Numerous collecting expeditions of Theobroma cacao L. germplasm have been undertaken in Latin-America. However, most of this germplasm has not contributed to cacao improvement because its relationship to cultivated selections was poorly understood. Germplasm labeling errors have impeded breeding and confounded the interpretation of diversity analyses. To improve the understanding of the origin, classification, and population differentiation within the species, 1241 accessions covering a large geographic sampling were genotyped with 106 microsatellite markers. After discarding mislabeled samples, 10 genetic clusters, as opposed to the two genetic groups traditionally recognized within T. cacao, were found by applying Bayesian statistics. This leads us to propose a new classification of the cacao germplasm that will enhance its management. The results also provide new insights into the diversification of Amazon species in general, with the pattern of differentiation of the populations studied supporting the palaeoarches hypothesis of species diversification. The origin of the traditional cacao cultivars is also enlightened in this study.
BackgroundTheobroma cacao L. cultivar Matina 1-6 belongs to the most cultivated cacao type. The availability of its genome sequence and methods for identifying genes responsible for important cacao traits will aid cacao researchers and breeders.ResultsWe describe the sequencing and assembly of the genome of Theobroma cacao L. cultivar Matina1-6. The genome of the Matina 1-6 cultivar is 445 Mbp, which is significantly larger than a sequenced Criollo cultivar, and more typical of other cultivars. The chromosome-scale assembly, version 1.1, contains 711 scaffolds covering 346.0 Mbp, with a contig N50 of 84.4 kbp, a scaffold N50 of 34.4 Mbp, and an evidence-based gene set of 29,408 loci. Version 1.1 has 10x the scaffold N50 and 4x the contig N50 as Criollo, and includes 111 Mb more anchored sequence. The version 1.1 assembly has 4.4% gap sequence, while Criollo has 10.9%. Through a combination of haplotype, association mapping and gene expression analyses, we leverage this robust reference genome to identify a promising candidate gene responsible for pod color variation. We demonstrate that green/red pod color in cacao is likely regulated by the R2R3 MYB transcription factor TcMYB113, homologs of which determine pigmentation in Rosaceae, Solanaceae, and Brassicaceae. One SNP within the target site for a highly conserved trans-acting siRNA in dicots, found within TcMYB113, seems to affect transcript levels of this gene and therefore pod color variation.ConclusionsWe report a high-quality sequence and annotation of Theobroma cacao L. and demonstrate its utility in identifying candidate genes regulating traits.
Subcellular localization of acyl carrier protein in leaf protoplasts of Spinacia oleracea.
This communication demonstrates that all de novo fatty acid biosynthesis in spinach leaf cells requires acyl carrier protein (ACP) and occurs specifically in the chloroplasts. Antibodies raised to purified spinach ACP inhibited at least 98% of malonyl CoA-ependent fatty acid synthesis by spinach leaf homogenates. Therefore, the presence of ACP in a compartment of the spinach leaf cell would serve as a marker for de novo fatty acid biosynthesis. A radioimmunoassa capable of detecting 10-'S mol (10-" g) of spinach ACP was deve oped to measure the levels of ACP in leaf cell components isolated by sucrose gradient centrifugation of a gentle lysate of spinach leaf protoplasts. All of the ACP of the leaf cell could be attributed to the chloroplast. Less than 1% of the ACP associated with chloroplasts resulted from binding of free ACP to chloro lasts. Of interest, ACP from Escherichia coli, soybean, and sunflower showed only partial crossreactivity with spinach ACP by the radioimmunoassay. These results strongly suggest that, in the leaf cell, chloroplasts are the sole site for the degnovo synthesis of C16 and C18 fatty acids. These fatty acids are then transported into the cytoplasm for further modification and are either inserted into extrachloroplastic membrane lipids or returned to the chloroplast for insertion into lamellar membrane lipids. In plants, acyl carrier protein (ACP) plays an essential role in both the synthesis and the subsequent metabolism of the C16 and C18 fatty acids (1). Whereas de novo fatty acid synthesis in isolated chloroplasts has long been known (1), the site of synthesis of fatty acids that are required for the formation of plasma, mitochondrial, and other extrachloroplast membranes in the leaf cell is not clear. In sharp contrast, in both animal and yeast cells, synthesis occurs in the cytoplasm (2). In Escherichi colA cells, it has been shown that ACP is localized on or near the inner face of the plasma membrane and this implies that the nonassociated fatty acid synthetase enzymes may be organized in the same area in vivo (3).Although earlier studies have provided evidence that fatty acid biosynthesis occurs in chloroplasts (1) and in proplastids (4-8), until recently the methods used for the isolation of these organelles led to substantial breakage and release of enzymes into the cytoplasmic fraction. Consequently, it has been difficult to assign a precise site for an enzyme in the leaf cell. In addition, after cell disruption, attempts to localize the complex set of reactions comprising fatty acid synthesis can be further complicated by cofactor dilution (particularly ACP), enzyme dilution, and inactivation. Hence, it has been difficult to conclude from these earlier studies whether de novo fatty acid synthesis takes place only in the chloroplast (or plastid) or in the cytoplasm or other organelles as well. Damage to organelles can be greatly reduced in the isolation procedure by using protoplasts as the starting material (9). Gentle lysis of isolated protoplasts gives an incre...
The avocado, Persea americana, is a fruit crop of immense importance to Mexican agriculture with an increasing demand worldwide. Avocado lies in the anciently diverged magnoliid clade of angiosperms, which has a controversial phylogenetic position relative to eudicots and monocots. We sequenced the nuclear genomes of the Mexican avocado race, P. americana var. drymifolia, and the most commercially popular hybrid cultivar, Hass, and anchored the latter to chromosomes using a genetic map. Resequencing of Guatemalan and West Indian varieties revealed that ∼39% of the Hass genome represents Guatemalan source regions introgressed into a Mexican race background. Some introgressed blocks are extremely large, consistent with the recent origin of the cultivar. The avocado lineage experienced 2 lineage-specific polyploidy events during its evolutionary history. Although gene-tree/species-tree phylogenomic results are inconclusive, syntenic ortholog distances to other species place avocado as sister to the enormous monocot and eudicot lineages combined. Duplicate genes descending from polyploidy augmented the transcription factor diversity of avocado, while tandem duplicates enhanced the secondary metabolism of the species. Phenylpropanoid biosynthesis, known to be elicited by Colletotrichum (anthracnose) pathogen infection in avocado, is one enriched function among tandems. Furthermore, transcriptome data show that tandem duplicates are significantly up- and down-regulated in response to anthracnose infection, whereas polyploid duplicates are not, supporting the general view that collections of tandem duplicates contribute evolutionarily recent “tuning knobs” in the genome adaptive landscapes of given species.
Molecular Cloning of Osmotin and Regulation of Its Expression by ABA and Adaptation to Low Water Potential
In response to adaptation to NaCI, cultured tobacco cells (Nicotiana tabacum L. cv Wisconsin 38) synthesize a major 26 kilodalton protein which has been named osmotin due to its induction by low water potentials. To help characterize the expression of osmotin in adapted cells, a cDNA clone for osmotin has been isolated. Abscisic acid induces messenger RNA encoding osmotin. Levels of this mRNA in adapted cells are approximately 15-fold higher than in unadapted cells. Message for osmotin is present at constant levels through the growth cycle of adapted cells, while in unadapted cells, the level decreases during exponential phase of growth and increases again when the cells approach stationary phase. While abscisic acid induces the message for osmotin, a low water potential environment appears to be required for accumulation of the protein. An osmotin mRNA, a low water potential environment is required for preferential translation of osmotin mRNA or to reduce osmotin turnover (21).We report here the isolation of a cDNA clone encoding osmotin. We confirm the hypothesis that ABA induces transcription or stabilization of osmotin mRNA. We also confirm that some posttranscriptional event allows the enhanced accumulation of osmotin after adaptation to osmotic stress. We show that the stable altered expression of osmotin is not related to gene amplification or rearrangement and compare the complete amino acid sequence of osmotin with four other homologous proteins.
No abstract
BackgroundThe Cocoseae is one of 13 tribes of Arecaceae subfam. Arecoideae, and contains a number of palms with significant economic importance, including the monotypic and pantropical Cocos nucifera L., the coconut, the origins of which have been one of the “abominable mysteries” of palm systematics for decades. Previous studies with predominantly plastid genes weakly supported American ancestry for the coconut but ambiguous sister relationships. In this paper, we use multiple single copy nuclear loci to address the phylogeny of the Cocoseae subtribe Attaleinae, and resolve the closest extant relative of the coconut.Methodology/Principal FindingsWe present the results of combined analysis of DNA sequences of seven WRKY transcription factor loci across 72 samples of Arecaceae tribe Cocoseae subtribe Attaleinae, representing all genera classified within the subtribe, and three outgroup taxa with maximum parsimony, maximum likelihood, and Bayesian approaches, producing highly congruent and well-resolved trees that robustly identify the genus Syagrus as sister to Cocos and resolve novel and well-supported relationships among the other genera of the Attaleinae. We also address incongruence among the gene trees with gene tree reconciliation analysis, and assign estimated ages to the nodes of our tree.Conclusions/SignificanceThis study represents the as yet most extensive phylogenetic analyses of Cocoseae subtribe Attaleinae. We present a well-resolved and supported phylogeny of the subtribe that robustly indicates a sister relationship between Cocos and Syagrus. This is not only of biogeographic interest, but will also open fruitful avenues of inquiry regarding evolution of functional genes useful for crop improvement. Establishment of two major clades of American Attaleinae occurred in the Oligocene (ca. 37 MYBP) in Eastern Brazil. The divergence of Cocos from Syagrus is estimated at 35 MYBP. The biogeographic and morphological congruence that we see for clades resolved in the Attaleinae suggests that WRKY loci are informative markers for investigating the phylogenetic relationships of the palm family.
The mRNAs encoding two enzymes of phenylpropanoid metabolism, phenylalanine ammonia-lyase (PAL; EC 4.3.1.5) and 4-coumarate:CoA ligase (4CL; EC 6.2.1.12), were induced in cultured parsley cells (Petroselinum hortense) either by irradiation with UV light or by treatment with elicitor, a cell-wall fraction of the fungus Phytophthora megasperma f. sp. glycinea. Two-dimensional gel electrophoresis of the encoded PAL and 4CL proteins revealed that the mRNAs induced by either treatment were very similar if not identical. RNA blot hybridization with cDNAs complementary to these mRNAs was used to measure changes in the mRNA amounts at various times after either treatment. Total cellular PAL and 4CL mRNA amounts increased coordinately after UV irradiation to a maximum at 7 hr and then decreased to uninduced levels by 30 hr with the same kinetics as observed previously for the changes in the translational activities. Treatment with the fungal elicitor also caused coordinated, but more rapid, changes in PAL and 4CL mRNA translational activities, with a sharp peak occurring 3 hr after the addition of elicitor. Corresponding changes in mRNA amounts were observed only for 4CL, whereas the amount of PAL mRNA continued to increase at least up to 20 hr after elicitor addition. Our results suggest that parsley cells respond to UV irradiation or addition of fungal elicitor by increased rates of transcription of genes involved in the synthesis of compounds related to UV or disease resistance, respectively.
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