Allotetraploid cotton species (Gossypium hirsutum and Gossypium barbadense) have long been cultivated worldwide for natural renewable textile fibers. The draft genome sequences of both species are available but they are highly fragmented and incomplete 1-4. Here we report referencegrade genome assemblies and annotations for G. hirsutum accession Texas Marker-1 (TM-1) and G. barbadense accession 3-79 by integrating single-molecule real-time sequencing, BioNano optical mapping and high-throughput chromosome conformation capture techniques. Compared with previous assembled draft genomes 1,3 , these genome sequences show considerable improvements in contiguity and completeness for regions with high content of repeats such as centromeres. Comparative genomics analyses identify extensive structural variations that probably occurred after polyploidization, highlighted by large paracentric/pericentric inversions in 14 chromosomes. We constructed an introgression line population to introduce favorable chromosome segments from G. barbadense to G. hirsutum, allowing us to identify 13 quantitative trait loci associated with superior fiber quality. These resources will accelerate evolutionary and functional genomic studies in cotton and inform future breeding programs for fiber improvement. Cotton represents the largest source of natural textile fibers in the world. Over 90% of annual fiber production comes from allotetraploid cotton (G. hirsutum and G. barbadense), which originated from an allopolyplodization event approximately 1-2 million year ago, followed by millennia of asymmetric subgenome selection 5,6. G. hirsutum is cultivated all over the world because of its high yield and G. barbadense is prized for its superior fiber quality. To cultivate G. hirsutum that produces longer, finer and stronger fibers, one approach is to introduce the superior fiber traits from G. barbadense into G. hirsutum. A genomics-enabled breeding strategy requires a detailed and robust understanding of genomic organization. Genomic feature G. hirsutum G. barbadense
The incompatible pathosystem between resistant cotton (Gossypium barbadense cv. 7124) and Verticillium dahliae strain V991 was used to study the cotton transcriptome changes after pathogen inoculation by RNA-Seq. Of 32 774 genes detected by mapping the tags to assembly cotton contigs, 3442 defence-responsive genes were identified. Gene cluster analyses and functional assignments of differentially expressed genes indicated a significant transcriptional complexity. Quantitative real-time PCR (qPCR) was performed on selected genes with different expression levels and functional assignments to demonstrate the utility of RNA-Seq for gene expression profiles during the cotton defence response. Detailed elucidation of responses of leucine-rich repeat receptor-like kinases (LRR-RLKs), phytohormone signalling-related genes, and transcription factors described the interplay of signals that allowed the plant to fine-tune defence responses. On the basis of global gene regulation of phenylpropanoid metabolism-related genes, phenylpropanoid metabolism was deduced to be involved in the cotton defence response. A closer look at the expression of these genes, enzyme activity, and lignin levels revealed differences between resistant and susceptible cotton plants. Both types of plants showed an increased level of expression of lignin synthesis-related genes and increased phenylalanine-ammonia lyase (PAL) and peroxidase (POD) enzyme activity after inoculation with V. dahliae, but the increase was greater and faster in the resistant line. Histochemical analysis of lignin revealed that the resistant cotton not only retains its vascular structure, but also accumulates high levels of lignin. Furthermore, quantitative analysis demonstrated increased lignification and cross-linking of lignin in resistant cotton stems. Overall, a critical role for lignin was believed to contribute to the resistance of cotton to disease.
Publisher's copyright statement:Additional information: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-pro t purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. Dt, 0.56 × 10 -3 ) ( Fig. 1d and Supplementary Fig. 3). This shows that a large amount is associated with the development of the long fiber trait in cultivated cotton (Fig. 3b). 217Domestication has led to the transformation of cotton fiber from brown to white. 218To understand this phenomenon, we examined two homoeologous gene pairs only 219 subjected to domestication selection in the Dt, 4-COUMARATE:COA LIGASE (4CL) 220 and CHALCONE SYNTHASE (CHS), which encode enzymes involved in the 221 phenylpropanoid metabolic pathway ( Fig. 3c and Supplementary Fig. 6 Fig. 3c). These SNPs display reductions in nucleotide diversity that occurred 225 during domestication (Fig. 3c). Interestingly, we found that the two SNPs in the Fig. 8) 42 . We identified a total of 188,360 DNase I-hypersensitive 248 sites (DHSs) in cotton leaves and fibers, of which ca. 47% are common to both tissues 249 (Fig. 4a). DHSs were preferentially identified in chromosomal arms and 250 approximately half were detected in promoter and intergenic regions ( Fig. 4b and 251 Supplementary Fig. 9). We found DHSs are hypo-methylated, consistent with 252 previous studies 42 (Fig. 4c) H3K4me1 and inactive H3K9me2 (Fig. 4d). Intergenic DHSs were also found to 255 exhibit an enrichment of H3K4me3 and H3K27me3, but depletion of H3K9me2 and 256 no enrichment of H3K4me1 (Fig. 4e). As predicted, the patterns of chromatin 257 modification marks in cotton are different between genic and TE regions 258 ( Supplementary Fig. 10). In addition, genes with promoter DHSs are generally 259 expressed at a higher level in both tissues than those without promoter DHSs (Fig. 4f), 260 and tissue-specific promoter DHSs corresponded to higher levels of gene expression 261 ( Fig. 4g) Hi-C analysis was carried out using the TM-1 accession to characterize global 296 chromatin interactions. We generated 1.1 billion Hi-C paired-end reads, of which ca. possible Hi-C bias, HindIII fragments of less than 2 kb were merged to obtain 299 305,682 chromosomal anchor regions (Fig. 5a). On the basis of a high-quality 300 genome assembly of TM-1 (Supplementary Fig. 11), we used the Hi-C data to 301 characterize the cotton chromatin interactome (Supplementary Fig. 12) and ( Fig. 5b), but many topologically associated domain-like (TAD-like) regions were 305 identified (Fig. 5c, Supplementary Fig. 13 and Supplementary are less frequent at regions marked by H3K9me2 (Fig. 5d). (Fig. 5g). 320We...
Notch ligands and receptors have been implicated in helper T cell (Th cell) differentiation. Whether Notch signals are involved in differentiation of T helper type 1 (Th1) cells, Th2 cells, or both, however, remains unresolved. To clarify the role of Notch in Th cell differentiation, we generated mice that conditionally inactivate Notch signaling in mature T cells. Mice that lack Notch signaling in CD4+ T cells fail to develop a protective Th2 cell response against the gastrointestinal helminth Trichuris muris. In contrast, they exhibit effective Th1 cell responses and are able to control Leishmania major infection. These data demonstrate that Notch signaling is a regulator of type 2 immunity.
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