Genome of papaya, a fast growing tropical fruit tree

Papaya is a major fruit crop in tropical and subtropical regions worldwide. It has long been recognized as a nutritious and healthy fruit rich in vitamins A and C. Its small genome, unique aspects of nascent sex chromosomes, and agricultural importance are justifications for sequencing the genome. A female plant of the transgenic variety SunUp was selected for sequencing its genome to avoid the complication of assembling the XY chromosomes in a male or hermaphrodite plant. The draft genome revealed fewer genes than sequenced genomes of flowering plants, partly due to its lack of genome wide duplication since the ancient triplication event shared by eudicots. Most gene families have fewer members in papaya, including significantly fewer disease resistance genes. However, striking amplifications in gene number were found in some functional groups, including MADS-box genes, starch synthases, and volatiles that might affect the speciation and adaptation of papaya. The draft genome was used to clone a gene controlling fruit flesh color and to accelerate the construction of physical maps of sex chromosomes in papaya. Finishing the papaya genome and re-sequencing selected genomes in the family will further facilitate papaya improvement and the study of genome and sex chromosome evolution in angiosperms, particularly in Caricaceae.     

The Application of Reverse Genetics to Polyploid Plant Species

Polyploidy events (polyploidization) followed by progressive loss of redundant genome components are a major feature of plant evolution, with new evidence suggesting that all flowering plants possess ancestral genome duplications. Furthermore, many of our most important crop plants have undergone additional, relatively recent, genome duplication events. Recent advances in DNA sequencing have made vast amounts of new genomic data available for many plants, including a range of important crop species with highly duplicated genomes. Along with assisting traditional forward genetics approaches to study gene function, this wealth of new sequence data facilitates extensive reverse genetics-based functional analyses. However, plants featuring high levels of genome duplication as a result of recent polyploidization pose additional challenges for reverse genetic analysis. Here we review reverse genetic analysis in such polyploid plants and highlight key challenges.     

被子植物叶绿体基因组的结构变异研究进展

叶绿体是绿色植物特有的细胞器,其基因组信息被广泛应用于植物系统发育和比较基因组学研究。目前,越来越多的物种有了叶绿体全基因组序列,人们对叶绿体基因组的结构及其变异规律有了更深入的了解。该文对近年来国内外有关被子植物叶绿体基因组插入/缺失、短片段倒位与重复、基因组结构重排以及基因丢失等结构变异式样的研究进展进行综述,并分析了叶绿体基因组结构研究中仍存在的问题以及该领域未来的发展趋势。     

基因组学技术大发展助力园艺植物研究取得新进展

园艺植物包括花卉、蔬菜、果树、部分瓜类(如西瓜(Citrullus lanatus)和甜瓜(Cucumis melo))和茶树(Camellia sinensis),在植物分类上涉及大量物种。园艺植物的基因组学和遗传学研究具有重要的理论价值和经济意义。基因组测序技术及相关生物信息学工具的发展为园艺植物基因组和分子生物学研究注入了新的活力。睡莲是一种重要的花卉植物,除了具有观赏价值,其进化地位也非常特殊,属于一种早期被子植物类群。最近,蓝星睡莲(N.colorata)的高质量基因组图谱绘制完成。通过系统分析和比较睡莲基因组与其它被子植物的基因组,研究者阐明了睡莲的进化位置及相关进化事件。所获得的高质量基因组序列将有助于园艺植物研究者开展深入的分子遗传学研究,鉴定到控制和调控花器官、花色花香及品质等众多性状的功能基因,从而推动基础研究的快速发展和加快新品种创制。     

Pollinator‐mediated interactions between cultivated papaya and co‐flowering plant species

Many modern crop varieties rely on animal pollination to set fruit and seeds. Intensive crop plantations usually do not provide suitable habitats for pollinators so crop yield may depend on the surrounding vegetation to maintain pollination services. However, little is known about the effect of pollinator‐mediated interactions among co‐flowering plants on crop yield or the underlying mechanisms. Plant reproductive success is complex, involving several pre‐ and post‐pollination events; however, the current literature has mainly focused on pre‐pollination events in natural plant communities. We assessed pollinator sharing and the contribution to pollinator diet in a community of wild and cultivated plants that co‐flower with a focal papaya plantation. In addition, we assessed heterospecific pollen transfer to the stigmatic loads of papaya and its effect on fruit and seed production. We found that papaya shared at least one pollinator species with the majority of the co‐flowering plants. Despite this, heterospecific pollen transfer in cultivated papaya was low in open‐pollinated flowers. Hand‐pollination experiments suggest that heterospecific pollen transfer has no negative effect on fruit production or weight, but does reduce seed production. These results suggest that co‐flowering plants offer valuable floral resources to pollinators that are shared with cultivated papaya with little or no cost in terms of heterospecific pollen transfer. Although HP reduced seed production, a reduced number of seeds per se are not negative, given that from an agronomic perspective the number of seeds does not affect the monetary value of the papaya fruit.     

Application of whole genome re-sequencing data in the development of diagnostic DNA markers tightly linked to a disease-resistance locus for marker-assisted selection in lupin (Lupinus angustifolius)

Background

Molecular marker-assisted breeding provides an efficient tool to develop improved crop varieties. A major challenge for the broad application of markers in marker-assisted selection is that the marker phenotypes must match plant phenotypes in a wide range of breeding germplasm. In this study, we used the legume crop species Lupinus angustifolius (lupin) to demonstrate the utility of whole genome sequencing and re-sequencing on the development of diagnostic markers for molecular plant breeding.

Results

Nine lupin cultivars released in Australia from 1973 to 2007 were subjected to whole genome re-sequencing. The re-sequencing data together with the reference genome sequence data were used in marker development, which revealed 180,596 to 795,735 SNP markers from pairwise comparisons among the cultivars. A total of 207,887 markers were anchored on the lupin genetic linkage map. Marker mining obtained an average of 387 SNP markers and 87 InDel markers for each of the 24 genome sequence assembly scaffolds bearing markers linked to 11 genes of agronomic interest. Using the R gene PhtjR conferring resistance to phomopsis stem blight disease as a test case, we discovered 17 candidate diagnostic markers by genotyping and selecting markers on a genetic linkage map. A further 243 candidate diagnostic markers were discovered by marker mining on a scaffold bearing non-diagnostic markers linked to the PhtjR gene. Nine out from the ten tested candidate diagnostic markers were confirmed as truly diagnostic on a broad range of commercial cultivars. Markers developed using these strategies meet the requirements for broad application in molecular plant breeding.

Conclusions

We demonstrated that low-cost genome sequencing and re-sequencing data were sufficient and very effective in the development of diagnostic markers for marker-assisted selection. The strategies used in this study may be applied to any trait or plant species. Whole genome sequencing and re-sequencing provides a powerful tool to overcome current limitations in molecular plant breeding, which will enable plant breeders to precisely pyramid favourable genes to develop super crop varieties to meet future food demands.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1878-5) contains supplementary material, which is available to authorized users.     

Leafing through the genomes of our major crop plants: strategies for capturing unique information

Crop plants not only have economic significance, but also comprise important botanical models for evolution and development. This is reflected by the recent increase in the percentage of publicly available sequence data that are derived from angiosperms. Further genome sequencing of the major crop plants will offer new learning opportunities, but their large, repetitive, and often polyploid genomes present challenges. Reduced-representation approaches - such as EST sequencing, methyl filtration and Cot-based cloning and sequencing - provide increased efficiency in extracting key information from crop genomes without full-genome sequencing. Combining these methods with phylogenetically stratified sampling to allow comparative genomic approaches has the potential to further accelerate progress in angiosperm genomics.     

Genetics and genomics of root symbiosis.

Model genetics and genomics have been developed as tools for studying the third largest family of flowering plants, the Leguminosae, which includes important crop plants. Functional genomics strategies for the global analysis of gene expression, the elucidation of pathways and reverse genetics are established. These approaches provide new possibilities for investigating rhizobial as well as mycorrhizal endosymbiosis. Plant genes with central functions in these mutualistic interactions have been identified by positional cloning and gene tagging. With progress in Lotus japonicus genome sequencing, which was recently initiated by Japanese researchers, comparative genomics will contribute to our understanding of symbiosis, pathogenesis and the evolution of plant genomes.     

High-Throughput Genomics Enhances Tomato Breeding Efficiency

Tomato (Solanum lycopersicum) is considered a model plant species for a group of economically important crops, such as potato, pepper, eggplant, since it exhibits a reduced genomic size (950 Mb), a short generation time, and routine transformation technologies. Moreover, it shares with the other Solanaceous plants the same haploid chromosome number and a high level of conserved genomic organization. Finally, many genomic and genetic resources are actually available for tomato, and the sequencing of its genome is in progress. These features make tomato an ideal species for theoretical studies and practical applications in the genomics field. The present review describes how structural genomics assist the selection of new varieties resistant to pathogens that cause damage to this crop. Many molecular markers highly linked to resistance genes and cloned resistance genes are available and could be used for a high-throughput screening of multiresistant varieties. Moreover, a new genomics-assisted breeding approach for improving fruit quality is presented and discussed. It relies on the identification of genetic mechanisms controlling the trait of interest through functional genomics tools. Following this approach, polymorphisms in major gene sequences responsible for variability in the expression of the trait under study are then exploited for tracking simultaneously favourable allele combinations in breeding programs using high-throughput genomic technologies. This aims at pyramiding in the genetic background of commercial cultivars alleles that increase their performances. In conclusion, tomato breeding strategies supported by advanced technologies are expected to target increased productivity and lower costs of improved genotypes even for complex traits.Key Words: Solanum lycopersicum, genetic and genomic resources, molecular markers, microarray, resistance to pathogens, fruit quality.     

Systemic Infection of Avocado,Persea americana,by Raffaelea lauricola,Does Not Progress Into Fruit Pulp or Seed

Avocado, Persea americana, is an important fruit crop in the tropics and warm subtropics. Laurel wilt, caused by Raffaelea lauricola, is a systemic vascular wilt of avocado that spread recently to Florida, an important producing state in the USA. As fruit and seed of avocado produced in Florida are sold in other states and countries where this crop is produced, there is concern that commerce in these commodities might spread this disease. Potted, fruit‐bearing trees were artificially inoculated with R. lauricola, and plants were systemically colonized by the fungus. In no instance did infection progress further than the hilum (87 total fruit), as determined by re‐isolation of R. lauricola on a semi‐selective medium or its detection, with qPCR and high fidelity PCR, of diagnostic small subunit (SSU) 18s rDNA. Thus, it would apparently be safe to propagate avocado with seed from trees affected by this disease. Pedicels/peduncles and hila associated with these fruit were colonized by the pathogen. The latter tissues would be associated with/attached to marketed fruit, but they do not harbour the pathogen’s ambrosia beetle vector, Xyleborus glabratus. Thus, commerce in avocado fruit appears to be a negligible risk for expanding the geographic range of laurel wilt.     

Agroclimatic modeling for the simulation of phenology,yield and quality of crop production

This paper describes the development of basic simulation concepts that can be used in models aimed at forecasting. The objective is to demonstrate the utility of considering the crop's basic environmental requirements or climatic normals in producing a self-contained comprehensive model. We seek to develop a model in which regularly measured weather data can be used to provide information on the crop performance. Following an abbreviated overview of modeling alternatives, the model design is described. The results of this study are a set of criteria and functions needed to predict the temporal evolution of phenological stages, fruit growth, fruit maturation, and fruit coloration for two varieties of oranges (Navel and Valencia). The major factors considered are the effect of temperature and solar radiation on flowering time, and flowering duration and the number of flowers; the effect of past stress, temperature, evaporation, wind, and rain, planting density, and tree age on fruit set. Given the number of fruits set, growth, maturation and coloration are modeled as responding primarily to temperature and water balance. Possible damage due to freezes is also modeled. These form the basis of a time dependent model (reported elsewhere) which uses daily air temperature and wind data for the prediction of these quantities. These criteria and functions are derived from an extensive body of published observations from many parts of the world, and are selected to be variety specific and independent of local climatology or other site-specific effects.     

尖孢镰刀菌致病机理和化感作用研究进展

尖孢镰刀菌引起的枯萎病在生产中的防控相当困难。通过总结国内外相关文献,综述近年来有关尖孢镰刀菌致病机理和化感作用的研究进展。尖孢镰刀菌通过分泌毒素和细胞壁降解酶共同致病,谱系特异性区域的存在是其致病性强和宿主范围广的主要原因;在尖孢镰刀菌各专化型中已分离出大量致病相关基因;其他植物和拮抗微生物(木霉菌、丛枝菌根真菌、非致病性尖孢镰刀菌以及植物生长促生菌)可以分泌化感物质,作用于宿主植物和尖孢镰刀菌,直接抑制尖孢镰刀菌的生长或激活宿主植物的防御反应。未来有关尖孢镰刀菌致病机理研究应该在基因组测序基础上构建精细的遗传图谱;对化感作用的研究应当深入探讨分子机理,利用高通量测序等技术在转录组或蛋白组水平上明确宿主植物抗枯萎病相关基因,同时利用分子标记辅助育种来筛选新的抗枯萎病品种。     

The response of transgenic <Emphasis Type="Italic">Brassica</Emphasis> species to salt stress: a review

Salt stress is considered one of the main abiotic factors to limit crop growth and productivity by affecting morpho-physiological and biochemical processes. Genetically, a number of salt tolerant Brassica varieties have been developed and introduced, but breeding of such varieties is time consuming. Therefore, current focus is on transgenic technology, which plays an important role in the development of salt tolerant varieties. Various salt tolerant genes have been characterized and incorporated into Brassica. Therefore, such genetic transformation of Brassica species is a significant step for improvement of crops, as well as conferring salt stress resistance qualities to Brassica species. Complete genome sequencing has made the task of genetically transforming Brassica species easier, by identifying desired candidate genes. The present review discusses relevant information about the principles which should be employed to develop transgenic Brassica species, and also will recommend tools for improved tolerance to salinity.     

Phylogenetic analysis of the plant-specific zinc finger-homeobox and mini zinc finger gene families

Zinc finger-homeodomain proteins (ZHD) are present in many plants; however, the evolutionary history of the ZHD gene family remains largely unknown. We show here that ZHD genes are plant-specific, nearly all intronless, and related to MINI ZINC FINGER ( MIF ) genes that possess only the zinc finger. Phylogenetic analyses of ZHD genes from representative land plants suggest that non-seed plant ZHD genes occupy basal positions and angiosperm homologs form seven distinct clades. Several clades contain genes from two or more major angiosperm groups, including eudicots, monocots, magnoliids, and other basal angiosperms, indicating that several duplications occurred before the diversification of flowering plants. In addition, specific lineages have experienced more recent duplications. Unlike the ZHD genes, MIF s are found only from seed plants, possibly derived from ZHD s by loss of the homeodomain before the divergence of seed plants. Moreover, the MIF genes have also undergone relatively recent gene duplications. Finally, genome duplication might have contributed substantially to the expansion of family size in angiosperms and caused a high level of functional redundancy/overlap in these genes.