Transcriptome sequencing of active buds from Populus deltoides CL. and Populus × zhaiguanheibaiyang reveals phytohormones involved in branching.

Branching in woody plants affects their ecological benefits and impacts wood formation. To obtain genome-wide insights into the transcriptome changes and regulatory mechanisms associated with branching, we performed high-throughput RNA sequencing to characterize cDNA libraries generated from active buds of Populus deltoides CL. 'zhonglin2025' (BC) and Populus × zhaiguanheibaiyang (NC). NC has more branches than BC and rapid growth. We obtained a total of 198.2 million high-quality clean reads from the NC and BC libraries. We detected 3543 differentially expressed genes (DEGs) between the NC and BC libraries; 1418 were down-regulated and 2125 were up-regulated. Gene ontology functional classification of the DEGs indicated that they included 89 genes that encoded proteins related to hormone biosynthesis, 364 genes related to hormone signaling transduction, and 104 related to the auxin efflux transmembrane transporter. We validated the expression profiles of 16° by real-time quantitative PCR and found that their expression patterns were similar to those obtained from the high-throughput RNA sequencing data. We also measured the hormone content in young buds of BC and NC by high-pressure liquid chromatography. In this study, we identified global hormone regulatory patterns and differences in gene expression between NC and BC, and constructed a hormone regulatory network to explain branching in Populus buds. In addition, candidate genes that may be useful for molecular breeding of particular plant types were identified. Our results will provide a starting point for future investigations into the molecular mechanisms of branching in Populus.

Molecular cloning and heterologous expression analysis of JrVTE1 gene from walnut (Juglans regia).

Tocopherol cyclase (VTE1) plays a key role in promoting the production of γ-tocopherol and improving total tocopherol content in photosynthetic organisms. Walnut is an important source of tocopherols in the human diet, and γ-tocopherol is the major tocopherol compound in walnut kernels. In this study, a full-length cDNA of the VTE1 gene was isolated from walnut using RT-PCR and RACE, and designated as JrVTE1. The full-length cDNA of the JrVTE1 gene contained a 1353-bp open-reading frame encoding a 451-amino-acid protein with a calculated molecular weight of 49.5 kDa. The deduced JrVTE1 protein had a considerable homology with other plant VTE1s and belonged to the tocopherol cyclase family. Functional characterization of JrVTE1 by heterologous expression was carried out in E. coli BL21 (DE3) and microshoot lines of the fruit trees jujube (Zizyphus jujuba var. spinosa) and pear (Pyrus communis) cultivar 'Old Home'. JrVTE1 in E. coli expressed as a 50 kDa protein, as expected. One or two copies of the transferred JrVTE1 gene were detected in the genomes of representative transgenic lines (from the initial transgenic plants) of jujube and pear by gel blots analysis. Over-expression of JrVTE1 in jujube and pear resulted in an accumulation of tocopherol and a shift in tocopherol composition in leaf, root and stem tissues. In the transgenic jujube, the total tocopherol content increased by 29.8 µg/g in the stems of line J3, 43.7 and 22.5 µg/g in the roots and leaves of line J1, respectively, whereas in the transgenic pear it increased by 47.3 µg/g in the leaf of line P3, and 16.7 and 10.4 µg/g in roots and stems of line P9, respectively. In the examined tissues of transgenic plants, the highest accumulation rate was the γ-tocopherol. These results indicate that JrVTE1 is one of the rate-limiting enzymes for tocopherol production and could be used to improve the tocopherol content of tree crops through genetic engineering.

Construction of a high-density genetic map using specific length amplified fragment markers and identification of a quantitative trait locus for anthracnose resistance in walnut (Juglans regia L.).

BACKGROUND: Walnut (Juglans regia, 2n = 32, approximately 606 Mb per 1C genome) is an economically important tree crop. Resistance to anthracnose, caused by Colletotrichum gloeosporioides, is a major objective of walnut genetic improvement in China. The recently developed specific length amplified fragment sequencing (SLAF-seq) is an efficient strategy that can obtain large numbers of markers with sufficient sequence information to construct high-density genetic maps and permits detection of quantitative trait loci (QTLs) for molecular breeding. RESULTS: SLAF-seq generated 161.64 M paired-end reads. 153,820 SLAF markers were obtained, of which 49,174 were polymorphic. 13,635 polymorphic markers were sorted into five segregation types and 2,577 markers of them were used to construct genetic linkage maps: 2,395 of these fell into 16 linkage groups (LGs) for the female map, 448 markers for the male map, and 2,577 markers for the integrated map. Taking into account the size of all LGs, the marker coverage was 2,664.36 cM for the female map, 1,305.58 cM for the male map, and 2,457.82 cM for the integrated map. The average intervals between two adjacent mapped markers were 1.11 cM, 2.91 cM and 0.95 cM for three maps, respectively. 'SNP_only' markers accounted for 89.25% of the markers on the integrated map. Mapping markers contained 5,043 single nucleotide polymorphisms (SNPs) loci, which corresponded to two SNP loci per SLAF marker. According to the integrated map, we used interval mapping (Logarithm of odds, LOD > 3.0) to detect our quantitative trait. One QTL was detected for anthracnose resistance. The interval of this QTL ranged from 165.51 cM to 176.33 cM on LG14, and ten markers in this interval that were above the threshold value were considered to be linked markers to the anthracnose resistance trait. The phenotypic variance explained by each marker ranged from 16.2 to 19.9%, and their LOD scores varied from 3.22 to 4.04. CONCLUSIONS: High-density genetic maps for walnut containing 16 LGs were constructed using the SLAF-seq method with an F1 population. One QTL for walnut anthracnose resistance was identified based on the map. The results will aid molecular marker-assisted breeding and walnut resistance genes identification.

Genetic relationships of ornamental cultivars of Ginkgo biloba analyzed by AFLP techniques.

Eight primer combinations that produced clear and a large number of polymorphic bands were screened from 64 EcoR I/Mse I primer combinations (Mse I fluorescent labeled). The genetic relationships of 21 ornamental cultivars of Ginkgo biloba L. from the United States of America, Holland, Japan, France, and China were analyzed. These primer combinations produced a total of 1 119 bands, 229 specific loci (including 54 absent bands, and 175 monomorphic bands). Among them, 983 polymorphic bands (PPB), accounting for 88%, were detected. The percentage of identification per primer combination was as high as 100%. The average PPB of 14 foreign cultivars was 35.86% and the average PPB of seven domestic cultivars was 31.51%. Genetic similarity coefficient (SC) among all cultivars varied from 0.4899 to 0.8499, and all cultivars were divided into the four clusters when SC was set at 0.7300. The cultivars from the same origin did not fall into the same group. The cultivars from France and China were classified into three groups. According to the comprehensive analyses based on specific loci, similarity coefficient, and clustering results, eight cultivars 'Fastigiata', 'Tit', 'Tubifolia', 'Daeryinxing', 'Variegata', 'Horizontalis, 'Pendula', and 'Yiyuanyeziyinxing' were considered to be important germplasms of ornamental cultivars of Ginkgo biloba.

[Mapping of seedlessness gene in grapes using SCAR markers].

Nine primers (including UBC-269 and GSLP1) were designed and synthesized based on DNA sequences of UBC-269(484) and GSLP1(569). The template DNA from Red Globe (seeded paternal parent) and Flame Seedless (seedless maternal parent) were screened using these primers. For Flame Seedless,GSLP1 yielded specific marker GSLP1(569); No. 39970524-5 primer yielded specific marker 39970524-5-564; and No. 6 primer yielded specific marker 39970524-6-1538 and 39970524-6-1200. GSLP1, No. 39970524-5, and No. 39970524-6 primers were used specifically to screen template DNA from the experimental plant materials. The results showed that the specific markers GSLP1(569), 39970524-5-564,39970524-6-1538 and 39970524-6-1200 were cosegregating with the major seedlessness gene. All these specific loci were also present in Thompson Seedless which was the initial donor of the seedlessness gene. It suggests that these SCAR markers are linked to a major grape seedlessness gene S. Markers order and map distance were estimated using the software 'QTXb17'. This showed that GSLP1(569), 39970524-5-564,39970524-6-1538 and 39970524-6-1200 were tightly linked to gene S. When P = 0.01,confidence limits for map distance ranged from 0.2 to 9.9; standard errors of map distance were from 0.6 to 1.9; LOD for linkage were from 32.7 to 46.4. These markers and the gene S were found to be in the same group. The markers were located on either side of gene S, covering 12.3 cM of the grape genome. The genetic distances between gene S and 39970524-5-564, GSLP1(569), 39970524-6-1538 and 39970524-6-1200 were 0.6 cM, 1.2 cM, 4.9 cM and 11.1 cM respectively.