Cryptic introgressions contribute to transgressive segregation for early blight resistance in tomato.

KEY MESSAGE: We identified cryptic early blight resistance introgressions in tomato breeding lines and demonstrated efficient genotypic selection for resistance in the context of a tomato breeding program. Early blight is a widespread and problematic disease affecting tomatoes (Solanum lycopersicum). Caused by the fungal pathogen Alternaria linariae (syn. A. tomatophila), symptoms include lesions on tomato stems, fruit, and foliage, often resulting in yield losses. Breeding tomatoes with genetic resistance would enhance production sustainability. Using cross-market breeding populations, we identified several quantitative trait loci (QTL) associated with early blight resistance. Early blight resistance putatively derived from 'Campbell 1943' was confirmed in modern fresh market tomato breeding lines. This resistance offered substantial protection against early blight stem lesions (collar rot) and moderate protection from defoliation. A distinctive and potentially novel form of early blight foliar resistance was discovered in a processing tomato breeding line and is probably derived from S. pimpinellifolium via 'Hawaii 7998'. Additional field trials validated the three most promising large-effect QTL, EB-1.2, EB-5, and EB-9. Resistance effects for EB-5 and EB-9 were consistent across breeding populations and environments, while EB-1.2's effect was population specific. Using genome-wide marker-assisted backcrossing, we developed fresh market tomato lines that were near-isogenic for early blight QTL. Resistance in these lines was largely mediated by just two QTL, EB-5 and EB-9, that together captured 49.0 and 68.7% of the defoliation and stem lesion variance, respectively. Our work showcases the value of mining cryptic introgressions in tomato lines, and across market classes, for use as additional sources of disease resistance.

CRISPR/CAS9 mutagenesis of a single r-opsin gene blocks phototaxis in a marine larva.

Many marine animals depend upon a larval phase of their life cycle to locate suitable habitat, and larvae use light detection to influence swimming behaviour and dispersal. Light detection is mediated by the opsin genes, which encode light-sensitive transmembrane proteins. Previous studies suggest that r-opsins in the eyes mediate locomotory behaviour in marine protostomes, but few have provided direct evidence through gene mutagenesis. Larvae of the marine annelid Capitella teleta have simple eyespots and are positively phototactic, although the molecular components that mediate this behaviour are unknown. Here, we characterize the spatio-temporal expression of the rhabdomeric opsin genes in C. teleta and show that a single rhabdomeric opsin gene, Ct-r-opsin1, is expressed in the larval photoreceptor cells. To investigate its function, Ct-r-opsin1 was disrupted using CRISPR/CAS9 mutagenesis. Polymerase chain reaction amplification and DNA sequencing demonstrated efficient editing of the Ct-r-opsin1 locus. In addition, the pattern of Ct-r-opsin1 expression in photoreceptor cells was altered. Notably, there was a significant decrease in larval phototaxis, although the eyespot photoreceptor cell and associated pigment cell formed normally and persisted in Ct-r-opsin1-mutant animals. The loss of phototaxis owing to mutations in Ct-r-opsin1 is similar to that observed when the entire photoreceptor and pigment cell are deleted, demonstrating that a single r-opsin gene is sufficient to mediate phototaxis in C. teleta. These results establish the feasibility of gene editing in animals like C. teleta, and extend previous work on the development, evolution and function of the C. teleta visual system . Our study represents one example of disruption of animal behaviour by gene editing through CRISPR/CAS9 mutagenesis, and has broad implications for performing genome editing studies in a wide variety of other understudied animals.

Candidate gene analysis of anthocyanin pigmentation loci in the Solanaceae.

Crop species in the Solanaceae, which includes tomato ( Lycopersicon esculentum), potato ( Solanum tuberosum), pepper ( Capsicum spp.), and eggplant ( S. melongena), exhibit natural variation in the types, levels, and tissue-specific expression patterns of anthocyanin pigments. While the identities of the genes underpinning natural variation in anthocyanin traits in these crops are largely unknown, many structural genes and regulators of anthocyanin biosynthesis have been isolated from the solanaceous ornamental species Petunia. To identify candidate genes that may correspond to loci controlling natural variation in the four crops, 13 anthocyanin-related genes were localized on a tomato F(2) genetic map. Gene map positions were then compared to mapped mutants in tomato and through comparative genetic maps to natural variants in potato, eggplant, and pepper. Similar map positions suggest that the tomato mutants anthocyaninless, entirely anthocyaninless, and anthocyanin gainer correspond to flavonoid 3'5'-hydroxylase ( f3'5'h), anthocyanidin synthase, and the Petunia Myb domain trancriptional regulatory gene an2, respectively. Similarly potato R, required for the production of red pelargonidin-based pigments, P, required for production of purple delphinidin-based pigments, and I, required for tissue-specific expression in tuber skin, appear to correspond to dihydroflavonol 4-reductase, f3'5'h and an2, respectively. The map location of an2 also overlaps pepper A and eggplant fap10.1, lla10.1, lra10.1, sa10.1, pa10.1 and ca10.1, suggesting that a homologous regulatory locus has been subjected to parallel selection in the domestication of many solanaceous crops. To test the hypothesis that tomato anthocyaninless corresponds to f3'5'h, a portion of the gene was sequenced. A premature stop codon was observed in an anthocyaninless mutant, but not in wild-type.

A fluorogenic 5' nuclease (TaqMan) assay to assess dosage of a marker tightly linked to red skin color in autotetraploid potato.

We have recently identified an allele of dihydroflavonol 4-reductase ( dfr) that cosegregates with the ability of potato ( Solanum tuberosum L) to produce red pelargonidin-based anthocyanin pigments. A rapid assay to assess dosage of this allele in cultivated potato, an autotetraploid, would be useful for breeding programs that develop red-skinned cultivars. To identify regions of dfr that are conserved between alleles, as well as regions that are variable, a portion of the gene was sequenced from several cultivated and wild potato clones. In one region the sequence of the 'red' dfr allele differed at two nucleotide positions from the three other sequence classes observed. A fluorogenic oligonucleotide probe labeled with 6-FAM was designed to anneal specifically to the red allele in this region, while a second probe labeled with VIC was designed to anneal to the 'not-red' dfr alleles. PCR primers that annealed to conserved sequences flanking the variable region were also developed. When subjected to a fluorogenic 5' nuclease (TaqMan) allelic discrimination assay all diploid clones tested clustered into three distinct groups based on the relative amounts of FAM and VIC released. These three groups represented clones homozygous for the red allele, heterozygous for the red allele, and homozygous for the not-red allele(s). When tetraploid clones were tested they separated into five distinct clusters, three of which were shared with diploid clones. The five clusters were interpreted to represent clones quadruplex, triplex, duplex, simplex and nulliplex for the red dfr allele. This interpretation was supported by monitoring the segregation of red allele dosage in several tetraploid crosses. To the best of our knowledge this is the first report of a fluorogenic 5' nuclease assay being used for allelic discrimination in an autopolyploid.

An allele of dihydroflavonol 4-reductase associated with the ability to produce red anthocyanin pigments in potato (Solanum tuberosum L.).

The potato R locus is necessary for the production of red pelargonidin-based anthocyanin pigments in any tissue of the plant, including tuber skin and flower petals. The production of pelargonidins in plants requires the activity of dihydroflavonol 4-reductase (DFR) to catalyze the reduction of dihydrokaempferol into leucopelargonidin. To test the hypothesis that potato R encodes DFR, portions of both dfr alleles were sequenced from a diploid potato clone known to be heterozygous Rr. Sequence comparison revealed a polymorphic BamHI restriction site. The presence or absence of this site was monitored in three diploid populations that segregated for R, as well as in a wide range of tetraploid breeding clones and cultivars, by amplifying a fragment of dfr and digesting the products with BamHI. An identically sized dfr restriction fragment lacking the BamHI site was present in all potato clones that produced red anthocyanin pigments, while the same fragment was absent in many potato clones with white tuber skin and flowers. An independent RFLP test using DraI to detect sequence polymorphism was performed on a subset of the potato clones. This test also revealed dfr-derived bands that were present in all red-colored potatoes and absent in several white clones. The presence of shared restriction fragments in all red-colored potatoes provides strong evidence that R does indeed code for DFR. The data are also consistent with a 48 year-old hypothesis by Dodds and Long, that R was selected just once during the domestication of potato. A cDNA clone corresponding to the red allele of dfr was sequenced and compared to two other alleles. The red allele is predicted to encode a 382 amino acid protein that differs at ten amino acid positions from the gene products of the two alternative alleles. Several of these differences map in a region known to influence DFR substrate specificity in Gerbera.

Atracurium induced vasodilatation is not mediated by histamine in the isolated femoral artery of the rabbit.

Atracurium causes a decrease in systemic vascular resistance (SVR) and mean arterial blood pressure (MAP) which has been ascribed to histamine release. However, histamine receptor blockade does not prevent these decreases completely. The hypotensive side effects of atracurium may not only be caused by histamine. In this study we examined the vasoactive effects of atracurium with and without histamine receptor blockade in an isolated femoral artery preparation of the rabbit. We also investigated whether vasodilatation caused by atracurium depends on the presence of endothelial cells. Tyrode perfused, rabbit femoral arteries were constricted with noradrenaline (NA) to +/- 70% of their passive diameter. Endothelial function was checked with acetylcholine (ACh). The vessels were divided into two groups. In both groups the responses to histamine (1.0-10(-6)M) and atracurium (3.2-10(-5)M) were determined. In group one (n = 5), the histamine and atracurium responses were repeated during histamine receptor blockade. In group two (n = 5), the diameter responses to histamine and atracurium before and after endothelium removal were compared. Also, some vessel segments (n = 5) were histologically prepared and examined for mast cells. The vasodilatory responses to atracurium both with and without histamine receptor blockade were the same. Removal of endothelium caused an increase in the histamine response, while the dilating response to atracurium remained constant. We conclude that in the isolated femoral artery of the rabbit, atracurium induces, vasodilatation that is not mediated by histamine release and cannot be prevented with histamine receptor blockade. The mechanism of atracurium induced dilation is independent of the endothelium and is located in the smooth muscle cell.

Lipopolysaccharidelike immunological properties of cell wall glycoproteins isolated from Cytophaga johnsonae.

Glycoproteins (GP) previously shown to be involved in the gliding motility of Cytophaga johnsonae were examined for biological activities characteristic of lipopolysaccharide (LPS). These integral membrane proteins activated 70Z/3 pre-B cells to synthesize immunoglobulin M, induced B cells to synthesize non-antigen-specific polyclonal immunoglobulin, induced macrophages to produce tumor necrosis factor, and modulated the antibody response to type III pneumococcal polysaccharide in the absence of thymus-derived (T) lymphocytes. Except for the GP activity in the 70Z/3 assay, all activities of the GP were comparable to or greater than those of LPS. No LPS was detected in the preparations of GP used or in the phenol-water extracts of C. johnsonae. The mechanism by which these GP exerted their biological activities was distinct from that of LPS, since LPS-resistant C3H/HeJ mice responded to GP. Furthermore, biologically inactive diphosphoryl lipid A obtained from nontoxic LPS of Rhodopseudomonas sphaeroides (an analog of toxic lipid A), which is an antagonist of LPS, did not block the induction of tumor necrosis factor by GP in macrophages. These results showed that the cell surface GP from C. johnsonae are potent LPS-like activators of B cells and macrophages. We suggest that these GP might be good candidates for use in developing an effective adjuvant system.

Use of nonmotile mutants to identify a set of membrane proteins related to gliding motility in Cytophaga johnsonae.

Nonmotile mutants of the gliding bacterium Cytophaga johnsonae were examined to identify proteins that might be involved in gliding motility. Wild-type and mutant cell proteins were solubilized and fractionated by using Triton X-114, and the proteins that partitioned into the aqueous phase or the detergent phase were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis for proteins that differed between wild-type and mutant cells. Seventeen proteins, ranging in size from 16 to 150 kilodaltons, were implicated by this technique as having some relationship to gliding and were designated Gld-1 through Gld-17. All Gld proteins behaved as integral membrane proteins, partitioning into the detergent phase. All 56 mutants examined exhibited changes in 1 or more of the Gld proteins, with the number of proteins altered in any mutant varying from 1 to 11. Several lines of evidence suggested that proteins Gld-12 through Gld-15 are glycoproteins. Analysis of banding patterns of detergent-fraction proteins of motile revertants supported the idea that the Gld proteins have a role in gliding motility.