Abstract:The genus Solanum comprises three food crops (potato, tomato, and eggplant), which are consumed on daily basis worldwide and also producers of notorious anti-nutritional steroidal glycoalkaloids (SGAs). Hydroxylated SGAs (i.e. leptinines) serve as precursors for leptines that act as defenses against Colorado Potato Beetle (Leptinotarsa decemlineata Say), an important pest of potato worldwide. However, SGA hydroxylating enzymes remain unknown. Here, we discover that 2-OXOGLUTARATE-DEPENDENT-DIOXYGENASE (2-ODD) … Show more
“…The content of downstream SGAs decreases gradually after the Br period along with the expression of the downstream biosynthesis-related gene GAME31 . These results are consistent with those of a previous study [ 40 ]. Fig.…”
Section: Resultssupporting
confidence: 94%
“…7 a). In contrast, GAME31 was mainly expressed at the tomato fruit ripening stage and catalyzes the first important step in the chemical shift after maturation within nonbitter SGA by a hydroxylation reaction [ 39 , 40 ]. Interestingly, we found that the different expression patterns between GAME11 and GAME31 resulted in the appropriate function at the right time.…”
Background
2-Oxoglutarate and Fe(II)-dependent dioxygenases (2ODDs) belong to the 2-oxoglutarate-dependent dioxygenase (2OGD) superfamily and are involved in various vital metabolic pathways of plants at different developmental stages. These proteins have been extensively investigated in multiple model organisms. However, these enzymes have not been systematically analyzed in tomato. In addition, type I flavone synthase (FNSI) belongs to the 2ODD family and contributes to the biosynthesis of flavones, but this protein has not been characterized in tomato.
Results
A total of 131 2ODDs from tomato were identified and divided into seven clades by phylogenetic classification. The Sl2ODDs in the same clade showed similar intron/exon distributions and conserved motifs. The Sl2ODDs were unevenly distributed across the 12 chromosomes, with different expression patterns among major tissues and at different developmental stages of the tomato growth cycle. We characterized several Sl2ODDs and their expression patterns involved in various metabolic pathways, such as gibberellin biosynthesis and catabolism, ethylene biosynthesis, steroidal glycoalkaloid biosynthesis, and flavonoid metabolism. We found that the Sl2ODD expression patterns were consistent with their functions during the tomato growth cycle. These results indicated the significance of Sl2ODDs in tomato growth and metabolism. Based on this genome-wide analysis of Sl2ODDs, we screened six potential FNSI genes using a phylogenetic tree and coexpression analysis. However, none of them exhibited FNSI activity.
Conclusions
Our study provided a comprehensive understanding of the tomato 2ODD family and demonstrated the significant roles of these family members in plant metabolism. We also suggest that no FNSI genes in tomato contribute to the biosynthesis of flavones.
“…The content of downstream SGAs decreases gradually after the Br period along with the expression of the downstream biosynthesis-related gene GAME31 . These results are consistent with those of a previous study [ 40 ]. Fig.…”
Section: Resultssupporting
confidence: 94%
“…7 a). In contrast, GAME31 was mainly expressed at the tomato fruit ripening stage and catalyzes the first important step in the chemical shift after maturation within nonbitter SGA by a hydroxylation reaction [ 39 , 40 ]. Interestingly, we found that the different expression patterns between GAME11 and GAME31 resulted in the appropriate function at the right time.…”
Background
2-Oxoglutarate and Fe(II)-dependent dioxygenases (2ODDs) belong to the 2-oxoglutarate-dependent dioxygenase (2OGD) superfamily and are involved in various vital metabolic pathways of plants at different developmental stages. These proteins have been extensively investigated in multiple model organisms. However, these enzymes have not been systematically analyzed in tomato. In addition, type I flavone synthase (FNSI) belongs to the 2ODD family and contributes to the biosynthesis of flavones, but this protein has not been characterized in tomato.
Results
A total of 131 2ODDs from tomato were identified and divided into seven clades by phylogenetic classification. The Sl2ODDs in the same clade showed similar intron/exon distributions and conserved motifs. The Sl2ODDs were unevenly distributed across the 12 chromosomes, with different expression patterns among major tissues and at different developmental stages of the tomato growth cycle. We characterized several Sl2ODDs and their expression patterns involved in various metabolic pathways, such as gibberellin biosynthesis and catabolism, ethylene biosynthesis, steroidal glycoalkaloid biosynthesis, and flavonoid metabolism. We found that the Sl2ODD expression patterns were consistent with their functions during the tomato growth cycle. These results indicated the significance of Sl2ODDs in tomato growth and metabolism. Based on this genome-wide analysis of Sl2ODDs, we screened six potential FNSI genes using a phylogenetic tree and coexpression analysis. However, none of them exhibited FNSI activity.
Conclusions
Our study provided a comprehensive understanding of the tomato 2ODD family and demonstrated the significant roles of these family members in plant metabolism. We also suggest that no FNSI genes in tomato contribute to the biosynthesis of flavones.
“…The high α‐tomatine levels in immature fruit decrease during ripening by the conversion to esculeoside A (Fig. 1; Mintz‐Oron et al ., 2008; Iijima et al ., 2009; Cárdenas et al ., 2019; Nakayasu et al ., 2020). The antimicrobial activity of α‐tomatine was first demonstrated on the fungal pathogen Fusarium oxysporum f. sp.…”
Section: α‐Tomatine: the Major Tomato Saponin With Antibiotic Activitymentioning
The glycoalkaloid saponin α-tomatine is a tomato-specific secondary metabolite that accumulates to mM levels in vegetative tissues, and has antimicrobial and antinutritional activity that kills microbial pathogens and deters herbivorous insects. We describe recent insights into the biosynthetic pathway of α-tomatine synthesis and its regulation. We discuss the mode of action of α-tomatine by physically interacting with sterols and thereby disrupting membranes, and how tomato protects itself from its toxic action. Tomato pathogenic microbes can enzymatically hydrolyse and thereby inactivate α-tomatine using either of three distinct types of glycosyl hydrolases. We also describe findings which extend well beyond the simple concept of plants producing toxins and pathogens inactivating them. There are reports that toxicity of α-tomatine is modulated by external pH; that α-tomatine can trigger programmed cell death in fungi; that cellular localization matters for the impact of α-tomatine on invading microbes; and that α-tomatine breakdown products generated by microbial hydrolytic enzymes can modulate plant immune responses. Finally we address a number of outstanding questions that deserve attention in the future.
“…Tomato and eggplant, on the other hands, contain only spirosolane glycoalkaloids 3 , 13 . In tomato, α-tomatine 5 and dehydrotomatine 6 are predominant in green tissues, while the non-bitter SGA esculeoside A is the major component in the red mature fruits 14 , 15 . α-Solasonine and α-solamargine are the two major spirosolane glycoalkaloids produced in eggplant 16 .…”
Potato (Solanum tuberosum), a worldwide major food crop, produces the toxic, bitter tasting solanidane glycoalkaloids α-solanine and α-chaconine. Controlling levels of glycoalkaloids is an important focus on potato breeding. Tomato (Solanum lycopersicum) contains a bitter spirosolane glycoalkaloid, α-tomatine. These glycoalkaloids are biosynthesized from cholesterol via a partly common pathway, although the mechanisms giving rise to the structural differences between solanidane and spirosolane remained elusive. Here we identify a 2-oxoglutarate dependent dioxygenase, designated as DPS (Dioxygenase for Potato Solanidane synthesis), that is a key enzyme for solanidane glycoalkaloid biosynthesis in potato. DPS catalyzes the ring-rearrangement from spirosolane to solanidane via C-16 hydroxylation. Evolutionary divergence of spirosolane-metabolizing dioxygenases contributes to the emergence of toxic solanidane glycoalkaloids in potato and the chemical diversity in Solanaceae.
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