Your search keyword '"Pratlong M"' showing total 5 results

1. Genetic control of rhizosheath formation in pearl millet.

Author

de la Fuente Cantó, C., Diouf, M. N., Ndour, P. M. S., Debieu, M., Grondin, A., Passot, S., Champion, A., Barrachina, C., Pratlong, M., Gantet, P., Assigbetsé, K., Kane, N., Cubry, P., Diedhiou, A. G., Heulin, T., Achouak, W., Vigouroux, Y., Cournac, L., and Laplaze, L.

Subjects

PEARL millet, GENOME-wide association studies, VESICULAR-arbuscular mycorrhizas, ARID regions, GENE expression, ROOT development

Abstract

The rhizosheath, the layer of soil that adheres strongly to roots, influences water and nutrients acquisition. Pearl millet is a cereal crop that plays a major role for food security in arid regions of sub-Saharan Africa and India. We previously showed that root-adhering soil mass is a heritable trait in pearl millet and that it correlates with changes in rhizosphere microbiota structure and functions. Here, we studied the correlation between root-adhering soil mass and root hair development, root architecture, and symbiosis with arbuscular mycorrhizal fungi and we analysed the genetic control of this trait using genome wide association (GWAS) combined with bulk segregant analysis and gene expression studies. Root-adhering soil mass was weakly correlated only to root hairs traits in pearl millet. Twelve QTLs for rhizosheath formation were identified by GWAS. Bulk segregant analysis on a biparental population validated five of these QTLs. Combining genetics with a comparison of global gene expression in the root tip of contrasted inbred lines revealed candidate genes that might control rhizosheath formation in pearl millet. Our study indicates that rhizosheath formation is under complex genetic control in pearl millet and suggests that it is mainly regulated by root exudation. [ABSTRACT FROM AUTHOR]

Published

2022

2. Genetic control of rhizosheath formation in pearl millet.

Author

de la Fuente Cantó, C., Diouf, M. N., Ndour, P. M. S., Debieu, M., Grondin, A., Passot, S., Champion, A., Barrachina, C., Pratlong, M., Gantet, P., Assigbetsé, K., Kane, N., Cubry, P., Diedhiou, A. G., Heulin, T., Achouak, W., Vigouroux, Y., Cournac, L., and Laplaze, L.

Subjects

PEARL millet, GENOME-wide association studies, VESICULAR-arbuscular mycorrhizas, ARID regions, GENE expression, ROOT development

Abstract

The rhizosheath, the layer of soil that adheres strongly to roots, influences water and nutrients acquisition. Pearl millet is a cereal crop that plays a major role for food security in arid regions of sub-Saharan Africa and India. We previously showed that root-adhering soil mass is a heritable trait in pearl millet and that it correlates with changes in rhizosphere microbiota structure and functions. Here, we studied the correlation between root-adhering soil mass and root hair development, root architecture, and symbiosis with arbuscular mycorrhizal fungi and we analysed the genetic control of this trait using genome wide association (GWAS) combined with bulk segregant analysis and gene expression studies. Root-adhering soil mass was weakly correlated only to root hairs traits in pearl millet. Twelve QTLs for rhizosheath formation were identified by GWAS. Bulk segregant analysis on a biparental population validated five of these QTLs. Combining genetics with a comparison of global gene expression in the root tip of contrasted inbred lines revealed candidate genes that might control rhizosheath formation in pearl millet. Our study indicates that rhizosheath formation is under complex genetic control in pearl millet and suggests that it is mainly regulated by root exudation. [ABSTRACT FROM AUTHOR]

Published

2022

3. Full moonlight-induced circadian clock entrainment in Coffea arabica.

Author

Breitler, J-C., Djerrab, D., Leran, S., Toniutti, L., Guittin, C., Severac, D., Pratlong, M., Dereeper, A., Etienne, H., and Bertrand, B.

Subjects

COFFEE, CLOCK genes, HEAT shock proteins, CHLOROPLASTS, PLANT physiology, FULL moon, MELANOPSIN

Abstract

Background: It is now well documented that moonlight affects the life cycle of invertebrates, birds, reptiles, and mammals. The lunisolar tide is also well-known to alter plant growth and development. However, although plants are known to be very photosensitive, few studies have been undertaken to explore the effect of moonlight on plant physiology. Results: Here for the first time we report a massive transcriptional modification in Coffea arabica genes under full moonlight conditions, particularly at full moon zenith and 3 h later. Among the 3387 deregulated genes found in our study, the main core clock genes were affected. Conclusions: Moonlight also negatively influenced many genes involved in photosynthesis, chlorophyll biosynthesis and chloroplast machinery at the end of the night, suggesting that the full moon has a negative effect on primary photosynthetic machinery at dawn. Moreover, full moonlight promotes the transcription of major rhythmic redox genes and many heat shock proteins, suggesting that moonlight is perceived as stress. We confirmed this huge impact of weak light (less than 6 lx) on the transcription of circadian clock genes in controlled conditions mimicking full moonlight. [ABSTRACT FROM AUTHOR]

Published

2020

4. Genomic resources and their influence on the detection of the signal of positive selection in genome scans.

Author

Manel, S., Perrier, C., Pratlong, M., Abi‐Rached, L., Paganini, J., Pontarotti, P., and Aurelle, D.

Subjects

NATURAL selection, BIOLOGICAL adaptation, CONSERVATION biology, POPULATION genetics, BIOLOGICAL evolution, SINGLE nucleotide polymorphisms

Abstract

Genome scans represent powerful approaches to investigate the action of natural selection on the genetic variation of natural populations and to better understand local adaptation. This is very useful, for example, in the field of conservation biology and evolutionary biology. Thanks to Next Generation Sequencing, genomic resources are growing exponentially, improving genome scan analyses in non-model species. Thousands of SNPs called using Reduced Representation Sequencing are increasingly used in genome scans. Besides, genome sequences are also becoming increasingly available, allowing better processing of short-read data, offering physical localization of variants, and improving haplo-type reconstruction and data imputation. Ultimately, genome sequences are also becoming the raw material for selection inferences. Here, we discuss how the increasing availability of such genomic resources, notably genome sequences, influences the detection of signals of selection. Mainly, increasing data density and having the information of physical linkage data expand genome scans by (i) improving the overall quality of the data, (ii) helping the reconstruction of demographic history for the population studied to decrease false-positive rates and (iii) improving the statistical power of methods to detect the signal of selection. Of particular importance, the availability of a high-quality reference genome can improve the detection of the signal of selection by (i) allowing matching the potential candidate loci to linked coding regions under selection, (ii) rapidly moving the investigation to the gene and function and (iii) ensuring that the highly variable regions of the genomes that include functional genes are also investigated. For all those reasons, using reference genomes in genome scan analyses is highly recommended. [ABSTRACT FROM AUTHOR]

Published

2016

5. The red coral ( Corallium rubrum) transcriptome: a new resource for population genetics and local adaptation studies.

Author

Pratlong, M., Haguenauer, A., Chabrol, O., Klopp, C., Pontarotti, P., and Aurelle, D.

Subjects

CORAL ecology, POPULATION genetics, BIOLOGICAL adaptation, SURVIVAL behavior (Animals), PHENOTYPIC plasticity

Abstract

The question of species survival and evolution in heterogeneous environments has long been a subject for study. Indeed, it is often difficult to identify the molecular basis of adaptation to contrasted environments, and nongenetic effects increase the difficulty to disentangle fixed effects, such as genetic adaptation, from variable effects, such as individual phenotypic plasticity, in adaptation. Nevertheless, this question is also of great importance for understanding the evolution of species in a context of climate change. The red coral ( Corallium rubrum) lives in the Mediterranean Sea, where at depths ranging from 5 to 600 m, it meets very contrasted thermal conditions. The shallowest populations of this species suffered from mortality events linked with thermal anomalies that have highlighted thermotolerance differences between individuals. We provide here a new transcriptomic resource, as well as candidate markers for the study of local adaptation. We sequenced the transcriptome of six individuals from 5 m and six individuals from 40 m depth at the same site of the Marseilles bay, after a period of common garden acclimatization. We found differential expression maintained between the two depths even after common garden acclimatization, and we analysed the polymorphism pattern of these samples. We highlighted contigs potentially implicated in the response to thermal stress, which could be good candidates for the study of thermal adaptation for the red coral. Some of these genes are also involved in the response to thermal stress in other corals. Our method enables the identification of candidate loci of local adaptation useful for other nonmodel organisms. [ABSTRACT FROM AUTHOR]

Published

2015