Synthesis and Biological Activity of Novel Antimitotic Nucleoside Derivatives of Podophyllotoxin and 4'-Demethylepipodophyllotoxin

Derry, William Brent

08 1900

<p> The objective of this study was to synthesize and biologically evaluate a series of novel nucleoside derivatives of the naturally occurring lignans, podophyllotoxin and 4'-demethylepipodophyllotoxin. Epipodophyllotoxin derivatives display two types of biological activity: while the naturally occurring compounds are potent inhibitors of microtubule polymerization, two semi-synthetic glycoside derivatives, viz VP16-213 (etoposide) and VM26 (teniposide), are specific inhibitors of mammalian DNA topoisomerase II. The latter two compounds have proven to be very useful in the treatment of many different types of cancer. In this study, the glycoside moiety of VP16-213/VM26 was replaced with either a thymidine or a 2'-deoxyadenosine group. The synthetic approach involved protective group chemistry, where functional groups on the nucleosides and DMEP were selectively blocked prior to their condensation in the presence of boron trifluoride etherate catalyst. These compounds are of interest because they involve substitution of the glucoside moiety with a nucleoside residue, whose effect on the biological activity of epipodophyllotoxin derivatives has not been examined. The biological activity of these compounds was assessed by examining their cross-resistance patterns towards a set of Chinese hamster ovary mutants resistant to podophyllotoxin VP16-213/VM26, mitotic index, and by a competition assay. From the cross resistance assay, all of the thymidine derivatives were found to be considerably less active than the parent podophyllotoxin and 4'-demethylepipodophyllotoxin molecules, while the 2'-deoxyadenosine derivatives were found to be completely inactive. The cross-resistance patterns of the thymidine derivatives suggests that these compounds display podophyllotoxin-like activity in vivo and show no VP16-213/VM26-like activity. Treatment of wild type cells with the active thymidine derivatives (compounds 1.2, 2.2, 2.3, and 2.4) increased the mitotic indices approximately ten-fold in a dose-dependent manner, which parallels the results of the dose-response curves in the initial cross-resistance assay. Furthermore, there was a marked increase in the levels of drug required to elevate the mitotic index in second-step mutants resistant to podophyllotoxin, again lending support to the initial results indicating that the cellular target of these compounds is tubulin. Only one compound (1.2), was found to out compete the binding of radiolabelled podophyllotoxin to purified calf brain tubulin. However, due to their low activity relative to podophyllotoxin, most of these compounds were insoluble at concentrations required to out compete the binding of radiolabelled podophyllotoxin. Molecular modelling studies have provided useful insights regarding the structure/activity relationships among the active and inactive nucleoside derivatives showing podophyllotoxin-like antimitotic activity. There appears to be steric limits for substituents attached at the C4 moiety that maintain the antimitotic activities of the parent molecules. The electrostatic potential and hydrophobic properties of these groups also seem to play a role in the degree of activity these compounds show, but remain unclear at this point. By simple comparison of the three-dimensional structures of these compounds there appears to be a very limited spacial and electrostatic requirement for the bulky glycosidic moiety attached to C4 which is essential for targeting VP16-213 and VM26 to DNA topoisomerase II. Thus, several important structural features which may distinguish the selectivity POD derivatives show for either tubulin or DNA topoisomerase II are described.</p> / Thesis / Master of Science (MSc)

Identification and Characterization of Genes Required for Symbiotic Nitrogen Fixation in Medicago truncatula Tnt1 Insertion Mutants

Cai, Jingya

07 1900

In this dissertation I am using M. truncatula as a model legume that forms indeterminate nodules with rhizobia under limited nitrogen conditions. I take advantage of an M. truncatula Tnt1 mutant population that provides a useful resource to uncover and characterize novel genes. Here, I focused on several objectives. First, I carried out forward and reverse genetic screening of M. truncatula Tnt1 mutant populations to uncover novel genes involved in symbiotic nitrogen fixation. Second, I focused on reverse genetic screening of two genes, identified as encoding blue copper proteins, and characterization of their mutants' potential phenotypes. Third, I further characterized a nodule essential gene, M. truncatula vacuolar iron transporter like 8 (MtVTL8), which encodes a nodule specific iron transporter. I characterized the expression pattern, expression localization and function of MtVTL8. Additionally, I characterized several residues predicted to be essential to function using a model based on the known crystal structure of Eucalyptus grandis vacuolar iron transporter 1 (EgVIT1), a homologous protein to MtVTL8. I identified several potential essential residues of the MtVTL8 protein, mutagenized them, and through complementation experiments in planta and in yeast assessed functionality of the resulting protein. This helped us to better understand the potential mechanism by which MtVTL8 functions.

Symbiotic nitrogen fixation

Medicago truncatula

Tnt1 insertion mutants

vacuolar iron transporter like genes

functional analysis

MtVTL8

Mutation testing : the perfect set of mutation operators / Mutationstestning : den perfekta mängden av mutationsoperatorer

Falk, Jonathan

January 2024

While mutation testing is an effective fault-based testing technique, it has its challenges such as being computationally expensive and requiring a large amount of effort to review surviving mutants. These problems have resulted in mutation testing mostly being restricted to academic research and not as widely adopted in the industry. In the academic context, the focus has been on maximizing the mutation score and while a high mutation score might increase the quality of the software, it is not feasible to kill all the mutants. Moreover, all mutants are not as equally important, and some can not or should not be killed. Instead, the focus should be shifted to prioritizing the productive mutants, those that further improve the test suite or the source code. This thesis investigated if some mutation operators are more suitable for certain types of software by using selective mutation. The mutation operators were evaluated based on their ability to generate productive mutants. Moreover, the mutation operators were analyzed to identify how they could be improved to reduce the number of unproductive mutants generated by them. Dextool Mutate was used to conduct mutation testing on four open-source C/C++ software that were all different types of software. It was concluded that some mutation operators are more suitable for certain types of software resulting in the proposal of a set of mutation operators for each software type. Moreover, various improvements for the mutation operators were identified that reduce the number of unproductive mutants generated. Lastly, it may be helpful to customize the implementation of mutation operators for each type of software and some software types may require additional specialized mutation operators.

software testing

mutation testing

mutation operator

selective mutation

productive mutants

experimental

industrial

Computer Sciences

Datavetenskap (datalogi)

Développement d’outils cellulaires et moléculaires pour l’étude des interactions Candida - phagocytes ; Application à la caractérisation du gène OLE2 codant une désaturase chez C. lusitaniae / Development of cellular and molecular tools for the analysis of Candida - phagocytes interactions; Application to the functional analysis of a desaturase encoded by OLE2 in C. lusitaniae

El Kirat, Sofiane

14 December 2010

Les levures Candida sont des pathogènes opportunistes responsables d’infections graves chez les patients immunodéprimés. Au cours de ce travail, nous avons développé un modèle cellulaire in vitro pour la caractérisation multiparamétrique des phénotypes d’interaction entre les levures Candida et les macrophages et les neutrophiles, principaux effecteurs de la défense anti-Candida. Il repose sur l’utilisation de marqueurs fluorescents pour le suivi quantitatif de l’interaction en cytométrie en flux et en fluorimétrie. Ce modèle a été validé par la comparaison de l’interaction de trois espèces de levures, C. albicans, C. glabrata et C. lusitaniae, avec des macrophages murins et des neutrophiles humains. Deux stratégies principales de survie des levures à la phagocytose ont été mises en évidence : par la résistance à la phagolyse et la multiplication des levures à l’intérieur des phagocytes jusqu’à leur éclatement, ou par l’évitement de la phagocytose et la multiplication des levures à l’extérieur des phagocytes. L’interprétation des données quantitatives a été confirmée par microscopie à fluorescence et vidéo-microscopie. Afin de mieux comprendre les interactions Candida-phagocytes, nous avons mis au point des outils pour l’analyse fonctionnelle de gènes chez C. lusitaniae. Une stratégie de PCR chevauchante a été développée pour l’obtention de mutants nuls de C. lusitaniae, sans étape de clonage. C’est ainsi que le gène OLE2, codant une Δ9 désaturase d’acides gras potentiellement impliquée dans la biosynthèse de la prostaglandine PGE2, a été invalidé. Le mutant ole2Δ présentait de très nets défauts de filamentation et de reproduction sexuée. Par rapport à une souche sauvage, le mutant ole2∆ était massivement phagocyté par les macrophages, et la survie des phagocytes était plus importante, ce qui suggère un rôle important des lipides insaturés et des oxylipides dans la signalisation cellulaire au cours de l’interaction Candida-phagocytes. Dans la dernière partie de notre travail, nous avons construit une banque de 10 000 mutants de C. lusitaniae par l’intégration aléatoire d’un marqueur dans le génome. Le criblage de cette banque à travers notre modèle cellulaire d’interaction permettra d’identifier de nouveaux gènes impliqués dans l’interaction avec les phagocytes afin de mieux comprendre la physiopathologie des candidoses et de trouver de nouvelles pistes thérapeutiques. / Candida species are opportunistic pathogens causing severe infectious diseases in immunocompromised patients. In this work, we developed a tool for a multi-parameter characterization of the cell interactions between the yeasts Candida and both macrophages and neutrophils, which constitute the main defense against candidiasis. It relies on the labelling of each population with specific fluorescent markers, and on the use of fluorimetry and flow cytometry to assess interactions. The tool has been validated by comparing the interactions of three yeast species C. albicans, C. glabrata and C. lusitaniae, with murine macrophages and human neutrophils. We found that yeasts use two main ways for escaping phagocytosis, which has been confirmed using video-microscopy: either (1) by surviving to phagolysis and dividing into the phagosome until phagocytes burst, or (2) by avoiding phagocytosis and dividing outside phagocytes. In order to better understand the cellular and molecular mechanisms involved in Candida-phagocytes interactions, we developed new molecular tools for the functional analysis of genes in C. lusitaniae, notably a two-step cloning-free PCR-based method for the deletion of genes. This method was successfully used for the deletion of OLE2, a gene encoding a Δ9-desaturase of fatty acids, possibly implicated in prostaglandin PGE2 biosynthesis. The ole2Δ mutant exhibited strong defects in both pseudofilamention and sexual mating. During macrophages infection, ole2Δ yeast cells were massively internalized and triggered less phagocytes cell death than the wild type strain, suggesting that unsaturated fatty acids and/or oxylipids could play a role during interaction with phagocytes. Lastly, a bank of 10,000 mutants was constructed in C. lusitaniae by the random integration of a genetic marker in the genome. The screening of this bank through our tool to analyse cellular interactions will be undertaken to gain insights into understanding of the early stages of the infectious process.

Candida

Macrophage

Neutrophile

Interaction hôte-pathogène

Fluorimétrie

Cytométrie en flux

Oxylipides

Délétion de gène

Banque de mutants

Candida

Macrophage

Neutrophil

Host-pathogen interaction

Fluorimetry

Flow cytometry

Oxylipids

Gene knock-out

Bank of mutants

Design and Application of Temperature Sensitive Mutants in Essential Factors of RNA Splicing and RNA Interference Pathway in Schizosaccharomyces Pombe

Nagampalli, Vijay Krishna

January 2014

Gene deletions are a powerful method to uncover the cellular functions of a given gene in living systems. A limitation to this methodology is that it is not applicable to essential genes. Even for non-essential genes, gene knockouts cause complete absence of gene product thereby limiting genetic analysis of the biological pathway. Alternatives to gene deletions are mutants that are conditional, for e.g, temperature sensitive (ts) mutants are robust tools to understand temporal and spatial functions of genes. By definition, products of such mutants have near normal activity at a lower temperature or near-optimal growth temperature which is called as the permissive temperature and reduced activity at a higher, non-optimal temperature called as the non-permissive temperature. Generation of ts alleles in genes of interest is often time consuming as it requires screening a large population of mutants to identify those that are conditional. Often many essential proteins do not yield ts such alleles even after saturation mutagenesis and extensive screening (Harris et al., 1992; Varadarajan et al., 1996). The limited availability of such mutants in many essential genes prompted us to adopt a biophysical approach to design temperature-sensitive missense mutants in an essential gene of fission yeast. Several studies report that mutations in buried or solvent-inaccessible amino acids cause extensive changes in the thermal stability of proteins and specific substitutions create temperature-sensitive mutants (Rennell et al., 1991; Sandberg et al., 1995). We used the above approach to generate conditional mutants in the fission yeast gene spprp18+encoding an essential predicted second splicing factor based on its homology with human and S. cerevisiae proteins. We have used a missense mutant coupled with a conditional expression system to elucidate the cellular functions of spprp18+. Further, we have employed the same biophysical principle to generate a missense mutant in spago1+ RNA silencing factor that is non-essential for viability but has critical functions in the RNAi pathway of fission yeast. Fission yeast pre-mRNA splicing: cellular functions for the protein factor SpPrp18 Pre-mRNA splicing is an evolutionarily conserved process that excises introns from nascent transcripts. Splicing reactions are catalyzed by the large ribonuclear protein machinery called the spliceosome and occur by two invariant trans-esterification reactions (reviewed in Ruby and Abelson, 1991; Moore et al., 1993). The RNA-RNA, RNA–protein and protein-protein interactions in an assembly of such a large protein complex are numerous and highly dynamic in nature. These interactions in in vitro splicing reactions show ordered recruitment of essential small nuclear ribonucleic particles snRNPs and non–snRNP components on pre-mRNA cis-elements. Further these trans acting factors recognize and poise the catalytic sites in proximity to identify and excise introns. The precision of the process is remarkable given the diversity in architecture for exons and introns in eukaryotic genes (reviewed in Burge et al., 1999; Will and Luhrmann, 2006). Many spliceosomal protein components are conserved across various organisms, yet introns have diverse features with large variations in primary sequence. We hypothesize that co-evolution of splicing factor functions occurs with changes in gene and intron architectures and argue for alternative spliceosomal interactions for spliceosomal proteins that thus enabling splicing of the divergent introns. In vitro biochemical and genetic studies in S. cerevisiae and biochemical studies with human cell lines have indicated that ScPRP18 and its human homolog hPRP18 function during the second catalytic reaction. In S. cerevisiae, ScPrp18 is non-essential for viability at growth temperatures <30°C (Vijayraghavan et al., 1989; Vijayraghavan and Abelson, 1990; Horowitz and Abelson, 1993b). The concerted action of ScSlu7 - ScPrp18 heteromeric complex is essential for proper 3’ss definition during the second catalytic reaction (Zhang and Schwer, 1997; James et al., 2002). These in vitro studies also hinted at a possible intron -specific requirement for ScPrp18 and ScSlu7 factors as they were dispensable for splicing of intron variants made in modified ACT1 intron containing transcripts (Brys and Schwer, 1996; Zhang and Schwer, 1997). A short spacing distance between branch point adenosine to 3’splice site rendered the substrate independent of Prp18 and Slu7 for the second step (Brys and Schwer, 1996; Zhang and Schwer, 1997). Extensive mutational analyses of budding yeast ScPrp18 identified two functional domains and suggested separate roles during splicing (Bacikova and Horowitz, 2002; James et al., 2002). Fission yeast with its genome harboring multiple introns and degenerate splice signals has recently emerged as a unique model to study relationships between splicing factors and their role in genomes with short introns. Previously, studies in our lab had initiated genetic and mutational analysis of S. pombe Prp18, the predicted homolog of budding yeast Prp18. Genetic analysis showed its essentiality, but a set of missense mutants based on studies of budding yeast ScPrp18 (Bacikova and Horowitz, 2002) gave either inactive null or entirely wild type phenotype for the fission yeast protein. In this study, we have extended our previous mutational analysis of fission yeast Prp18 by adopting biophysical and computational approaches to generate temperature-sensitive mutants. A missense mutant was used to understand the splicing functions and interactions of SpPrp18 and the findings are summarized below. Fission yeast SpPrp18 is an essential splicing factor with transcript-specific functions and links efficient splicing with cell cycle progression We initiated our analysis of SpPrp18 by adopting a biophysical approach to generate ts mutants. We used the PREDBUR algorithm to predict a set of buried residues, which when mutated could result in a temperature-sensitive phenotype that complements the null allele at permissive temperature. These predictions are based upon two biophysical properties of amino acids: 1) Hydrophobicity, which is calculated in a window of seven amino acids 2) Hydrophobic moment, which is calculated in a sliding window of nine amino acids in a given protein sequence. Several studies correlate these properties to protein stability and function (Varadarajan et al., 1996). One of the buried residue mutants V194R, in helix 1 of SpPrp18 conferred weak temperature- sensitivity and strong cold-sensitivity even when the protein was over expressed from a plasmid. Through semi-quantitative RT-PCR we showed splicing-defects for tfIId+ intron1 in these cells even when grown at permissive temperature. The primary phenotype was the accumulation of pre-mRNA. Further, we showed this splicing arrest is co-related with reduced levels of SpPrp18 protein, linking protein stability and splicing function. Next we examined the effects of this mutation on function by further reduction of protein levels. This was done by integrating the expression cassette nmt81:spprp18+/spprp18V194R at the leu1 chromosomal locus and by metabolic depletion of the integrated allele. Through RT-PCRs we demonstrated that depletion of wild type or missense protein has intron specific splicing defects. These findings showed its non-global and possibly substrate-specific splicing function. In the affected introns, precursor accumulation is the major phenotype, confirming prior data from our lab that hinted at its likely early splicing role. This contrasts with the second step splicing role of the human or budding yeast Prp18 proteins. Previous data from our lab showed loss of physical interaction between SpPrp18 and SpSlu7 by co-immunoprecipitation studies. This again differs from the strong and functionally important ScPrp18 and ScSlu7 interaction seen in budding yeast. We show the absence of charged residues in SpSlu7 interaction region formed by SpPrp18 helix1 and helix2 which can explain the altered associations for SpPrp18 in fission yeast. Importantly, as the V194R mutation in helix 1 shows splicing defects even at permissive temperature, the data indicate a critical role for helix 1 for splicing interactions, possibly one that bridges or stabilizes the proposed weak association of SpPrp18-SpSlu7 with a yet unknown splicing factor. We also investigated the effects of mutations in other helices; surprisingly we recovered only mutations with very subtle growth phenotypes and very mild splicing defects. Not surprisingly, stop codon at L239 residue predicted to form a truncated protein lacking helices 3, 4 and 5 conferred recessive but null phenotype implicating essential functions for other helices. Other amino acid substitutions at L239 position had near wild type phenotype at 30°C and 37°C. Helix 3 buried residue mutant I259A conferred strong cold-sensitivity when over expressed from plasmid, but semi quantitative analysis indicated no splicing defects for intron1 in the constitutively expressed transcript tfIId+. These findings indicate cold sensitivity either arises due to compromised splicing of yet unknown transcripts or that over-expressed protein has near wild type activity. We find mutations in the helix 5 buried residues L324 also conferred near WT phenotype. Earlier studies in the lab found that substitution of surface residues KR that are in helix 5 with alanine lead to null phenotypes (Piyush Khandelia and Usha Vijayraghavan unpublished data). We report stable expression of all of these mutant proteins; L239A, L239P, L239G, I259A, I259V, L324F, L324A as determined by our immunoblot analysis at 30°C and 37°C. The mild phenotypes of many buried residues can be attributed to orientation of their functional groups into a protein cavity between the helices. Lastly, our microscopic cellular and biochemical analysis of cellular phenotypes of spprp18 mutant provided a novel and direct role of this factor in G1-S transition of cell cycle. Our RT-PCR data suggest spprp18+ is required for efficient splicing of several intron containing transcripts involved in G1-S transition and subsequent activation of MBF complex (MluI cell cycle box-binding factor complex) during S-phase and shows a mechanistic link between cell cycle progression and splicing. A tool to study links between RNA interference, centromeric non-coding RNA transcription and heterochromatin formation S.pombe possesses fully functional RNA interference machinery with a single copy for essential RNAi genes ago1+, dcr1+ and rdp1+. Deletion of any of these genes causes loss of heterochromatinzation with abnormal cytokinesis, cell-cycle deregulation and mating defects (Volpe et al., 2002). In S.pombe, exogenous or endogenously generated dsRNA’s from transcription of centromeric repeats are processed by the RNaseIII enzyme dicer to form siRNA. These siRNA’s are loaded in Ago1 to form minimal RNA induced silencing complex (RISC) complex or specialized transcription machinery complex RNA induced transcriptional silencing (RITS) complex and target chromatin or complementary mRNAs for silencing. Thus as in other eukaryotes, fission yeast cells deploy RNAi mediated silencing machinery to regulate gene-expression and influence chromatin status. Several recent studies point to emerging new roles of RNAi and its association with other RNA processes (Woolcock et al., 2011; Bayane et al., 2008; Kallgren et al., 2014). Many recent reports suggest physical interactions of RISC or RITS and RNA dependent RNA polymerase complex (RDRC) with either some factors of the spliceosomal machinery, heterochromatin machinery (CLRC complex) and the exosome mediated RNA degradation machinery (Bayne et al., 2008 and Chinen et al., 2010 ; Hiriart et al., 2012; Buhler et al., 2008; Bayne et al., 2010 ). Thus we presume conditional alleles in spago1+ will facilitate future studies to probe the genetic network between these complexes as most analyses thus far rely on ago1∆ allele or have been based on proteomic pull down analyses of RISC or RITS complexes. In this study, we employed biophysical and modeling approaches described earlier to generate temperature sensitive mutants in spago1+ and spdcr1+. We tested several mutants for their ability to repress two reporter genes in a conditional manner. Our modeling studies on SpAgo1 PAZ domain indicated structural similarities with human Ago1 PAZ domain. We created site-directed missense mutants at predicted buried residues or in catalytic residues. We also analyzed the effects of random amino acid replacements in specific predicted buried or catalytic residues of SpAgoI. These ago1 mutants were screened as pools for their effects on silencing of GFP or of ura4+ reporter genes. These assays assessed post transcriptional gene silencing (PTGS) or transcriptional gene silencing (TGS) activity of these mutants. We obtained three temperature sensitive SpAgo1 mutants V324G, V324S and L215V while the V324E replacement was a null allele. Based upon our modeling, a likely explanation for the phenotype of these mutants is structural distortion or mis-orientation of the functional groups caused due to these mutations, which affect activity in a temperature dependent manner. This distortion in the PAZ domain may affect binding of siRNA and thereby lead to heterochromatin formation defects that we observed. Our data on the SpAgo1 V324 mutant shows conditional centromeric heterochromatin formation confirmed by semi quantitative RT-PCR for dh transcripts levels that shows temperature dependent increase in these transcripts. We find reduced H3K9Me2 levels at dh locus by chromatin immunoprecipitation (ChIP) assay, linking the association of siRNAs for establishment of heterochromatin at this loci. The data on PTGS of GFP transcripts show SpAgo1 V324G mutation has decreased slicing activity as semi-quantitative RT-PCR for GFP transcripts show increased levels at non permissive temperature. These studies point out the importance of siRNA binding to the PAZ domain and its effect on slicing activity of SpAgo1. The mutations in Y292 showed residue loss of centromeric heterochromatin formation phenotype. Thus, we ascribe critical siRNA binding and 3’ end recognition functions to this residue of SpAgo1. These studies point out functional and structural conservation across hAgo1 and SpAgo1. Adopting the aforementioned biophysical mutational approach, we generated mutants in spdcr1+ and screened for those with conditional activity. Our modeling studies on SpDcr1 helicase domain shows it adopts the conserved helicase domain structure seen for other DEAD Box helicases. Our data on mutational analysis of a conserved buried residue I143 in the walker motif B created inactive protein. The data confirm critical functions for dicer in generation of siRNAs and also in recognition of dsRNA ends. Mutants in buried residues L1130 and I1228 of RNase IIIb domain were inactive and the proximity of these residues to the catalytic core suggest that the critical structural alignment of catalytic residues is indispensable for carrying out dsRNA cleavage to generate siRNAs. We also attribute critical catalytic functions to SpDcr1 D1185 residue for generation of siRNA and heterochromatin formation as measured by our transcriptional gene silencing assay. Our studies employing biophysical and computational approaches to design temperature-sensitive mutants have been successfully applied to an essential splicing factor SpPrp18, which was refractory for ts mutants by other methods. Using a missense mutant, we showed its intron-specific splicing function for subsets of transcripts and deduced that its ubiquitous splicing role is arguable. We have uncovered a link between the splicing substrates of SpPrp18 and direct evidence of splicing based cell cycle regulation, thus providing a mechanistic link to the cell cycle arrest seen in some splicing factor mutants. The same methodology was applied to another important biological pathway, the RNAi machinery, where central factors SpAgoI and SpDcrI were examined We report the first instance of conditional gene silencing tool by designing Ago1 ts mutants which will be useful for future studies of the global interaction network between RNAi and other RNA processing events.

RNA Splicing

Cell Cycle

Schizosaccharomyces Pombe

RNA Interference

RNA Transcription

Temperature Sensitive Mutants

Fission Yeast Genes

Missense Mutants

Fission Yeast Pre-mRNA Splicing

Heterochromatin

Yeast SpPrp18

Cell Cycle Progression

Yeast SpSlu7

Microbiology and Cell Biology

Effet du changement climatique sur la réponse des plantes et des pathogènes, lors du développement de la maladie racinaire provoquée par les champignons pathogènes du sol du genre verticillium, chez deux espèces du genre médicago / Effect of climate change on the response and plant pathogens during the development of root disease caused by pathogenic fungisoil of verticillium genus in two species of the medicago genus

Sbeiti, Abed al latiff

23 September 2016

Nous nous sommes intéressés à évaluer l'influence du changement climatique sur les patrons nets de réponse des plantes aux agents pathogènes. Dans ce travail, nous avons étudié les effets de l’augmentation de la température (20°, 25° et 28°C) sur le phénotype précoces (symptômes de maladie) et sur la fitness en fin de cycle de différentes accessions et mutants de nodulation de la plante légumineuse modèle Medicago truncatula, inoculées par des souches d’agent pathogène racinaire Verticillium adaptées à des différentes températures. Le comportement des variétés de Luzerne cultivée (Medicago sativa) dans ces conditions a été également analysé. Le travail a été divisé en 3 parties. La première partie nous a permis d’identifier parmi 12 souches de Verticillium spp., une souche froide (VA1) et une souche tempérée (V31.2), avec une température optimale de 20°C et 25°C respectivement pour la croissance, la sporulation et l'agressivité sur M. truncatula. Par contre, notre collection des souches ne renfermant pas de souches adaptées à des températures plus élevées. Nous avons obtenu par mutagénèse UV de la souche V31.2 une troisième souche (AS38) chaude qui est agressive à 28°C. Dans la deuxième partie nous avons observé les symptômes de maladie pour sept accessions naturelles de M. truncatula, inoculées par ces trois souches d’agent pathogène, à trois températures 20°, 25° et 28°C et en présence de la souche Sinorhizobium meliloti RCR2011. De faibles symptômes ont été relevés pour deux accessions A17 et DZA315.16 inoculées par VA1 à 20°C. Nous avons observé une sensibilité maximale pour trois accessions (F83005.5, DZA315.16 et L321) inoculées par V31.2 à 25°C, et pour quatre accessions (F83005.5, DZA315.16, L321 et L198) inoculées par AS38 à 28°C. Les résultats des symptômes de maladie ont été confirmés par une quantification moléculaire de l’ADN fongique (qPCR) et par ré-isolement à partir des tissus aériens de la plante. L’effet de VA1 et V31.2 sur trois caractères de fitness (nombre et poids de gousse par plante, ainsi que biomasse aérienne) de M. truncatula a été étudié. L’effet de VA1 s’observe uniquement à 20°C sur l'accession A17. Par contre, V31.2 a montré un impact sur les trois caractères de fitness qui diminuent chez les accessions sensibles, ainsi que sur le nombre de gousse pour l’accession résistante L198. Dans la troisième partie nous avons analysé de la même façon pour quatre mutants de nodulation dans le fond génétique A17. Les mutants ont montré un niveau de résistance à la souche VA1 plus élevé qu’A17, quelle que soit la température étudiée. Vis à vis de la souche V31.2, à 20°C les mutants skl et hcl ont montré le même taux de symptômes qu’A17 tandis que les mutants nfp et sunn ont de taux de symptômes supérieur à celui d'A17. Ces mutants ont tous une sensibilité plus élevé à 25°C. Les résultats des symptômes de maladie ont été confirmés par le test de ré-isolement. Pour ces mutants nous montrons pour la première fois, que seul le mutant sunn (hypernodulant) à la même productivité qu’A17, quelle que soit la condition (contrôle ou inoculées) et la souche (VA1 ou V31.2) étudiée ; alors que le mutant skl (hypernodulant également) a une productivité plus faible. Les deux autres mutants déficients dans la nodulation nfp et hcl ont montré une productivité plus faible qu’A17 quelle que soit la souche et la température étudiée. Enfin une bonne similitude a été trouvée entre la réponse phénotypique précoce (symptômes de maladie) de M. truncatula et de M. sativa inoculées par Verticillium spp. Dans cette thèse, on n’est pas trouvé la corrélation positive entre la capacité de la nodulation et la protection contre la maladie, mais la symbiose augmente la fitness pour certaines de ces plantes. Les résultats suggèrent aussi que l'augmentation de la température pourrait contribuer à faire apparaître une souche adaptée à 28°C (AS38) qui est plus agressive et plus virulente que V31.2 sur M. truncatula. / We were interested to evaluate the influence of climate change on net patterns of plants responses to pathogens. In this work, we studied the effects of temperature increase (20 °, 25 ° and 28 ° C) on early phenotype (symptoms of disease) and on fitness at the end of growth cycle on different accessions and nodulation mutants of the legume model plant Medicago truncatula, inoculated by the root pathogen Verticillium adapted to different temperatures. The behavior of cultivated varieties of alfalfa (Medicago sativa) in these conditions was also analyzed. The work is divided into 3 parts. In the first part, we identified among 12 strains of Verticillium spp., a cold strain (VA1) and a temperate strain (V31.2) with an optimum temperature of growth, sporulation and aggressiveness to M. truncatula of 20°C and 25°C respectively. Since our strain collection doesn’t contain strains adapted to higher temperatures, we have obtained by UV mutagenesis of strain V31.2 a third strain (AS38), considered as a ‘hot’ strain, which is aggressive at 28°C. In the second part, we observed the symptoms of disease on seven natural accessions of M. truncatula, inoculated by the three strains of the pathogen at three temperatures 20°C, 25°C and 28°C in the presence of Sinorhizobium meliloti RCR2011. Mild symptoms were observed for two accessions A17 and DZA315.16 inoculated with VA1 at 20°C. We observed a maximal sensitivity for three accessions (F83005.5, DZA315.16 and L321) inoculated with V31.2 at 25 ° C, and for four accessions (F83005.5, DZA315.16, L321 and L198) inoculated with AS38 at 28 ° C. The results of phenotypic disease symptoms were confirmed by molecular quantification of fungal DNA (qPCR), and re-isolation of the fungus from aerial plant tissues. The effect of strains VA1 and V31.2 on three fitness traits (number and weight of pods per plant and aerial biomass) was studied. The effect negative of VA1 was observed only at 20°C on the A17 accession. In contrast, V31.2 showed an impact on the three fitness traits, which decrease in susceptible accessions, as well as on pod number of the resistant accession L198. In the third part, a similar analysis was made for four nodulation mutants in A17 genetic background. Nodulation mutants showed a higher level of resistance to VA1 than A17, at different studied temperatures. Towards strain V31.2 at 20°C the mutants skl and hcl showed the same symptom scores as A17 whereas nfp and sunn mutants had more susceptible. Mutants showed a higher sensitivity at 25°C to V31.2 fungal strain. The results of phenotypic disease symptoms were confirmed by re-isolation experiments. For the nodulation mutants we showed, for the first time, that only the sunn mutant (hypernodulant) has the same productivity as A17, regardless of the condition (inoculated or control) and the studied strain (VA1 or V31.2); while the skl mutant (hypernodulant also) has a lower productivity. The other two mutants defective in nodulation (nfp and hcl) showed lower productivity than A17 regardless of the strain (VA1 or V31.2) and the temperature studied. Finally, a strong similarity was found between the early phenotypic response symptoms disease in M. truncatula and M. sativa inoculated by Verticillium spp. In this thesis, we didn’t find a positive correlation between the ability of nodulation and protection against the disease, however the symbiosis increases the fitness of some of these plants. The results also suggest that increasing temperatures could favour appearance a strain adapted to 28°C (AS38), which is more aggressive and more virulent than V31.2 on M. truncatula.

Changement climatique

Fitness

Medicago sativa

Medicago truncatula

Mutagénèse

Mutants de nodulation

Réponse phénotypique

Verticillium spp

Réponse précoce

Climate change

Fitness

Medicago sativa

Medicago truncatula

Mutagenesis

Mutants nodulation

Phenotypic response

Verticillium spp

Response precoce

Characterization of Pea (Pisum Sativum L.) genes implicated in arbuscular mycorrhiza formation and function / Caractérisation de gènes de pois (Pisum sativum L.) impliqués dans la formation et le fonctionnement de la mycorhize à arbuscules

Kuznetsova, Elena Vladislavovna

21 October 2010

L’association mycorhizienne à arbuscules (AM) est le résultat d’une interaction compatible entre les génomes des deux partenaires symbiotiques. Dans ce contexte, le but de mes recherches a été de mieux caractériser le rôle des gènes de pois liés aux stades tardifs de la symbiose, PsSym36, PsSym33 and PsSym40, dans le fonctionnement de la symbiose MA (i) en étudiant l’effet des mutations de ces trois gènes sur l’expression des gènes de la plante et du champignon, et (ii) en créant les conditions pour positionner deux de ces gènes, PsSym36 and PsSym40, sur la carte génétique afin d’envisager leur clonage futur. L’expression d’un groupe de dix gènes fongiques et de huit gènes de plante, déjà décrits pour être activés durant le développement de la mycorhize, a été comparée dans les racines de pois inoculées avec G. intraradices chez les plantes de génotypes sauvages, ou les mutants Pssym36, Pssym33 et Pssym40. L’expression de la plupart des gènes fongiques a été inhibée dans les racines du mutant Pssym36 où la formation des arbuscules est avortée, tandis que l’expression de plusieurs d’entre eux a été activée lorsqu’il existe un développement plus rapide du champignon dans les racines du mutant Pssym40. Des microdisséquats obtenus à partir de racines mycorhizées du mutant PsSym40 confirment l’expression préférentielle de trois gènes de G. intraradices (SOD, DESAT et PEPISOM) dans les cellules contenant les arbuscules. L’inactivation du gène PsSym36 provoque également une inhibition des gènes de plante alors que la mutation des gènes PsSym33 and PsSym40 affecte l’expression des gènes de plante plutôt de façon temporelle. Les résultats indiquent ainsi une implication des gènes SYM de pois dans la modulation des interactions moléculaires entre la plante et le champignon impliquées au niveau de la signalisation, des échanges nutritifs ou de la régulation des réponses au stress durant la formation et/ou le fonctionnement de la symbiose AM. Les conditions pour la localisation des gènes PsSym36 and PsSym40 sur la carte génétique du pois ont été développées pour leur clonage basé sur la cartographie. En utilisant les marqueurs moléculaires obtenus, il a été possible de conclure que la localisation du gène PsSym40 réside vraisemblablement à l’extérieur des groupes de liaison I, II, III ou V de la carte génétique du pois. / The arbuscular mycorrhizal (AM) association results from a successful interaction between the genomes of the two symbiotic partners. In this context, the aim of my research was to better characterize the role of the late stage symbiosis-related pea genes PsSym36, PsSym33 and PsSym40 in the functional AM (i) by investigating the effect of mutations in the three genes on fungal and plant gene responses and (ii) by creating conditions for the localization of two of the genes, PsSym36 and PsSym40, on the pea genetic map for future map-based cloning. The expression of a subset of ten fungal and eight plant genes,previously reported to be activated during mycorrhiza development, was compared in Glomus intraradices-inoculated roots of wild type and Pssym36, Pssym33 and Pssym40 mutant pea plants. Most of the fungal genes were down-regulated in roots of the Pssym36 mutant where arbuscule formation is defective, and several were upregulated with more rapid fungal development in roots of the Pssym40 mutant. Microdissection of mycorrhizal PsSym40 roots corroborated preferential expression of the three G. intraradices genes SOD, DESAT and PEPISOM in arbuscule-containing cells. Inactivation of PsSym36 also resulted in down regulation of plant genes whilst mutation of the PsSym33 and PsSym40 genes affected plant gene responses in a more time-dependent way. Results thus indicate an implication of the investigated pea SYM genes in the modulation of plant and fungal molecular interactions linked to signaling, nutrient exchange or stress response regulation during AM symbiosis formation and functioning. Conditions for localization of the PsSym36 and PsSym40 genes on the pea genetic map were developed for their future map-based cloning. Based on the molecular markers obtained, it was possible to conclude that localization of the PsSym40 gene most likely resides outside the linkage groups I, II, III or V of the genetic map of pea. / Формирование арбускулярной микоризы (АМ) является результатом успешного взаимодействия между геномами двух симбиотических партнёров. Целью моего исследования являлось изучение роли поздних симбиотических генов гороха PsSym36, PsSym33 и PsSym40 в формировании функционального АМ симбиоза. Для этого было проведено исследование эффекта мутаций в генах PsSym36, PsSym33 и PsSym40 на экспрессию грибных и растительных генов, предположительно (по литературным данным) вовлечённых в процессы формирования АМ, а так же проведена работа по локализации генов PsSym36 и PsSym40 на генетической карте гороха для последующего более точного картирования и позиционного клонирования данных генов. Экспрессия десяти грибных и восьми растительных генов была определена в корнях растений дикого типа и PsSym36, PsSym33 и PsSym40 мутантов, инокулированных G. intraradices. В корнях PsSym36 мутанта, имеющего дефект развития арбускул, большая часть грибных генов была супрессирована, в то время как в корнях PsSym40 мутанта, для которого характерна более быстрая по сравнению с диким типом микоризация, был отмечен более высокий уровень экспрессии грибных генов. Использование метода микродиссекций позволило выделить клетки, содержащие арбускулы, из микоризованных корней мутанта PsSym40 и подтвердить, что гены G. intraradices SOD, DESAT и PEPISOM преимущественно экспрессируются в клетках, содержащих арбускулы. Мутация в гене PsSym36 также привела к подавлению экспрессии большинства вовлечённых в анализ растительных генов, тогда как мутации в генах PsSym33 и PsSym40 оказали влияние на ксперессию растительных генов в меньшей степени. Полученные результаты свидетельствуют о роли исследуемых SYM генов гороха в контролировании растительно-грибных молекулярных взаимодействий, связанных с сигналингом, обменом питательными веществами и стрессовыми реакциями в процессе формирования и функционирования АМ симбиоза. Проведённое генетическое картирование не привело к локализации генов PsSym36 и PsSym40 на генетической карте гороха. Однако разработка и использование молекулярных маркеров для картирования позволили исключить локализацию гена PsSym40 в I, II, III и V группах сцепления с высокой долей вероятности.

Mycorhizes à arbuscules

Glomus intraradices

Pisum sativum

Gènes végétaux de symbiose

Mutants végétaux

Cartographie génétique

Arbuscular mycorrhiza

Glomus intraradices

Pisum sativum

Symbiosis related plant genes

Plant mutants

Fungal and plant gene expression

Genetic mapping

572.8

Geração e caracterização de linhagens isogênicas portadoras de mutantes de p53: modelo para avaliar a estratégia de reparação dos genes p53 e p16 INK4A na presença dos mutantes p53R175H e p53R248Q. / Generation and characterization of isogenic cell lines harboring p53 mutants: a model for the evaluation of p53 and p16INK4A replacement in the presence of p53R175H and p53R248Q.

Souza, Felipe da Costa

30 March 2012

A destruição funcional das vias de controle do ciclo celular constituem um evento comuns em todos os tumores humanos. Muitos estudos associam mutações em p53 com mau prognostico no tratamento do câncer. Nesse trabalho, visamos a geração e caracterização de linhagens isogênicas portando diferentes mutantes de p53 como modelo de estudo para remediação simultânea de p53 e p16 na presença de mutantes hotspots específicos. Os mutantes R175H e R248Q não geraram alterações na cinética de proliferação da linhagem H358, mas levaram a um aumento de 27,5% na eficiência de plaqueamento e, no caso de R248Q, ao dobro de eficiência na formação de colônias em suspensão. Os resultados do tratamento das linhagens isogênicas com adenovírus Adp16 e Adp53 mostraram que os mutantes não interferiram no parada do ciclo celular em G1 induzida por p16. / Alterations of the cell cycle pathway are a common event in all human tumors. Several studies have shown a correlation between hotspot mutations and an unfavorable profile for cancer therapies. Hence, this study aims the generation and characterization of isogenic cell lines, harboring p53 mutants, as model to investigate the replacement of p53 and p16 genes on these mutant H358 cell lines. Our data identified that neither p53R175H nor p53R248Q mutants accelerated cell cycle progression. However, both leads to a 27,5% increased plate efficiency while R248Q leads to a two-fold increases in the number of colonies formed in soft agar. Our data also showed that the mutants did not affect the efficiency of p16 replacement.

Adenovirus

Adenovírus

Cell cycle

Ciclo celular

Cinética

DNA repair

Kinetics

Mutantes de P53

Mutants of p53

Neoplasias

Neoplasms

Reparação de DNA

Envolvimento da giberelina na regulação do desenvolvimento vegetativo e reprodutivo de tomateiro (Solanum lycopersicum) cv Micro-Tom / Involvement of gibberellin in regulating of vegetative and reproductive growth of tomato (Solanum lycopersicum L.) cv Micro-Tom

Farinha, Tatiana Bistaco

28 January 2009

As giberelinas (GAs) são bem conhecidas pelo seu papel no alongamento do caule, germinação de sementes, desenvolvimento dos frutos e florescimento em plantas de dia longo. Apesar de boa parte das plantas de interesse agronômico não possuírem resposta fotoperiódica, há poucos estudos sob a possibilidade dessa classe hormonal estar envolvida em processos de florescimento e frutificação em plantas de dia neutro, como é o caso do tomateiro. O principal objetivo do trabalho foi avaliar a importância da via de indução por giberelina para o crescimento vegetativo e reprodutivo em Solanum lycopersicum cv Micro-tom (MT). Para tal, foram utilizados tratamentos exógenos com GA ou um inibidor de sua síntese, paclobutrazol (paclo), em diferentes estágios do desenvolvimento de MT. Os mutantes pro e gib3, os quais são supersensíveis e deficientes a GA, respectivamente, também foram utilizados para análises comparativas. Avaliou-se o tempo para 50% das plantas apresentarem botões florais visíveis a olho nu, tempo para antese, altura e número de entrenós na antese, número de frutos, massa média e total dos frutos e brix. O tratamento com 5 aplicações de paclo ao longo do ciclo levou a uma extensão do desenvolvimento vegetativo, com um atraso significativo na floração. No tratamento que recebeu aplicação de paclo 16 dias após semeadura, mesmo com a planta apresentando uma redução na altura, houve um restabelecimento de seu desenvolvimento reprodutivo, tornando este superior ao controle em termos de tamanho do fruto. Para o tratamento com aplicação de GA aos 16 dias, obteve-se um aumento no brix comparado ao controle. Por outro lado, o mutante procera, por possuir um crescimento vegetativo (altura e número de entrenós na antese) bem superior ao controle MT, teve seu crescimento reprodutivo prejudicado. Estes resultados nos levaram a concluir que embora GA possa induzir diretamente o florescimento e a frutificação de tomateiro, ela também pode reprimir esses processos, provavelmente deslocando o dreno para o crescimento vegetativo. Sendo assim, tanto a aplicação de GA quanto de paclo, se feitas em determinado estágio do desenvolvimento, podem melhorar a qualidade do fruto de tomateiro, aumentando o tamanho dos frutos ou o brix. / The gibberellins (GAs) are well known for their roles in stem elongation, seed germination, fruit development and flowering induction in long day plants. Despite the fact that many plants of agronomic interest do not respond to photoperiod, there are few studies about the possibility of this hormonal class to be involved in the process of flowering and fruit formation in photoperiod-insensitive plants, such as tomato. The main objective of this study was to evaluate the importance of the GA induction pathway for the vegetative and reproductive growth of Solanum lycopersicum cv Micro-Tom (MT). To accomplish this, we performed exogenous application of GA, or an inhibitor of its biosynthesis, paclobutrazol (paclo), at different stages of MT development. The mutants pro and gib3, which are hypersensitive and deficient in GA, respectively, were also used for comparative analysis. It was evaluated the time spent for 50% of plants presenting visible flower buds, the time to anthesis, plant height and the number of internodes at anthesis, number of fruits, total and individual fruit weight and fruit brix. The treatment that received five paclo applications during the life cycle presented stunted vegetative growth, which also reflected in a significant flowering delay. In the treatment that received paclo at 16th day after sowing, there was a reduction in plant height, but its reproductive development was resumed yielding fruit size superior to the control. Conversely, the treatment that received GA at 16th presented fruits with higher brix, compared to the control. Furthermore, the mutant pro, which had a vegetative growth higher than the control (in terms of plant height and number of internodes at anthesis), showed a reduced reproductive growth. These results drove us to the conclusion that although GA can directly induce flower and fruit development in tomato, it also can arrest these processes, probably redirecting the sink for vegetative growth. Thus, both GA and paclo applications, if made in a certain stage of plant development, can improve the quality of tomato fruit, increasing fruit size or brix.

Desenvolvimento vegetal

Flowering

Fruit formation

Frutificação

Gibberellin

Giberelina

Hormones

Hormonios vegetais

Mutaçã vegetal

Mutants.

Paclobutrazol

Productivity

Reprodução vegetal

Tomate.

Tomato

Migration of neural crest cells in normal ICR mouse and mutant dominant megacolon mouse embryos.

January 2001

Mok Wing Fai Simon. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2001. / Includes bibliographical references (leaves 91-97). / Abstracts in English and Chinese. / Abstract (English) --- p.i / Abstract (Chinese) --- p.iii / Acknowledgements --- p.iv / Table of content --- p.v / List of Figures --- p.viii / List of Tables --- p.x / Chapter CHAPTER ONE: --- INTRODUCTION / Chapter 1.1 --- Origin of the Neural Crest Cells / Chapter 1.1.1 --- Formation of the Neural Tube --- p.1 / Chapter 1.1.2 --- The Neural Crest cells and the Vagal Neural Crest Cells --- p.2 / Chapter 1.1.3 --- The migration profiles of Neural Crest Cells Originated from the Axial level other than Vagal Neural Crest --- p.4 / Chapter 1.1.4 --- Development of the Gastrointestinal Tract and the Enteric Nervous System --- p.5 / Chapter CHAPTER TWO: --- MIGRATION OF NEURAL CREST CELLS IN NORMAL ICR AND DOM MUTANT MOUSE EMBRYOS / Chapter 2.1 --- Introduction --- p.27 / Chapter 2.2 --- Materials / Chapter 2.2.1 --- Pregnant mice --- p.39 / Chapter 2.2.2 --- The Handling Medium --- p.39 / Chapter 2.2.3 --- The Culture Medium --- p.40 / Chapter 2.2.4 --- Preparation of Wheat Germ Agglutinin-Gold Conjugates (WGA-Au) --- p.42 / Chapter 2.2.5 --- "Preparation of 1,´1ة-dioctadecyl-´3ة 3,3 '3,3 226}0ة-tetramethyl indocarbocyanine perchlorate (Di-I) " --- p.43 / Chapter 2.2.6 --- Preparation of Carnoýةs Solution --- p.43 / Chapter 2.2.7 --- Preparation of Paraformaldehyde --- p.43 / Chapter 2.2.8 --- Pregnont Dominant Megacolon (Dom) Mice --- p.44 / Chapter 2.2.9 --- DNA Extraction for Genotyping of Dom Embryos --- p.45 / Chapter 2.2.10 --- Primers Used in PCR for Genotyping of Dom Embryos --- p.45 / Chapter 2.2.11 --- PCR Reagent System --- p.46 / Chapter 2.2.12 --- 10XTBE --- p.46 / Chapter 2.3 --- Methods / Chapter 2.3.1 --- Isolation of Embryos from Pregnant Mice --- p.47 / Chapter 2.3.2 --- In situ labeling of exogenous dye --- p.48 / Chapter 2.3.3 --- Whole Embryo Culture --- p.49 / Chapter 2.3.4 --- Morphological Examination of Cultured Embryos --- p.49 / Chapter 2.3.5 --- Histological Examination of Cultured embryos --- p.50 / Chapter 2.3.6 --- Genotyping of Dom F1 Generation --- p.51 / Chapter 2.3.7 --- Genotyping of Dom Embryos by PCR --- p.52 / Chapter 2.3.8 --- Gel Electrophoresis --- p.52 / Chapter 2.3.9 --- Counting of WGA-Au Labelled Cells --- p.53 / Chapter 2.4 --- Results / Chapter 2.4.1 --- Genotyping --- p.54 / Chapter 2.4.2 --- Examination on Gross morphology of Control and Experimental Embryos --- p.54 / Chapter 2.4.3 --- Morphological Examination of DOM Mutant Embryo after culture --- p.57 / Chapter 2.4.4 --- Initial Stage of Vagal and Trunk Neural Crest Cells Migration in Mouse Embryos --- p.62 / Chapter 2.4.5 --- Initial Stage of Vagal and Trunk Neural Crest Cells Migration in DOM Embryos --- p.64 / Chapter 2.4.6 --- Distribution of Labelled Cells in ICR Embryos after WGA-Au Labelling --- p.65 / Chapter 2.4.7 --- Distribution of WGA-Au Labelled Cells in DOM Embryos --- p.69 / Chapter CHAPTER THREE: --- DISCUSSION / Chapter 3.1 --- Development of embryos in vitro --- p.78 / Chapter 3.2 --- Comparison of the Two Exogenous Dyes --- p.80 / Chapter 3.3 --- Migration Pathway of the Vagal and Trunk Neural Crest Cells --- p.81 / Chapter 3.4 --- Counting of Labelled Cells in DOM Embryos --- p.83 / Chapter 3.5 --- Initial Stage of Vagal and Trunk Neural Crest Cells Migration of Different Genotypes of the DOM Embryos --- p.84 / Chapter 3.6 --- Differences in Distribution of WGA-Au Labelled Cells in Different Genotypes of DOM Embryos --- p.85 / Chapter CHAPTER FOUR: --- CONCLUSION --- p.88 / REFERENCES --- p.91 / "FIGURES, LEGEND TABLE AND APPENDIX"

Neural Crest

Cell Movement

Nervous System--embryology

Nervous System--growth & development

Mice, Inbred ICR--embryology

Mice, Neurologic Mutants--embryology