Signatures of selection in recently domesticated macadamia

Macadamia is a high value nut crop that is recently domesticated, ideal for testing the effect of artificial selection. Here, we sequence the genome of Hawaiian cultivar ‘Kau’ and assemble into 794 Mb in 14 pseudo-chromosomes with 37,728 genes. Genome analysis reveals a whole-genome duplication event, occurred 46.8 million years ago. Gene expansions occurred in gene families involves in fatty acid biosynthesis. Gene duplication of MADS-Box transcription factors in proanthocyanidin biosynthesis are relevant for seed coat development. Genome re-sequencing of 112 accessions reveals the origin of Hawaiian cultivars from Mount Bauple in southeast Queensland in Australia. Selective sweeps are detected in macadamia cultivars, including genes involved in fatty acid biosynthesis, seed coat development, and heat stress response. Such strong effects of artificial selection in few generations reveals the genomic basis for ‘one-step operation’ for clonal crop domestication. The knowledge gained could accelerate domestication of new crops from wild species.

Catalase (CAT) Gene Family in Wheat (Triticum aestivum L.): Evolution, Expression Pattern and Function Analysis

Catalases (CATs) are present in almost all living organisms and play important roles in plant development and response to various stresses. However, there is relatively little information on CAT genes in wheat and related Triticeae species. A few studies on CAT family genes in wheat have been reported. In this study, ten CAT proteins (TaCATs) were identified in wheat and classified into three groups based on their phylogenetic features and sequence analysis. The analysis of the structure and motif composition of the TaCAT proteins suggested that a segmental duplication event occurred in the TaCAT gene family. Collinearity relationship analysis among different species showed that there were three orthologous CAT genes in rice and in maize. By analyzing the cis-elements in the promoter regions, we speculated that TaCAT genes expression might be regulated by light, oxygen deficit, methyl jasmonate and abscisic acid, and by transcription factors such as MYB. A Gene Ontology (GO)-based analysis showed that TaCAT proteins may be related to the response to various stresses, are cytoplasm localized, and may function as antioxidant enzymes. RT-qPCR and transcriptome data analyses exhibited distinct expression patterns of TaCAT genes in different tissues and in response to various treatments. In this study, a comprehensive analysis of wheat CAT genes was performed, enriching our knowledge of CAT genes and providing a foundation for further functional analyses of this gene family in wheat.

Genomic Identification, Evolution, and Expression Analysis of Bromodomain Genes Family in Buffalo

Bromodomain (BRD) is an evolutionarily conserved protein–protein interaction module that is critical in gene regulation, cellular homeostasis, and epigenetics. This study aimed to conduct an identification, evolution, and expression analysis of the BRD gene family in the swamp buffalo (Bubalus bubalis). A total of 101 BRD protein sequences deduced from 22 BRD genes were found in the buffalo genome. The BRD proteins were classified into six groups based on phylogenetic relationships, conserved motifs, and conserved domains. The BRD genes were irregularly distributed in 13 chromosomes. Collinearity analysis revealed 20 BRD gene pairs that had remarkable homologous relationships between the buffalo and cattle, although no tandem or segmental duplication event was found in the buffalo BRD genes. Comparative transcriptomics using a 10x sequencing platform analysis showed that 22 BRD genes were identified in the Sertoli cells (SCs) at different developmental stages of buffalo. Further, the mRNA expression levels of bromodomain and the extraterminal (BET) family in SCs at the pubertal stage were higher than that at the prepubertal stage of buffalo. However, the SMARCA2, PHIP, BRD9, and TAF1 genes exhibited the opposite trend. The maturation process of SCs may be regulated by the BRD family members expressed differentially in SCs at different developmental stages of buffalo. In summary, our findings provide an understanding of the evolutionary, structural, and functional properties of the buffalo BRD family members, and further characterize the function of the BRD family in the maturation of SCs. It also provides a theoretical basis for further understanding in the future of the mechanism of SCs regulating spermatogenesis.

Rapid Cis–Trans Coevolution Driven by a Novel Gene Retroposed from a Eukaryotic Conserved CCR4–NOT Component in Drosophila

Young, or newly evolved, genes arise ubiquitously across the tree of life, and they can rapidly acquire novel functions that influence a diverse array of biological processes. Previous work identified a young regulatory duplicate gene in Drosophila, Zeus that unexpectedly diverged rapidly from its parent, Caf40, an extremely conserved component in the CCR4–NOT machinery in post-transcriptional and post-translational regulation of eukaryotic cells, and took on roles in the male reproductive system. This neofunctionalization was accompanied by differential binding of the Zeus protein to loci throughout the Drosophila melanogaster genome. However, the way in which new DNA-binding proteins acquire and coevolve with their targets in the genome is not understood. Here, by comparing Zeus ChIP-Seq data from D. melanogaster and D. simulans to the ancestral Caf40 binding events from D. yakuba, a species that diverged before the duplication event, we found a dynamic pattern in which Zeus binding rapidly coevolved with a previously unknown DNA motif, which we term Caf40 and Zeus-Associated Motif (CAZAM), under the influence of positive selection. Interestingly, while both copies of Zeus acquired targets at male-biased and testis-specific genes, D. melanogaster and D. simulans proteins have specialized binding on different chromosomes, a pattern echoed in the evolution of the associated motif. Using CRISPR-Cas9-mediated gene knockout of Zeus and RNA-Seq, we found that Zeus regulated the expression of 661 differentially expressed genes (DEGs). Our results suggest that the evolution of young regulatory genes can be coupled to substantial rewiring of the transcriptional networks into which they integrate, even over short evolutionary timescales. Our results thus uncover dynamic genome-wide evolutionary processes associated with new genes.

Molecular evidence for segmental duplication across chromosomes of soybean using transcription factor gene family

Duplication of genome is an important genetic innovation. Large genome size (1.1 Gb) along with ancient and recent duplication events make the soybean genome more complex. Analyzing the distribution and duplication event in soybean transcription family genes, the segmental duplication within chromosomes was revealed. Our study provides a strong evidence that the large segmental duplication event in genome architecture and evolution of soybean genome using simple method of sequence and order analysis of TF genes. Finally, a scheme for interrelationship of different chromosomes has been proposed.

Populus trichocarpa (Black Cottonwood) As a Model for Plant Genomic Studies: A Review

Numerous plants have been the subject of recent research in the pharmacological, cosmetic, and agro-alimentary domains due to their chemical composition and multiple therapeutic capabilities. Populus trichocarpa is one of the most common trees found in deciduous forests (Salicaceae family). The current study examines Populus trichocarpa as a model plant for plant genomics research, as well as the most recent findings on phytochemical composition and medicinal potential. More than 45,000 potential protein-coding genes were discovered. In the Populus genome, a whole-genome duplication event was discovered, with approximately 8,000 pairs of duplicated genes surviving. Furthermore, the reproductive biology of Populus provides new opportunities and challenges in the study and analysis of natural genetic and phenotypic variation. In the present review, we endeavour to describe and compile the available knowledge on Populus trichocarpa as a model plant for genomic investigations and to bring that material up to date of Populus trichocarpa's phytochemical and medicinal properties.

The evolved divergence of γ-secretase-susceptibility of homologous proteins Ngfrb and Nradd in zebrafish

Objective NGFR/p75NTR and NRADD/NRH proteins are closely related structurally and are encoded by genes that arose from a duplication event early in vertebrate evolution. The transmembrane domain (TMD) of NGFR is cleaved by γ-secretase but there is conflicting data around the susceptibility to γ-secretase cleavage of NRADD proteins. If NGFR and NRADD show differential susceptibility to γ-secretase, then they can be used to dissect the structural constraints determining substrate susceptibility. We sought to test this differential susceptibility. Results We developed labelled, lumenally-truncated forms of zebrafish Ngfrb and Nradd and a chimeric protein in which the TMD of Nradd was replaced with the TMD of Ngfrb. We expressed these in zebrafish embryos to test their susceptibility to γ-secretase cleavage by monitoring their stability using western immunoblotting. Inhibition of γ-secretase activity using DAPT increased the stability of only the Ngfrb construct. Our results support that only NGFR is cleaved by γ-secretase. Either NGFR evolved γ-secretase-susceptibility since its creation by gene duplication, or NRADD evolved to be refractory to γ-secretase. Protein structure outside of the TMD of NGFR is likely required for susceptibility to γ-secretase.

Convergent evolution of mevalonate pathway in Inonotus obliquus and Betula pendula.

Inonotus obliquus, Chaga mushroom, is a fungal species from Hymenochaetaceae family (Basidiomycota) which has been widely used for traditional medicine in Europe and Asia. Here, chaga genome was sequenced using Pacbio sequencing into a 50.7Mbp assembly consisting of 301 primary contigs with an N50 value of 375 kbp. Genome evolution analyses revealed a lineage-specific whole genome duplication event and an expansion of Cytochrome P450 superfamily. Fungal biosynthetic clusters were enriched for tandemly duplicated genes, suggesting that biosynthetic pathway evolution has proceeded through small-scale duplications. Metabolomic fingerprinting confirmed a highly complex terpene biosynthesis chemistry when compared against related fungal species lacking the genome duplication event.

Characterisation of the Genes Encoding Mannuronan-C5-Epimerase in the Brown Alga Lessonia Variegata

<p>Alginate is known to be a commercially valuable polysaccharide, of great importance in industries such as food, cosmetics, medicine and pharmaceuticals. It is obtained commercially by harvesting brown algae. The final step in the alginate biochemical pathway involves the epimerization of D-mannuronic residues into L-guluronic residues, catalyzed by the enzyme mannuronan-C5-epimerase. This final step has been found to be responsible for controlling the physicochemical properties of the produced alginate. This study is the first to characterize the genes encoding for the enzyme mannuronan-C5- epimerase in the Northern, Southern and Wellington lineages of the brown alga Lessonia variegata (Phaeophyceae). The gene of interest was amplified by standard PCR and cloning. Cloning PCR results revealed the presence of two distinct copies of the gene in Lessonia variegata. The coding region of the copies was found to be very conserved with very little sequence variation. The Lessonia variegata sequences were compared with those of Laminaria digitata and Saccharina japonica, which indicated that at least one gene duplication event has occurred in Lessonia variegata, leading to the formation of two gene duplicates. The possible mechanisms by which the gene paralogs may control the structure and function of the produced alginate have been discussed.</p>