126 research outputs found
A 96-well DNase I footprinting screen for drugâDNA interactions
The established protocol for DNase I footprinting has been modified to allow multiple parallel reactions to be rapidly performed in 96-well microtitre plates. By scrutinizing every aspect of the traditional method and making appropriate modifications it has been possible to considerably reduce the time, risk of sample loss and complexity of footprinting, whilst dramatically increasing the yield of data (30-fold). A semi-automated analysis system has also been developed to present footprinting data as an estimate of the binding affinity of each tested compound to any base pair in the assessed DNA sequence, giving an intuitive âone compoundâone lineâ scheme. Here, we demonstrate the screening capabilities of the 96-well assay and the subsequent data analysis using a series of six pyrrolobenzodiazepine-polypyrrole compounds and human Topoisomerase II alpha promoter DNA. The dramatic increase in throughput, quantified data and decreased handling time allow, for the first time, DNase I footprinting to be used as a screening tool to assess DNA-binding agents
QTL associated with resistance to cassava brown streak and cassava mosaic diseases in a bi-parental cross of two Tanzanian farmer varieties, Namikonga and Albert
Cassava production in Africa is compromised by
cassava brown streak disease (CBSD) and cassava mosaic
disease (CMD). To reduce costs and increase the precision
of resistance breeding, a QTL study was conducted to identify molecular markers linked to resistance against
these diseases. A bi-parental F1
mapping population was
developed from a cross between the Tanzanian farmer varieties,
Namikonga and Albert. A one-step genetic linkage
map comprising 943 SNP markers and 18 linkage groups
spanning 1776.2 cM was generated. Phenotypic data from
240 F1
progeny were obtained from two disease hotspots
in Tanzania, over two successive seasons, 2013 and 2014.
Two consistent QTLs linked to resistance to CBSD-induced
root necrosis were identified in Namikonga on chromosomes
II (qCBSDRNFc2Nm) and XI (qCBSDRNc11Nm)
and a putative QTL on chromosome XVIII (qCBSDRNc18Nm).
qCBSDRNFc2Nm was identified at Naliendele
in both seasons. The same QTL was also associated
with CBSD foliar resistance. qCBSDRNc11Nm was identified
at Chambezi in both seasons, and was characterized by
three peaks, spanning a distance of 253 kb. Twenty-seven
genes were identified within this region including two LRR
proteins and a signal recognition particle. In addition, two
highly significant CMD resistance QTL (qCMDc12.1A
and qCMDc12.2A) were detected in Albert, on chromosome
12. Both qCMDc12.1A and qCMDc12.2A lay within the range of markers reported earlier, defining the CMD2
locus. This is the first time that two loci have been identified
within the CMD2 QTL, and in germplasm of apparent
East African origin. Additional QTLs with minor effects on
CBSD and CMD resistance were also identified.The Bill and Melinda Gates Foundation for funding under Contract ID OPPGD1016.http://www.sherpa.ac.uk/romeo/issn/0040-5752/am2017Forestry and Agricultural Biotechnology Institute (FABI)Genetic
Evolution of Disease Response Genes in Loblolly Pine: Insights from Candidate Genes
BACKGROUND: Host-pathogen interactions that may lead to a competitive co-evolution of virulence and resistance mechanisms present an attractive system to study molecular evolution because strong, recent (or even current) selective pressure is expected at many genomic loci. However, it is unclear whether these selective forces would act to preserve existing diversity, promote novel diversity, or reduce linked neutral diversity during rapid fixation of advantageous alleles. In plants, the lack of adaptive immunity places a larger burden on genetic diversity to ensure survival of plant populations. This burden is even greater if the generation time of the plant is much longer than the generation time of the pathogen. METHODOLOGY/PRINCIPAL FINDINGS: Here, we present nucleotide polymorphism and substitution data for 41 candidate genes from the long-lived forest tree loblolly pine, selected primarily for their prospective influences on host-pathogen interactions. This dataset is analyzed together with 15 drought-tolerance and 13 wood-quality genes from previous studies. A wide range of neutrality tests were performed and tested against expectations from realistic demographic models. CONCLUSIONS/SIGNIFICANCE: Collectively, our analyses found that axr (auxin response factor), caf1 (chromatin assembly factor) and gatabp1 (gata binding protein 1) candidate genes carry patterns consistent with directional selection and erd3 (early response to drought 3) displays patterns suggestive of a selective sweep, both of which are consistent with the arm-race model of disease response evolution. Furthermore, we have identified patterns consistent with diversifying selection at erf1-like (ethylene responsive factor 1), ccoaoemt (caffeoyl-CoA-O-methyltransferase), cyp450-like (cytochrome p450-like) and pr4.3 (pathogen response 4.3), expected under the trench-warfare evolution model. Finally, a drought-tolerance candidate related to the plant cell wall, lp5, displayed patterns consistent with balancing selection. In conclusion, both arms-race and trench-warfare models seem compatible with patterns of polymorphism found in different disease-response candidate genes, indicating a mixed strategy of disease tolerance evolution for loblolly pine, a major tree crop in southeastern United States
Genetic control of Eucalyptus urophylla and E. grandis resistance to canker caused by Chrysoporthe cubensis
Chrysophorte cubensis induced canker occurs in nearly all tropical and subtropical regions where eucalypts are planted, causing losses in both wood quality and volume productivity, especially so in the warmer and more humid regions of Brazil. The wide inter and intra-specific genetic variability of resistance to canker among Eucalyptus species facilitates the selection of resistant plants. In this study, we evaluated resistance to this pathogen in five Eucalyptus grandis (G) and 15 E. urophylla (U) trees, as well as in 495 individuals from 27 progenies derived from crosses between the trees. In the field, six-months-old test seedlings were inoculated with C. cubensis. Lesion length in the xylem and bark was measured eight months later. The results demonstrated that xylem lesions could preferentially be used for the selection of resistant clones. Eight trees (7 U and 1 G) were susceptible, and the remainder (8 U and 4 G) resistant. Individual narrow and broad sense heritability estimates were 17 and 81%, respectively, thereby suggesting that canker resistance is quantitative and highly dependent on dominance and epistasis
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The genome of Eucalyptus grandis
Eucalypts are the worldâs most widely planted hardwood trees. Their outstanding diversity, adaptability and growth have
made them a global renewable resource of fibre and energy. We sequenced and assembled >94% of the 640-megabase
genome of Eucalyptus grandis. Of 36,376 predicted protein-coding genes, 34% occur in tandem duplications, the largest
proportion thus far in plant genomes. Eucalyptus also shows the highest diversity of genes for specialized metabolites such as
terpenes that act as chemical defence and provide unique pharmaceutical oils. Genome sequencing of the E. grandis sister
species E. globulus and a set of inbred E. grandis tree genomes reveals dynamic genome evolution and hotspots of inbreeding
depression. The E. grandis genome is the first reference for the eudicot order Myrtales and is placed here sister to
the eurosids. This resource expands our understanding of the unique biology of large woody perennials and provides a
powerful tool to accelerate comparative biology, breeding and biotechnology
Comprehensive genetic dissection of wood properties in a widely-grown tropical tree: Eucalyptus
Background: Eucalyptus is an important genus in industrial plantations throughout the world and is grown for use as timber, pulp, paper and charcoal. Several breeding programmes have been launched worldwide to concomitantly improve growth performance and wood properties (WPs). In this study, an interspecific cross between Eucalyptus urophylla and E. grandis was used to identify major genomic regions (Quantitative Trait Loci, QTL) controlling the variability of WPs. Results: Linkage maps were generated for both parent species. A total of 117 QTLs were detected for a series of wood and end-use related traits, including chemical, technological, physical, mechanical and anatomical properties. The QTLs were mainly clustered into five linkage groups. In terms of distribution of QTL effects, our result agrees with the typical L-shape reported in most QTL studies, i.e. most WP QTLs had limited effects and only a few (13) had major effects (phenotypic variance explained > 15%). The co-locations of QTLs for different WPs as well as QTLs and candidate genes are discussed in terms of phenotypic correlations between traits, and of the function of the candidate genes. The major wood property QTL harbours a gene encoding a Cinnamoyl CoA reductase (CCR), a structural enzyme of the monolignol-specific biosynthesis pathway. Conclusions: Given the number of traits analysed, this study provides a comprehensive understanding of the genetic architecture of wood properties in this Eucalyptus full-sib pedigree. At the dawn of Eucalyptus genome sequence, it will provide a framework to identify the nature of genes underlying these important quantitative traits. (Résumé d'auteur
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