Your search keyword '"Ellis, Noel"' showing total 21 results

1. Do Transcription Factors Play Special Roles in Adaptive Variation?

Author

Martin, Cathie, Ellis, Noel, and Rook, Fred

Subjects

*TRANSCRIPTION factors, *PLANT physiology, *GENETIC transcription, *PROTEIN binding, *PROMOTERS (Genetics)

Abstract

The article examines research on the role of plant transcription factors (TF) in adaptive variation. Control of genetic transcription is attributed to the combined activity of multiple TF binding to cis-elements in their promoters. Strategies for engineering plants in the future are expected to be influenced by the possible evolution of phenotypic variation through changes in genes encoding lower-order TF. It suggests exploring lower-order regulators of cell development and metabolism to engineer plant traits.

Published

2010

2. Highly Stereoselective Synthesis of cis-Alkenyl Pinacolboronates and Potassium cis-Alkenyltrifluoroborates via a Hydroboration/ Protodeboronation Approach.

Author

Molander, Gary A. and Ellis, Noel M.

Subjects

*ORGANOBORON compounds, *ORGANIC synthesis, *ORGANOFLUORINE compounds, *BORATES, *ACETIC acid

Abstract

A number of alkynyl pinacolboronates bearing various functional groups were synthesized according to literature methods. These were then stereose][ectively reduced to the cis-alkenyl pinacolboronates via hydroboration with dicyclohexylborane followed by chemoselective protodeboronation using acetic acid. Treatment with potassium hydrogen fluoride smoothly converted these to the corresponding potassium organotrifluoroborates. [ABSTRACT FROM AUTHOR]

Published

2008

3. Using bioinformatics to analyse germplasm collections.

Author

Davenport, Guy, Ellis, Noel, Ambrose, Mike, and Dicks, Jo

Subjects

*GERMPLASM, *BIOINFORMATICS, *MICROSATELLITE repeats, *GENETIC markers, *CROP genetics, *PLANT diversity

Abstract

In the last few years, we have seen a growing emphasis on the characterisation of germplasm collections by molecular markers such as microsatellites, AFLPs, SSAPs, RBIPs and SNPs. This emphasis has served to enhance the use of germplasm collections in crop improvement via plant breeding while also aiding the management of collections themselves through an improved understanding of the relationships between accessions and underlying patterns of diversity. With the new data sets becoming available comes the recognition of the role that bioinformatics can play in making the most of the data. The basis of the new bioinformatics infrastructure is databases that enable the association of passport and trait data with molecular markers. Visualisation tools enable us to view large quantities of these data simultaneously and to tease out patterns underlying our data sets. We also need analytical tools to help us search for trait-marker or haplotype-marker associations and to look for patterns of genetic diversity. Most importantly, all of these components should interact in a fluid and intuitive manner such that the developers of germplasm collections and the plant genetics and breeding communities can access and manipulate the data. Here, we focus on the development of new bioinformatics tools for germplasm analysis within two projects: GENE-MINE and GERMINATE. We look at different aspects of our bioinformatics infrastructure, to give a sense of the powerful analyses that bioinformatics can facilitate. Finally, we look forward to bringing together these different areas to the benefit of the plant breeding and genetic resources communities. [ABSTRACT FROM AUTHOR]

Published

2004

4. Conservation and diversification of gene function in plant development

Author

Hofer, Julie and Ellis, Noel

Subjects

*ARABIDOPSIS, *ANGIOSPERMS, *PLANT genetics, *PLANT development

Abstract

The Arabidopsis genome sequence has given us an inventory of the genes needed to specify a flowering plant. Plants are highly diverse in appearance and the mechanisms whereby this diversity has arisen need explanation. A fundamental question is to what extent diversity arises from remodelling of gene function or relocation of gene pathways, rather than from the gain or loss of genes. Similar types of genetic rewiring may be responsible for both intra- and inter-specific differences in developmental processes. Recent advances in the understanding of shoot, flower and leaf development provide insights to this question. [Copyright &y& Elsevier]

Published

2002

5. Linchpin Synthons: Metalation of Aryl Bromides Bearing a Potassium Trifluoroborate Moiety.

Author

Molander, Gary A. and Ellis, Noel M.

Subjects

*BROMIDES, *BROMINE compounds, *POTASSIUM, *BORATES, *HALOGENS, *NONMETALS

Abstract

Aryl bromides bearing a potassium trifluoroborate moiety were subjected to lithium-halogen exchange at low temperature using a variety of alkyllithium reagents. A number of different electrophiles were evaluated in their reactions with the aryllithiums produced therein. Under carefully optimized conditions, potassium bromophenyl trifluoroborates afforded good to excellent yields of the corresponding alcohols (64-94% isolated yield) when aldehydes or ketones were used as the electophilic partner. Esters were unfortunately found to be unreactive. [ABSTRACT FROM AUTHOR]

Published

2006

6. afila, the origin and nature of a major innovation in the history of pea breeding.

Author

Tayeh, Nadim, Hofer, Julie M. I., Aubert, Grégoire, Jacquin, Françoise, Turner, Lynda, Kreplak, Jonathan, Paajanen, Pirita, Le Signor, Christine, Dalmais, Marion, Pflieger, Stéphanie, Geffroy, Valérie, Ellis, Noel, and Burstin, Judith

Subjects

*COMPARATIVE genomics, *PHENOTYPES, *CROP improvement, *HAPLOTYPES, *ZINC-finger proteins, *PEAS

Abstract

Summary: The afila (af) mutation causes the replacement of leaflets by a branched mass of tendrils in the compound leaves of pea – Pisum sativum L. This mutation was first described in 1953, and several reports of spontaneous af mutations and induced mutants with a similar phenotype exist. Despite widespread introgression into breeding material, the nature of af and the origin of the alleles used remain unknown.Here, we combine comparative genomics with reverse genetic approaches to elucidate the genetic determinants of af. We also investigate haplotype diversity using a set of AfAf and afaf cultivars and breeding lines and molecular markers linked to seven consecutive genes.Our results show that deletion of two tandemly arranged genes encoding Q‐type Cys(2)His(2) zinc finger transcription factors, PsPALM1a and PsPALM1b, is responsible for the af phenotype in pea. Eight haplotypes were identified in the af‐harbouring genomic region on chromosome 2. These haplotypes differ in the size of the deletion, covering more or less genes.Diversity at the af locus is valuable for crop improvement and sheds light on the history of pea breeding for improved standing ability. The results will be used to understand the function of PsPALM1a/b and to transfer the knowledge for innovation in related crops. [ABSTRACT FROM AUTHOR]

Published

2024

7. Synthesis of an Acyltrifluoroborate and Its Fusion with Azides To Form Amides.

Author

Molander, Gary A., Raushel, Jessica, and Ellis, Noel M.

Subjects

*AZIDES, *AMIDES, *LEWIS acids, *CHEMICAL reagents, *CHEMICAL reactions

Abstract

A uniquely stable acyl potassium trifluoroborate, potassium (2-phenylacetyl)trifluoroborate, has been synthesized and isolated. In the presence of an activating Lewis acid, this reagent reacts with azides to form amides in good yields. [ABSTRACT FROM AUTHOR]

Published

2010

8. Recombinant inbred lines derived from cultivars of pea for understanding the genetic basis of variation in breeders' traits.

Author

Moreau, Carol, Knox, Maggie, Turner, Lynda, Rayner, Tracey, Thomas, Jane, Philpott, Haidee, Belcher, Steve, Fox, Keith, Ellis, Noel, and Domoney, Claire

Subjects

*PIGEON pea, *PLANT breeding, *CROP yields, *CULTIVARS, *PLANT genetics, *GENETIC polymorphisms

Abstract

In order to gain an understanding of the genetic basis of traits of interest to breeders, the pea varieties Brutus, Enigma and Kahuna were selected, based on measures of their phenotypic and genotypic differences, for the construction of recombinant inbred populations. Reciprocal crosses were carried out for each of the three pairs, and over 200 F2 seeds from each cross advanced to F13. Bulked F7 seeds were used to generate F8–F11 bulks, which were grown in triplicated plots within randomized field trials and used to collect phenotypic data, including seed weight and yield traits, over a number of growing seasons. Genetic maps were constructed from the F6 generation to support the analysis of qualitative and quantitative traits and have led to the identification of four major genetic loci involved in seed weight determination and at least one major locus responsible for variation in yield. Three of the seed weight loci, at least one of which has not been described previously, were associated with the marrowfat seed phenotype. For some of the loci identified, candidate genes have been identified. The F13 single seed descent lines are available as a germplasm resource for the legume and pulse crop communities. [ABSTRACT FROM AUTHOR]

Published

2018

9. Genetic Variation Controlling Wrinkled Seed Phenotypes in Pisum: How Lucky Was Mendel?

Author

Rayner, Tracey, Moreau, Carol, Ambrose, Mike, Isaac, Peter G., Ellis, Noel, and Domoney, Claire

Subjects

*PHENOTYPES, *PEA seeds, *GENETIC markers in plants, *INOSITOL, *PLANT germplasm, *SEED coats (Botany)

Abstract

One of the traits studied by Mendel in pea (Pisum sativum L.) was the wrinkled-seeded phenotype, and the molecular basis for a mutation underlying this phenotype was discovered in the 1990s. Although the starch-branching enzyme gene mutation identified at the genetic locus r is most likely to be that in seeds available to Mendel in the mid-1800s, it has remained an open question as to whether or not additional natural mutations in this gene exist within Pisum germplasm collections. Here, we explore this question and show that all but two wrinkled-seeded variants in one such collection correspond to either the mutant allele described previously for the r locus or a mutation at a second genetic locus, rb, affecting the gene encoding the large subunit of Adenosine diphosphoglucose (ADP-glucose) pyrophosphorylase; the molecular basis for the rb mutation is described here. The genetic basis for the phenotype of one (JI 2110) of the two lines which are neither r nor rb has been studied in crosses with a round-seeded variant (JI 281); for which extensive genetic marker data were expected. In marked contrast to the trait studied by Mendel and the rb phenotype; the data suggest that the wrinkled-seeded phenotype in JI 2110 is maternally determined, controlled by two genetic loci, and the extent to which it is manifested is very sensitive to the environment. Metabolite analysis of the cotyledons of JI 2110 revealed a profile for sucrose and sucrose-derived compounds that was more similar to that of wild-type round-seeded, than that of wrinkled-seeded r, pea lines. However, the metabolite profile of the seed coat (testa) of JI 2110 was distinct from that of other round-seeded genotypes tested which, together with analysis of recombinant inbred progeny lines, suggests an explanation for the seed phenotype. [ABSTRACT FROM AUTHOR]

Published

2017

10. Translational Genomics in Agriculture: Some Examples in Grain Legumes.

Author

Varshney, Rajeev K., Kudapa, Himabindu, Pazhamala, Lekha, Chitikineni, Annapurna, Thudi, Mahendar, Bohra, Abhishek, Gaur, Pooran M., Janila, Pasupuleti, Fikre, Asnake, Kimurto, Paul, and Ellis, Noel

Subjects

*PLANT genomes, *LEGUMES, *BIOINFORMATICS, *PLANT species, *PLANT genes

Abstract

Recent advances in genomics and associated disciplines like bioinformatics have made it possible to develop genomic resources, such as large-scale sequence data for any crop species. While these datasets have been proven very useful for the understanding of genome architecture and dynamics as well as facilitating the discovery of genes, an obligation for, and challenge to the scientific community is to translate genome information to develop products, i.e. superior lines for trait(s) of interest. We call this approach, “translational genomics in agriculture” (TGA). TGA is currently in practice for cereal crops, such as maize (Zea mays) and rice (Oryza sativa), mainly in developed countries and by the private sector; progress has been slow for legume crops. Grown globally on 62.8 million ha with a production of 53.2 million tons and a value of nearly 24.2 billion dollars, the majority of these legumes have low crop productivity (<1 ton/ hectare) and are in the developing countries of sub Saharan Africa, Asia and South America. Interestingly, the last five years have seen enormous progress in genomics for these legume crops. Therefore, it is time to implement TGA in legume crops in order to enhance crop productivity and to ensure food security in developing countries. Prospects, as well as some success stories of TGA, in addition to advances in genomics, trait mapping and gene expression analysis are discussed for five leading legume crops, chickpea (Cicer arietinum), common bean (Phaseolus vulgaris), groundnut (Arachis hypogaea), pigeonpea (Cajanus cajan) and soybean (Glycine max). Some efforts have also been outlined to initiate/ accelerate TGA in three additional legume crops namely faba bean (Vicia faba), lentil (Lens culinaris) and pea (Pisum sativum). [ABSTRACT FROM PUBLISHER]

Published

2015

11. Exploiting a fast neutron mutant genetic resource in Pisum sativum (pea) for functional genomics.

Author

Claire, Domoney, Knox, Maggie, Moreau, Carol, Ambrose, Mike, Palmer, Sarah, Smith, Peter, Christodoulou, Vangelis, Isaac, Peter G., Hegarty, Matthew, Blackmore, Tina, Swain, Martin, and Ellis, Noel

Subjects

*FAST neutrons, *PLANT mutation, *PLANT germplasm, *PLANT genomes, PEA genetics

Abstract

A fast neutron (FN)-mutagenised population was generated in Pisum sativum L. (pea) to enable the identification and isolation of genes underlying traits and processes. Studies of several phenotypic traits have clearly demonstrated the utility of the resource by associating gene deletions with phenotype followed by functional tests exploiting additional mutant sources, from both induced and natural variant germplasm. For forward genetic screens, next generation sequencing methodologies provide an opportunity for identifying genes associated with deletions rapidly and systematically. The application of rapid reverse genetic screens of the fast neutron mutant pea population supports conclusions on the frequency of deletions based on phenotype alone. These studies also suggest that large deletions affecting one or more loci can be non-deleterious to the pea genome, yielding mutants that could not be obtained by other means. Deletion mutants affecting genes associated with seed metabolism and storage are providing unique opportunities to identify the products of complex and related gene families, and to study the downstream consequences of such deletions. [ABSTRACT FROM AUTHOR]

Published

2013

12. Conserved genetic determinant of motor organ identity in Medicago truncatula and related legumes.

Author

Jianghua Chen, Moreau, Carol, Yu Liu, Kawaguchi, Masayoshi, Hofer, Julie, Ellis, Noel, and Rujin Chen

Subjects

*MEDICAGO truncatula, *LEGUME genetics, *PLANT cells & tissues, *PLANT physiology, *TRANSCRIPTION factors, *GENE expression

Abstract

Plants exhibit various kinds of movements that have fascinated scientists and the public for centuries. Physiological studies in plants with the so-called motor organ or pulvinus suggest that cells at opposite sides of the pulvinus mediate leaf or leaflet movements by swelling and shrinking. How motor organ identity Is determined is unknown. Using a genetic approach, we isolated a mutant designated elongated petiolulel 1(e/pi) from Medicago truncatula that fails to fold its leaflets in the dark due to loss of motor organs. Map-based cloning indicated that ELP1 encodes a putative plant-specific LOB domain transcription factor. RNA in situ analysis revealed that ELP1 is expressed in primordial cells that give rise to the motor organ. Ectopic expression of ELP1 resulted in dwarf plants with petioles and rachises reduced in length, and the epidermal cells gained characteristics of motor organ epidermal cells. By identifying ELP1 orthologs from other legume species, namely pea (Pisum sativum) and Lotus japonicus, we show that this motor organ identity is regulated by a conserved molecular mechanism. [ABSTRACT FROM AUTHOR]

Published

2012

13. Genetic Background and Agronomic Value of Leaf Types in Pea (Pisum sativum).

Author

Mikić, Aleksandar, Mihailović, Vojislav, Ćupina, Branko, Kosev, Valentin, Warkentin, Tom, McPhee, Kevin, Ambrose, Mike, Hofer, Julie, and Ellis, Noel

Subjects

*AGRONOMY, *LEAVES, *PLANT species, *PEA varieties, *PLANT breeding, *TENDRILS, PEA genetics

Abstract

Pea (Pisum sativum L.) has a compound leaf like many other legume species. The 'semi-leafless' pea (afaf TLTL), with all leaflets transformed into tendrils, is considered one of the most important achievements in pea breeding, due to a significantly enhanced standing ability and equally efficient dry matter production in comparison to normal-leafed genotypes (AFAF TLTL). 'Semi-leafless' cultivars provide high and stable grain yield and are dominant in the modern dry pea production worldwide. There are also 'semi-leafless' cultivars that are autumn-sown and those for forage production. The genotypes with all tendrils transformed into leaflets (AFAF tltl), called 'acacia' or 'tendril-less', are extremely prone to lodging and may have importance in breeding for forage production. Little is known about the potential agronomic value of 'acacia-tendril-less' (afaf tltl) genotypes. [ABSTRACT FROM AUTHOR]

Published

2011

14. Phylogeny, phylogeography and genetic diversity of the Pisum genus.

Author

Smýkal, Petr, Kenicer, Gregory, Flavell, Andrew J., Corander, Jukka, Kosterin, Oleg, Redden, Robert J., Ford, Rebecca, Coyne, Clarice J., Maxted, Nigel, Ambrose, Mike J., and Ellis, Noel T. H.

Subjects

*PLANT phylogeny, *PHYLOGEOGRAPHY, *PLANT diversity, *PISUM, *MICROSATELLITE repeats, *PLANT germplasm

Abstract

The tribe Fabeae (formerly Vicieae) contains some of humanity's most important grain legume crops, namely Lathyrus (grass pea/sweet pea/chickling vetches; about 160 species); Lens (lentils; 4 species); Pisum (peas; 3 species); Vicia (vetches; about 140 species); and the monotypic genus Vavilovia. Reconstructing the phylogenetic relationships within this group is essential for understanding the origin and diversification of these crops. Our study, based on molecular data, has positioned Pisum genetically between Vicia and Lathyrus and shows it to be closely allied to Vavilovia. A study of phylogeography, using a combination of plastid and nuclear markers, suggested that wild pea spread from its centre of origin, the Middle East, eastwards to the Caucasus, Iran and Afghanistan, and westwards to the Mediterranean. To allow for direct data comparison, we utilized model-based Bayesian Analysis of Population structure (BAPS) software on 4429 Pisum accessions from three large world germplasm collections that include both wild and domesticated pea analyzed by retrotransposon-based markers. An analysis of genetic diversity identified separate clusters containing wild material, distinguishing Pisum fulvum, P. elatius and P. abyssinicum, supporting the view of separate species or subspecies. Moreover, accessions of domesticated peas of Afghan, Ethiopian and Chinese origin were distinguished. In addition to revealing the genetic relationships, these results also provided insight into geographical and phylogenetic partitioning of genetic diversity. This study provides the framework for defining global Pisum germplasm diversity as well as suggesting a model for the domestication of the cultivated species. These findings, together with gene-based sequence analysis, show that although introgression from wild species has been common throughout pea domestication, much of the diversity still resides in wild material and could be used further in breeding. Moreover, although existing collections contain over 10,000 pea accessions, effort should be directed towards collecting more wild material in order to preserve the genetic diversity of the species. [ABSTRACT FROM PUBLISHER]

Published

2011

15. An Integrated Linkage Map of Three Recombinant Inbred Populations of Pea (Pisum sativum L.).

Author

Sawada, Chie, Moreau, Carol, Robinson, Gabriel H. J., Steuernagel, Burkhard, Wingen, Luzie U., Cheema, Jitender, Sizer-Coverdale, Ellen, Lloyd, David, Domoney, Claire, and Ellis, Noel

Subjects

*PEAS, *GENE mapping

Abstract

Biparental recombinant inbred line (RIL) populations are sets of genetically stable lines and have a simple population structure that facilitates the dissection of the genetics of interesting traits. On the other hand, populations derived from multiparent intercrosses combine both greater diversity and higher numbers of recombination events than RILs. Here, we describe a simple population structure: a three-way recombinant inbred population combination. This structure was easy to produce and was a compromise between biparental and multiparent populations. We show that this structure had advantages when analyzing cultivar crosses, and could achieve a mapping resolution of a few genes. [ABSTRACT FROM AUTHOR]

Published

2022

16. Tendril-less Regulates Tendril Formation in Pea Leaves.

Author

Hofer, Julie, Turner, Lynda, Moreau, Carol, Ambrose, Mike, Isaac, Peter, Butcher, Susan, Weller, James, Dupin, Adeline, Dalmais, Marion, Le Signor, Christine, Bendahmane, Abdelhafid, and Ellis, Noel

Subjects

*TENDRILS, *PLANT mutation, *LEUCINE zippers, *TRANSCRIPTION factors, *PHYLOGENY, *SWEET peas, *LEGUMES

Abstract

Tendrils are contact-sensitive, filamentous organs that permit climbing plants to tether to their taller neighbors. Tendrilled legume species are grown as field crops, where the tendrils contribute to the physical support of the crop prior to harvest. The homeotic tendril-less (tl) mutation in garden pea (Pisum sativum), identified almost a century ago, transforms tendrils into leaflets. In this study, we used a systematic marker screen of fast neutron-generated tl deletion mutants to identify TI as a Class I homeodomain leucine zipper (HDZIP) transcription factor. We confirmed the tendril-less phenotype as loss of function by targeting induced local lesions in genomes (TILLING) in garden pea and by analysis of the tendril-less phenotype of the t mutant in sweet pea (Lathyrus odoratus). The conversion of tendrils into leaflets in both mutants demonstrates that the pea tendril is a modified leaflet, inhibited from completing laminar development by TI. We provide evidence to show that lamina inhibition requires Unifoliata/LEAFY-mediated TI expression in organs emerging in the distal region of the leaf primordium. Phylogenetic analyses show that TI is an unusual Class I HDZIP protein and that tendrils evolved either once or twice in Papilionoid legumes. We suggest that tendrils arose in the Fabeae clade of Papilionoid legumes through acquisition of the TI gene. [ABSTRACT FROM AUTHOR]

Published

2009

17. Conservation of Arabidopsis Flowering Genes in Model Legumes.

Author

Hecht, Valérie, Foucher, Fabrice, Ferrándiz, Cristina, Macknight, Richard, Navarro, Cristina, Morin, Julie, Vardy, Megan E., Ellis, Noel, Beltrán, José Pío, Rameau, Catherine, and Weller, James L.

Subjects

*ARABIDOPSIS thaliana, *FLOWERING of plants, *PLANT genetics, *LEGUMES, *ROSALES, *PLANT physiology

Abstract

The model plants Arabidopsis (Arabidopsis thaliana) and rice (Oryza sativa) have provided a wealth of information about genes and genetic pathways controlling the flowering process, but little is known about the corresponding pathways in legumes. The garden pea (Pisum sativum) has been used for several decades as a model system for physiological genetics of flowering, but the lack of molecular information about pea flowering genes has prevented direct comparison with other systems. To address this problem, we have searched expressed sequence tag and genome sequence databases to identify flowering-gene-related sequences from Medicago truncatula, soybean (Glycine max), and Lotus japonicus, and isolated corresponding sequences from pea by degenerate-primer polymerase chain reaction and library screening. We found that the majority of Arabidopsis flowering genes are represented in pea and in legume sequence databases, although several gene families, including the MADS-box, CONSTANS, and FLOWERING LOCUS T / TERMINAL FLOWER1 families, appear to have undergone differential expansion, and several important Arabidopsis genes, including FRIGIDA and members of the FLOWERING LOCUS C clade, are conspicuously absent. In several cases, pea and Medicago orthologs are shown to map to conserved map positions, emphasizing the closely syntenic relationship between these two species. These results demonstrate the potential benefit of parallel model systems for an understanding of flowering phenology in crop and model legume species. [ABSTRACT FROM AUTHOR]

Published

2005

18. Estimating genome conservation between crop and model legume species.

Author

Hong-Kyu Choi, Jeong-Hwan Mun, Dong-Jin Kim, Hongyan Zhu, Jong-Min Baek, Mudge, Joanne, Roe, Bruce, Ellis, Noel, Doyle, Jeff, Kiss, Gyorgy B., Young, Nevin D., and Cook, Douglas R.

Subjects

*NITROGEN cycle, *LEGUMES, *GENE mapping, *PHYLOGENY, *CELL nuclei, *GENOMES

Abstract

Legumes are simultaneously one of the largest families of crop plants and a cornerstone in the biological nitrogen cycle. We combined molecular and phylogenetic analyses to evaluate genome conservation both within and between the two major clades of crop legumes. Genetic mapping of orthologous genes identifies broad conservation of genome macrostructure, especially within the galegoid legumes, while also highlighting inferred chromosomal rearrangements that may underlie the variation in chromosome number between these species. As a complement to comparative genetic mapping, we compared sequenced regions of the model legume Medicago truncatula with those of the diploid Lotus japonicus and the polyploid Glycine max. High conservation was observed between the genomes of M. truncatula and L. japonicus, whereas lower levels of conservation were evident between M. truncatula and G. max. In all cases, conserved genome microstructure was punctuated by significant structural divergence, including frequent insertion/deletion of individual genes or groups of genes and lineage-specific expansion/contraction of gene families. These results suggest that comparative mapping may have considerable utility for basic and applied research in the legumes, although its predictive value is likely to be tempered by phylogenetic distance and genome duplication. [ABSTRACT FROM AUTHOR]

Published

2004

19. NMR profiling of transgenic peas.

Author

Charlton, Adrian, Allnutt, Theo, Holmes, Stephen, Chisholm, James, Bean, Samantha, Ellis, Noel, Mullineaux, Phil, and Oehlschlager, Sarah

Subjects

*NUCLEAR magnetic resonance, *TRANSGENIC plants, *PEAS, *GENETICALLY modified foods, *PLANT genetics, *PLANT biotechnology

Abstract

A high throughput proton nuclear magnetic resonance spectroscopy method for the metabolite fingerprinting of plants was applied to genetically modified peas ( Pisum sativum) to determine whether biochemical changes, so called ‘unintended effects’, beyond those intended by incorporation of a transgene, were detectable. Multivariate analysis of 1H NMR (nuclear magnetic resonance) spectra obtained from uniformly grown glasshouse plants revealed differences between the transgenic and control group that exceeded the natural variation of the plants. When a larger data set of six related transgenic lines was analysed, including a null segregant in addition to the wild-type control, multivariate analysis showed that the distribution of metabolites in the transgenics was different from that of the null segregant. However, the profile obtained from the wild-type material was diverse in comparison with both the transgenics and the null segregant, suggesting that the primary cause of the observed differences was that the transformation process selects for a subset of individuals able to undergo the transformation and selection procedures, and that their descendants have a restricted variation in metabolite profile, rather than that the presence of the transgene itself generates these differences. [ABSTRACT FROM AUTHOR]

Published

2004

20. DETERMINATE and LATE FLOWERING Are Two TERMINAL FLOWER1/CENTRORADIALIS Homologs That Control Two Distinct Phases of Flowering Initiation and Development in Pea.

Author

Foucher, Fabrice, Morin, Julie, Courtiade, Juliette, Cadioux, Sandrine, Ellis, Noel, Banfield, Mark J., and Rameau, Catherine

Subjects

*GENES, *FLOWERS, *PLANT species, *SPECIES, *GENE mapping

Abstract

Genes in the TERMINAL FLOWER1 (TFL1)/CENTRORADIALIS family are important key regulatory genes involved in the control of flowering time and floral architecture in several different plant species. To understand the functions of TFL1 homologs in pea, we isolated three TFL1 homologs, which we have designated PsTFL1a, PsTFL1b, and PsTFL1c. By genetic mapping and sequencing of mutant alleles, we demonstrate that PsTFL1a corresponds to the DETERMINATE (DET) gene and PsTFL1c corresponds to the LATE FLOWERING (LF) gene. DET acts to maintain the indeterminacy of the apical meristem during flowering, and consistent with this role, DET expression is limited to the shoot apex after floral initiation. LF delays the induction of flowering by lengthening the vegetative phase, and allelic variation at the LF locus is an important component of natural variation for flowering time in pea. The most severe class of alleles flowers early and carries either a deletion of the entire PsTFL1c gene or an amino acid substitution. Other natural and induced alleles for LF, with an intermediate flowering time phenotype, present no changes in the PsTFL1c amino acid sequence but affect LF transcript level in the shoot apex: low LF transcript levels are correlated with early flowering, and high LF transcript levels are correlated with late flowering. Thus, different TFL1 homologs control two distinct aspects of plant development in pea, whereas a single gene, TFL1, performs both functions in Arabidopsis. These results show that different species have evolved different strategies... [ABSTRACT FROM AUTHOR]

Published

2003

21. The Sym35 Gene Required for Root Nodule Development in Pea Is an Ortholog of Nin from Lotus japonicus[sup1].

Author

Borisov, Alexey Y., Madsen, Lene H., Tsyganov, Viktor E., Umehara, Yosuke, Voroshilova, Vera A., Batagov, Arsen O., Sandal, Niels, Mortensen, Anita, Schauser, Leif, Ellis, Noel, Tikhonovich, Igor A., and Stougaard, Jens

Subjects

*PHENOTYPES, *PEAS, *LOTUS (Genus), *ROOT-tubercles, *GENES

Abstract

Discusses phenotypic analysis of pea sym35 mutants and Lotus japonicus nin mutants. Stages of root nodule formation; Developmental regulation of the PsNin and LjNin genes; Expression of PsNin in the meristematic cells.

Published

2003