobacco GUS expression. was not tissue specific (weakly constitutive or restricted to two or more tissues). The 3' DNA sequence (15 kb) flanking the <i> gus</i>::<i>nptII </i> insert in the plant with GUS expression in the stigma was also isolated using a subgenomic library. A gene for a cytochrome P450 like protein was discovered on the minus DNA strand of the 3' sequence with a start codon approximately 6.5 kb from the T-DNA left border.

plant science

T-DNA tagging

brassica carinata

marker genes

promoterless GUS::NPTII gene fusion

GUS expression

transgenic plants

Recherche de marqueurs moléculaires de la tolérance de la Vigne à Eutypa lata. Compréhension des mécanismes physiologiques impliqués / Research and validation of molecular markers of grapevine susceptibility to Eutypa lata. Studies of physiological mechanisms involved

Cardot, Chloé

18 December 2017

Les maladies du bois de la vigne, causées par des champignons nécrotrophes, ont un impact considérable sur l'économie viticole au niveau mondial. En effet, tous les cépages Vitis vinifera cultivés actuellement présentent une sensibilité plus ou moins forte à ces champignons.Dans le but d'établir un test rapide d'évaluation de la sensibilité de clones de vigne (nouvellement sélectionnés ou futures obtentions variétales) à Eutypa lata, le champignon responsable de l'Eutypiose, une recherche de marqueurs moléculaires de tolérance a été réalisée. Suite à l'infection in vivo et in vitro d'une douzaine de cépages de sensibilité différente par E. lata, plusieurs gènes candidats ont été identifiés comme marqueurs potentiels de la tolérance à la maladie à partir d'une étude transcriptomique.A l'aide d'un système innovant d'infection in vitro, le dialogue moléculaire sans contact physique entre des disques foliaires de V. vinifera et le mycélium d’E. lata a également été étudié chez les douze cépages. Cette étude a permis de mettre en évidence le rôle potentiel d'éliciteurs dans la mise en place des réponses de défenses. De plus, l'infection par E. lata régule différentiellement l'expression des gènes codant pour un transporteur d'hexoses et des invertases, ainsi que les activités invertasiques associées, chez les cépages de sensibilités variables.Les travaux de recherche présentées dans cette thèse ont ainsi permis l'identification des marqueurs de tolérance à l'Eutypiose et la mise au point d'un test d'infection in vitro efficace et fiable, permettant de diagnostiquer la sensibilité des futures créations variétales. De plus les résultats obtenus démontrent l'importance des éliciteurs dans la mise en place des défenses, de la régulation du transport et du métabolisme des sucres au cours de l'infection par E. lata. / Nowadays, grapevine wood decay diseases cause significant economic losses for the most sensitive varieties and represent a threat to the sustainability of the wine industry.This research focuses on the identification of molecular markers for sensitivity to Eutypa lata, responsible for Eutypiosis that could be used to diagnose the sensitivity of new grapevine clones or cultivars. Using an in vivo and in vitro infection assay, several potential markers genes for tolerance to Eutypiosis have been identified from a gene expression study on twelve different cultivars.Using an innovative in vitro infection system, the molecular dialogue (without physical contact) between Vitis vinfera foliars discs of and Eutypa lata was studied, leading to the identification of elicitors that could potentially play a role in the induction of defense responses in the cultivars. In addition, the expression of several sugar transport and invertase genes and their associated activities were demonstrated to be differentially regulated by the infection in tolerant and susceptible cultivars.Altogether, this research work led to the identification of several tolerance markers genes to Eutypiosis and to the development of a new, efficient and reliable in vitro infection system that could be used to diagnose new cultivar susceptibility. Furthermore, the results obtained demonstrated the importance of sugar transport and defense metabolism regulation during the infection of grapevine by Eutypa lata.

Eutypa lata

Vitis vinifera

Maladie du bois

Marqueurs de tolérance

Transporteurs d'hexoses

Invertases

Éliciteurs de défenses

Eutypa lata

Vitis vinifera

Wood decay diseases

Tolerance marker genes

Hexose transporters

Invertases

Elicitors

571.982

Marker asistované selekce autoinkompatibilních rostlin řepky / Marker assisted selection in hybrid breeding of oil seed rape

HAVLÍČKOVÁ, Lenka

January 2007

Marker assisted selection in hybrid breeding of oil seed rape

Cultura de tecidos e transformação genética de espécies da família Poaceae / Tissue culture and genetic transformation of Poaceae family species

Cabral, Glaucia Barbosa

11 July 2012

Brachiaria é um gênero de forrageiras da família Poaceae que apresenta plantas que se reproduzem por via sexual e assexualmente por apomixia,reprodução por sementes. A apomixia desperta interesse biológico e biotecnológico, pela perspectiva de levar esta característica de clonagem de plantas via sementes, a outras espécies. As cultivares plantadas de B. brizantha cv. Marandu e B. decumbens cv. Basilisk são poliplóides e reproduzem-se por apomixia, enquanto as plantas sexuais são diplóides,o que inviabiliza os cruzamentos, dificultando sobremaneira o melhoramento. A transformação genética é uma estratégia que vem sendo incorporada ao melhoramento genético. A natureza apomítica destasplantas pode permitir a clonagem e estabilidade das plantas transgênicas. Para transformação genética é necessário o desenvolvimento de um método eficiente de regeneraçãoin vitro. B. brizantha é considerada recalcitrante a cultura de tecidos, e métodos eficientes associados com os sistemas de transformação genética ainda não foram descritos na literatura. O arroz (Oryza sativa) é uma Poaceae modelo para estudos de genética inversa, no entanto, cultivares tropicais do grupo japônica são recalcitrantes a transformação genética, como é o caso da cultivar Primavera. O método direto de transformação genética mais amplamente utilizado é a biobalística, e vem sendo aplicado em espécies de monocotiledôneas, uma vez que essas não são hospedeiros naturais de Agrobacterium tumefaciens. No entanto, vários fatores tem sido testados no sentido de favorecer a interação e transferência de genes durante a cocultura para obtenção de transgênicos em diversas espécies de monocotiledôneas. Os objetivos deste estudo foram obter sistemas de regeneração in vitro deB. Brizanthae de arroz cultivar Primavera para transformação genética destas espécies. Em B. brachiaria foram obtidos sistema de micropropagação, organogênese, calos embriogênicos, unidades embriogênicas e suspensões celulares, e para a cultivar Primavera de arroz foram obtidas unidades embriogênicas, que foram caracterizadas morfo-anatomicamente e quanto as condições de indução, multiplicação e regeneração in vitro. Métodos de expressão transiente e estável de genes marcadores foram estabelecidos para B brizantha via biobalística e Agrobacterium tumefaciens. A natureza da transgenia foi confirmada por métodos histoquímico e molecular como PCR e Southern blot. Os sistemas de regeneração e transformação obtidos mostraram-se eficientes e irão contribuir para os estudos da apomixia e introdução de genes de interesse em braquiária / Brachiaria is a genus of Poaceae family forage grass that reproduces by sexual and asexually by apomixis. Apomixis is of biological and biotechnological interest awakened by the prospect of bringing this feature of cloning plants through seed to other species. B. brizantha cv. Marandu and B. decumbens cv. Basilisk are polyploid and reproduce by apomixis, while the sexual plants are diploid, which makes the crosses, greatly hindering the improvement. Genetic transformation is a strategy that is being incorporated into breeding programs. The nature of these apomictic plants may allow the cloning and the stability of transgenic plants. For genetic transformation is necessary to develop an efficient method of in vitro regeneration. B. brizantha is considered recalcitrant to tissue culture, and efficient methods associated with the genetic transformation systems have not been described in the literature. Rice (Oryza sativa) is a Poaceae model for studies of reverse genetics; however, tropical cultivars from japonica group are recalcitrant to genetic transformation, such as Primavera cultivar. Biolistic is the genetic transformation direct method most widely used, and has been applied to species of monocots, since these are not natural hosts of Agrobacterium tumefaciens. However, several factors have been tested in order to promote interaction and gene transfer during coculture for obtaining transgenics in several monocots species. The objectives of this study were to obtain in vitro regeneration and genetic transformation systems for these species. In B. Brachiaria systemsfor micropropagation, organogenesis, embryogenic units and embryogenic cell suspensions were obtained, and forrice Primavera cultivar embryogenic units were obtained, which was morpho-anatomical characterized and in vitro induction, proliferation and regeneration conditions established. Methods for transient and stable gene expression have been acquired for B. brizanthavia biolistic and Agrobacterium tumefaciens. The nature of the embryogenic callus and transgenic plants was confirmed by histochemical and molecular methods such as PCR and Southern blot. The regeneration and transformation systems showed to be effective and will contribute to apomixis studies and introduction of genes of interest in B. brizantha

Agrobacterium tumefaciens

Agrobacterium tumefaciens

Biobalística

Biolistics

Brachiaria brizantha cv

Brachiaria brizantha cv

Embriogênese somática

Genes marcadores

Marandu

Marandu

Marker genes

Organogênese

Organogenesis

Oryza sativa cv

Oryza sativa cv

Primavera

Primavera

Somatic embryogenesis

Cultura de tecidos e transformação genética de espécies da família Poaceae / Tissue culture and genetic transformation of Poaceae family species

Glaucia Barbosa Cabral

11 July 2012

Brachiaria é um gênero de forrageiras da família Poaceae que apresenta plantas que se reproduzem por via sexual e assexualmente por apomixia,reprodução por sementes. A apomixia desperta interesse biológico e biotecnológico, pela perspectiva de levar esta característica de clonagem de plantas via sementes, a outras espécies. As cultivares plantadas de B. brizantha cv. Marandu e B. decumbens cv. Basilisk são poliplóides e reproduzem-se por apomixia, enquanto as plantas sexuais são diplóides,o que inviabiliza os cruzamentos, dificultando sobremaneira o melhoramento. A transformação genética é uma estratégia que vem sendo incorporada ao melhoramento genético. A natureza apomítica destasplantas pode permitir a clonagem e estabilidade das plantas transgênicas. Para transformação genética é necessário o desenvolvimento de um método eficiente de regeneraçãoin vitro. B. brizantha é considerada recalcitrante a cultura de tecidos, e métodos eficientes associados com os sistemas de transformação genética ainda não foram descritos na literatura. O arroz (Oryza sativa) é uma Poaceae modelo para estudos de genética inversa, no entanto, cultivares tropicais do grupo japônica são recalcitrantes a transformação genética, como é o caso da cultivar Primavera. O método direto de transformação genética mais amplamente utilizado é a biobalística, e vem sendo aplicado em espécies de monocotiledôneas, uma vez que essas não são hospedeiros naturais de Agrobacterium tumefaciens. No entanto, vários fatores tem sido testados no sentido de favorecer a interação e transferência de genes durante a cocultura para obtenção de transgênicos em diversas espécies de monocotiledôneas. Os objetivos deste estudo foram obter sistemas de regeneração in vitro deB. Brizanthae de arroz cultivar Primavera para transformação genética destas espécies. Em B. brachiaria foram obtidos sistema de micropropagação, organogênese, calos embriogênicos, unidades embriogênicas e suspensões celulares, e para a cultivar Primavera de arroz foram obtidas unidades embriogênicas, que foram caracterizadas morfo-anatomicamente e quanto as condições de indução, multiplicação e regeneração in vitro. Métodos de expressão transiente e estável de genes marcadores foram estabelecidos para B brizantha via biobalística e Agrobacterium tumefaciens. A natureza da transgenia foi confirmada por métodos histoquímico e molecular como PCR e Southern blot. Os sistemas de regeneração e transformação obtidos mostraram-se eficientes e irão contribuir para os estudos da apomixia e introdução de genes de interesse em braquiária / Brachiaria is a genus of Poaceae family forage grass that reproduces by sexual and asexually by apomixis. Apomixis is of biological and biotechnological interest awakened by the prospect of bringing this feature of cloning plants through seed to other species. B. brizantha cv. Marandu and B. decumbens cv. Basilisk are polyploid and reproduce by apomixis, while the sexual plants are diploid, which makes the crosses, greatly hindering the improvement. Genetic transformation is a strategy that is being incorporated into breeding programs. The nature of these apomictic plants may allow the cloning and the stability of transgenic plants. For genetic transformation is necessary to develop an efficient method of in vitro regeneration. B. brizantha is considered recalcitrant to tissue culture, and efficient methods associated with the genetic transformation systems have not been described in the literature. Rice (Oryza sativa) is a Poaceae model for studies of reverse genetics; however, tropical cultivars from japonica group are recalcitrant to genetic transformation, such as Primavera cultivar. Biolistic is the genetic transformation direct method most widely used, and has been applied to species of monocots, since these are not natural hosts of Agrobacterium tumefaciens. However, several factors have been tested in order to promote interaction and gene transfer during coculture for obtaining transgenics in several monocots species. The objectives of this study were to obtain in vitro regeneration and genetic transformation systems for these species. In B. Brachiaria systemsfor micropropagation, organogenesis, embryogenic units and embryogenic cell suspensions were obtained, and forrice Primavera cultivar embryogenic units were obtained, which was morpho-anatomical characterized and in vitro induction, proliferation and regeneration conditions established. Methods for transient and stable gene expression have been acquired for B. brizanthavia biolistic and Agrobacterium tumefaciens. The nature of the embryogenic callus and transgenic plants was confirmed by histochemical and molecular methods such as PCR and Southern blot. The regeneration and transformation systems showed to be effective and will contribute to apomixis studies and introduction of genes of interest in B. brizantha

Agrobacterium tumefaciens

Biobalística

Brachiaria brizantha cv

Embriogênese somática

Genes marcadores

Marandu

Organogênese

Oryza sativa cv

Primavera

Agrobacterium tumefaciens

Biolistics

Brachiaria brizantha cv

Marandu

Marker genes

Organogenesis

Oryza sativa cv

Primavera

Somatic embryogenesis

Transformación genética del albaricoquero (Prunus armeniaca L.), mediada por Agrobacterium, y regeneración de plantas transformadas

Petri Serrano, César

23 July 2005

ResumenEn esta tesis se ha optimizado un protocolo de regeneración a partir de material varietal de 'Helena' y 'Canino'. Mediante el estudio de los diversos factores que afectan la transformación de material adulto, se ha establecido por primera vez un protocolo eficiente de transformación mediada por Agrobacterium tumefaciens de una variedad comercial de albaricoquero.El diseño de una estrategia de selección gradual con paromomicina ha permitido la regeneración de plántulas transformadas con los genes marcadores nptII y sgfp o gus, con las eficiencias más elevadas que se han publicado hasta el momento para transformar material varietal en especies del género Prunus, aunque la baja viabilidad de las yemas transformadas redujo el número final de plantas obtenidas.El protocolo establecido en esta tesis sienta las bases que permitirán la introducción de genes de interés agronómico y comercial, modificando de manera discreta variedades élite aceptadas y establecidas en el mercado. / In this thesis a protocol of regeneration has been optimized from leaf explants of the cultivars 'Helena' and 'Canino'. By means of the study of the diverse factors that affect the transformation of adult material, an efficient protocol of Agrobacterium tumefaciens-mediated transformation has been established for the first time for a commercial cultivar of apricot.The design of a gradual selection strategy with paromomycin has permitted the regeneration of transformed shoots with the marker genes nptII and sgfp or gus, with the highest efficiencies that have been published up to now from adult material in Prunus, although the low viability of the transformed buds reduced the final number of plants obtained. This protocol establishes the bases that will permit the introduction of agronomic and commercial interesting genes, modifying discreetly commercial cultivars accepted and established in the market.

nptII

Agrobacterium tumefaciens

regeneration

nptII

transformation

Prunus armeniaca

gus

marker genes

gfp

aminoglycoside antibiotics

progressive selection

Prunus armeniaca

transformación

regeneración

Agrobacterium tumefaciens

selección progresiva

antibióticos aminoglicósidos

gfp

genes marcadores

gus.

Biología Fundamental

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