The Effect of Genome Parametrization and SNP Marker Subsetting on Genomic Selection in Autotetraploid Alfalfa.

BACKGROUND: Alfalfa, the most economically important forage legume worldwide, features modest genetic progress due to long selection cycles and the extent of the non-additive genetic variance associated with its autotetraploid genome. METHODS: To improve the efficiency of genomic selection in alfalfa, we explored the effects of genome parametrization (as tetraploid and diploid dosages, plus allele ratios) and SNP marker subsetting (all available SNPs, only genic regions, and only non-genic regions) on genomic regressions, together with various levels of filtering on reading depth and missing rates. We used genotyping by sequencing-generated data and focused on traits of different genetic complexity, i.e., dry biomass yield in moisture-favorable (FE) and drought stress (SE) environments, leaf size, and the onset of flowering, which were assessed in 143 genotyped plants from a genetically broad European reference population and their phenotyped half-sib progenies. RESULTS: On average, the allele ratio improved the predictive ability compared with other genome parametrizations (+7.9% vs. tetraploid dosage, +12.6% vs. diploid dosage), while using all the SNPs offered an advantage compared with any specific SNP subsetting (+3.7% vs. genic regions, +7.6% vs. non-genic regions). However, when focusing on specific traits, different combinations of genome parametrization and subsetting achieved better performances. We also released Legpipe2, an SNP calling pipeline tailored for reduced representation (GBS, RAD) in medium-sized genotyping experiments.

Unraveling the Unusual Subgenomic Organization in the Neopolyploid Free-Living Flatworm Macrostomum lignano.

Whole genome duplication (WGD) is an evolutionary event resulting in a redundancy of genetic material. Different mechanisms of WGD, allo- or autopolyploidization, lead to distinct evolutionary trajectories of newly formed polyploids. Genome studies on such species are important for understanding the early stages of genome evolution. However, assembling neopolyploid is a challenging task due to the presence of 2 homologous (or homeologous) chromosome sets and therefore the existence of the extended paralogous regions in its genome. Post-WGD evolution of polyploids includes cytogenetic diploidization leading to the formation of species, whose polyploid origin might be hidden by disomic inheritance. Earlier we uncovered the hidden polyploid origin of the free-living flatworms of the genus Macrostomum (Macrostomum lignano, M. janickei, and M. mirumnovem). Cytogenetic diploidization in these species is accompanied by intensive chromosomal rearrangements including chromosomes fusions. In this study, we unravel the M. lignano genome organization through generation and sequencing of 2 sublines of the commonly used inbred line of M. lignano (called DV1) differing only in a copy number of the largest chromosome (MLI1). Using nontrivial assembly free comparative analysis of their genomes, we deciphered DNA sequences belonging to MLI1 and validated them by sequencing the pool of microdissected MLI1. Here we presented the uncommon mechanism of genome rediplodization of M. lignano, which consists of (i) presence of 3 subgenomes, which emerged via formation of large fused chromosomes and its variants, and (ii) sustaining their heterozygosity through inter- and intrachromosomal rearrangements.

Development of polymorphic EST-SSR markers and characterization of the autotetraploid genome of sainfoin (Onobrychis viciifolia).

BACKGROUND: Sainfoin (Onobrychis viciifolia) is a highly nutritious, tannin-containing, and tetraploid forage legume. Due to the lack of detailed transcriptomic and genomic information on this species, genetic and breeding projects for sainfoin improvement have been significantly hindered. METHODS: In this study, a total of 24,630,711 clean reads were generated from 14 different sainfoin tissues using Illumina paired-end sequencing technology and deposited in the NCBI SRA database (SRX3763386). From these clean reads, 77,764 unigene sequences were obtained and 6,752 EST-SSRs were identified using de novo assembly. A total of 2,469 primer pairs were designed, and 200 primer pairs were randomly selected to analyze the polymorphism in five sainfoin wild accessions. RESULTS: Further analysis of 40 sainfoin individuals from the five wild populations using 61 EST-SSR loci showed that the number of alleles per locus ranged from 4 to 15, and the expected heterozygosity varied from 0.55 to 0.91. Additionally, by counting the EST-SSR band number and sequencing the three or four bands in one sainfoin individual, sainfoin was confirmed to be autotetraploid. This finding provides a high level of information about this plant. DISCUSSION: Through this study, 61 EST-SSR markers were successfully developed and shown to be useful for genetic studies and investigations of population genetic structures and variabilities among different sainfoin accessions.

Screening and analysis on the differentially expression genes between diploid and autotetraploid watermelon by using of digital gene expression profile / Triagem e análise da expressão diferencial dos genes entre melancia diplóide e autotetraplóide através do perfil de expressão gênica digital

Abstract Synthetic polyploids are key breeding materials for watermelon. Compared with diploid watermelon, the tetraploid watermelon often exhibit wide phenotypic differences and differential gene expression. Digital gene expression (DGE) profile technique was performed in this study to present gene expression patterns in an autotetraploid and its progenitor diploid watermelon, and deferentially expressed genes (DEGs) related to the abiotic and biotic stress were also addressed. Altogether, 4,985 DEGs were obtained in the autotetraploid against its progenitor diploid, and 66.02% DEGs is up-regulated. GO analysis shows that these DEGs mainly distributed in 'metabolic process', 'cell' and 'catalytic activity'. KEGG analysis revealed that these DEGs mainly cover 'metabolic pathways', 'secondary metabolites' and 'ribosome'. Moreover, 134 tolerance related DEGs were identified which cover osmotic adjustment substance, protective enzymes/protein, signaling proteins and pathogenesis-related proteins. This study present the differential expression of stress related genes and global gene expression patterns at background level in autotetraploid watermelons. These new evidences could supplement the molecular theoretical basis for the better resistance after the genome doubling in the gourd family.

Resumo Poliploides sintéticos são materias fundamentais para melhoramento genético da melancia. Comparativamente ao seu homólogo diploide, a melancia tetraploide apresenta amplas diferenças genotípica e fenotípica e diferença de expressão gênica. A expressão gênica digital ou DGE (digital gene expression) foi utilizada neste estudo para representar o perfil de expressão gênica da melancia autotetraploide e seu progenitor diploide e a expressão diferencial de genes relacionados ao estresse biótico e abiótico. Os resultados mostraram que 4.985 DEGs foram observados no organismo autotetraploide, sendo que, deste total, 66.02%foram supra-regulados. A análise de ontologia gênica (GO) mostrou que estes DEGs estão relacionados principalmente com processos metabólicas, célula e atividade catalítica, abrangendo de acordo com a análise de genes e genoma (KEGG) rotas metabólicas, metabolismo secundário e ribossomos. Além disso, 134 genes de defesa foram identificados, abrangendo substâncias de ajuste osmótico, enzimas/proteínas de proteção, proteínas sinalizadoras e proteínas relacionadas à patogênese. Este estudo mostrou a expressão diferencial de genes relacionados ao estresse e o perfil global de expressão gênica de melancia autotetraploide, estes resultados podem complementar, a nível molecular, o entendimento do fator resistência após a duplicação do genoma em cucurbitáceas.

Screening and analysis on the differentially expression genes between diploid and autotetraploid watermelon by using of digital gene expression profile

Abstract Synthetic polyploids are key breeding materials for watermelon. Compared with diploid watermelon, the tetraploid watermelon often exhibit wide phenotypic differences and differential gene expression. Digital gene expression (DGE) profile technique was performed in this study to present gene expression patterns in an autotetraploid and its progenitor diploid watermelon, and deferentially expressed genes (DEGs) related to the abiotic and biotic stress were also addressed. Altogether, 4,985 DEGs were obtained in the autotetraploid against its progenitor diploid, and 66.02% DEGs is up-regulated. GO analysis shows that these DEGs mainly distributed in metabolic process, cell and catalytic activity. KEGG analysis revealed that these DEGs mainly cover metabolic pathways, secondary metabolites and ribosome. Moreover, 134 tolerance related DEGs were identified which cover osmotic adjustment substance, protective enzymes/protein, signaling proteins and pathogenesis-related proteins. This study present the differential expression of stress related genes and global gene expression patterns at background level in autotetraploid watermelons. These new evidences could supplement the molecular theoretical basis for the better resistance after the genome doubling in the gourd family.

Resumo Poliploides sintéticos são materias fundamentais para melhoramento genético da melancia. Comparativamente ao seu homólogo diploide, a melancia tetraploide apresenta amplas diferenças genotípica e fenotípica e diferença de expressão gênica. A expressão gênica digital ou DGE (digital gene expression) foi utilizada neste estudo para representar o perfil de expressão gênica da melancia autotetraploide e seu progenitor diploide e a expressão diferencial de genes relacionados ao estresse biótico e abiótico. Os resultados mostraram que 4.985 DEGs foram observados no organismo autotetraploide, sendo que, deste total, 66.02%foram supra-regulados. A análise de ontologia gênica (GO) mostrou que estes DEGs estão relacionados principalmente com processos metabólicas, célula e atividade catalítica, abrangendo de acordo com a análise de genes e genoma (KEGG) rotas metabólicas, metabolismo secundário e ribossomos. Além disso, 134 genes de defesa foram identificados, abrangendo substâncias de ajuste osmótico, enzimas/proteínas de proteção, proteínas sinalizadoras e proteínas relacionadas à patogênese. Este estudo mostrou a expressão diferencial de genes relacionados ao estresse e o perfil global de expressão gênica de melancia autotetraploide, estes resultados podem complementar, a nível molecular, o entendimento do fator resistência após a duplicação do genoma em cucurbitáceas.

Deciphering the molecular bases for drought tolerance in Arabidopsis autotetraploids.

Whole genome duplication (autopolyploidy) is common in many plant species and often leads to better adaptation to adverse environmental conditions. However, little is known about the physiological and molecular mechanisms underlying these adaptations. Drought is one of the major environmental conditions limiting plant growth and development. Here, we report that, in Arabidopsis thaliana, tetraploidy promotes alterations in cell proliferation and organ size in a tissue-dependent manner. Furthermore, it potentiates plant tolerance to salt and drought stresses and decreases transpiration rate, likely through controlling stomata density and closure, abscisic acid (ABA) signalling and reactive oxygen species (ROS) homeostasis. Our transcriptomic analyses revealed that tetraploidy mainly regulates the expression of genes involved in redox homeostasis and ABA and stress response. Taken together, our data have shed light on the molecular basis associated with stress tolerance in autopolyploid plants.

Cytogenetic evidence for autopolyploidy in Parnassia palustris.

Diploid populations of Parnassia palustris L. var. palustris and var. condensata Travis & Wheldon have a highly symmetrical karyotype, consisting of seven metacentrk and two submetacentric chromosomes. The gross morphology of the karyotype of tetraploid populations is indistinguishable from that of the diploids. Studies of meiosis in tetraploids of both varieties demonstrated a high frequency of quadrivalent formation, strongly suggesting an autopolyploid origin. Later stages of meiosis in the tetraploids are regular and the pollen shows no decrease in stainability compared with that of the diploids. Some evidence is presented to show that tetraploids of both varieties may have a wider ecological amplitude than do diploids.