High-Density Linkage Map Construction and Mapping of Salt-Tolerant QTLs at Seedling Stage in Upland Cotton Using Genotyping by Sequencing (GBS).

Over 6% of agricultural land is affected by salinity. It is becoming obligatory to use saline soils, so growing salt-tolerant plants is a priority. To gain an understanding of the genetic basis of upland cotton tolerance to salinity at seedling stage, an intra-specific cross was developed from CCRI35, tolerant to salinity, as female with Nan Dan (NH), sensitive to salinity, as the male. A genetic map of 5178 SNP markers was developed from 277 F2:3 populations. The map spanned 4768.098 cM, with an average distance of 0.92 cM. A total of 66 QTLs for 10 traits related to salinity were detected in three environments (0, 110, and 150 mM salt treatment). Only 14 QTLs were consistent, accounting for 2.72% to 9.87% of phenotypic variation. Parental contributions were found to be in the ratio of 3:1, 10 QTLs from the sensitive and four QTLs from the resistant parent. Five QTLs were located in At and nine QTLs in the Dt sub-genome. Moreover, eight clusters were identified, in which 12 putative key genes were found to be related to salinity. The GBS-SNPs-based genetic map developed is the first high-density genetic map that has the potential to provide deeper insights into upland cotton salinity tolerance. The 12 key genes found in this study could be used for QTL fine mapping and cloning for further studies.

[Effect of silencing lycB gene on the carotenoid synthesis in Haematococcus pluvialis].

Haematococcus pluvialis is a freshwater planktonic single-cell microalgae. It will accumulate high amount of carotenoids under unfavorable environmental conditions. As one of carotenoids, lycopene is an important intermediate in the carotenoid biosynthesis pathway. Lycopene ß-cyclase (LycB) is the key enzyme that catalyzes the circularization of lycopene to form ß-carotene. In this study, we constructed a p1301-BS-RNAi vector using lycB from Dunaliella salina as the interference sequence with kanamycin and atrazine resistance marker, and then transformed it into H. pluvialis by electroporation. Sixteen independent transgenic lines were obtained after resistance selection, genome PCR, and RT-PCR analyses. Seven well-grown lines were selected to determine the contents of carotenoids by HPLC analysis after inducing by high light. The lycopene content in these lines was increased by 99.4% while the ß-carotene content was decreased by 48.4%, indicating that the interference by heterogenous lycB could inhibit the conversion of lycopene into ß-carotene. The amount of increase in lycopene was only 5% of the amount of decrease in ß-carotene, indicating that 95% of the decreased ß-carotene was converted into other metabolites. Therefore, in order to largely increase the lycopene content in H. pluvialis, it is necessary to coordinatively regulate other metabolic pathways.