Genome-wide analysis identifies gain and loss/change of function within the small multigenic insecticidal Albumin 1 family of Medicago truncatula

Karaki, Lamis; Silva, P da; Chouabe, Christophe; Chantret, Nathalie; Eyraud, Vanessa; Gressent, Frédéric; Sivignon, Catherine; Rahioui, Isabelle; Kahn, Daniel; Brochier-Armanet, Céline; Rahbé, Yvan; Royer, Corinne

doi:10.1186/s12870-016-0745-0

Cited by 16 publications

(23 citation statements)

References 70 publications

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“…As mentioned previously, plants also contain albumins; however, those are not phylogenetically related to the animal albumins. 39 This fact is consistent with the concept of albumin, which are water soluble, moderately soluble in concentrated salt solutions, not evolutionarily related, and experience heat denaturation. 1 Therefore, just to avoid possible confusion, for the following sections of this article, albumins solely refer to those from animals if not otherwise specified.…”

Section: Resultssupporting

confidence: 87%

“…The detail distribution of albumins is presented in Table S1 (see supporting information). As mentioned previously, plants also contain albumins; however, those are not phylogenetically related to the animal albumins 39. This fact is consistent with the concept of albumin, which are water soluble, moderately soluble in concentrated salt solutions, not evolutionarily related, and experience heat denaturation 1.…”

Section: Resultssupporting

confidence: 82%

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Genome-Wide Identification and Comparative Analysis of Albumin Family in Vertebrates

Cao

Geng

2017

Evol Bioinform Online

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Albumins are the most well-known globular proteins, and the most typical representatives are the serum albumins. However, less attention was paid to the albumin family, except for the human and bovine serum albumin. To characterize the features of albumin family, we have mined all the putative albumin proteins from the available genome sequences. The results showed that albumin is widely distributed in vertebrates, but not present in the bacteria and archaea. The phylogenetic analysis of vertebrate albumin family implied an evolutionary relationship between members of serum albumin, α-fetoprotein, vitamin D–binding protein, and afamin. Meanwhile, a new member from the albumin family was found, namely, extracellular matrix protein 1. The structural analysis revealed that the motifs for forming the internal disulfide bonds are highly conserved in the albumin family, despite the low overall sequence identity across the family. The domain arrangement of albumin proteins indicated that most of vertebrate albumins contain 3 characteristic domains, arising from 2 evolutionary patterns. And a significant trend has been observed that the albumin proteins in higher vertebrate species tend to possess more characteristic domains. This study has provided the fundamental information required for achieving a better understanding of the albumin distribution, phylogenetic relationship, characteristic motif, structure, and new insights into the evolutionary pattern.

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Section: Resultssupporting

confidence: 87%

Section: Resultssupporting

confidence: 82%

Genome-Wide Identification and Comparative Analysis of Albumin Family in Vertebrates

Cao

Geng

2017

Evol Bioinform Online

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“…Overall, these studies suggest that both the PA1b peptides and cyclotides have evolved for plant defence. A phylogenetic analysis of the albumin-1 genes showed that the ancestral bchain gene encoded for a seed-protecting toxin [59]. The study also showed that the plant tribe Sophorae under the Fabaceae plant family contains the oldest A1b toxin to date, suggesting that the seed-protecting function of albumin-1 b-chain may have already evolved 58 million years ago [59].…”

Section: Albumin-1 Precursorsmentioning

confidence: 93%

“…Why the albumin-1 multigene family radiated extensively in C. ternatea is not known. However, the expansion of albumin-1 genes amongst Fabaceae species is not unprecedented as a study in 2016 showed that, like C. ternatea, the albumin-1 genes in Medicago truncatula also extensively diversified with 52 predicted albumin-1b peptides encoded in its genome [59]. That study showed that, in addition to having a wide tissue distribution of the A1 transcript/peptide, some of its A1b genes did not exhibit insecticidal activity, suggesting functional diversification [59].…”

Section: Albumin-1 Precursorsmentioning

confidence: 99%

“…In contrast to the cyclotide domain and or the PA1b domain of albumin-1 precursors, the role of the a-chain remains uncertain. Multiple sequence alignments have demonstrated that the a-chain is much more conserved than the b-chain, suggesting an important conserved role [59]. In 2012, a plant expression study of albumin-1 precursor genes demonstrated that the linked a-chain is required for the production of b-chain peptides [56].…”

Section: Ternatea Cyclotide Diversitymentioning

confidence: 99%

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Clitoria ternatea (butterfly pea) cyclotides: insights on functional diversity, regulation and biotechnological applications

Oguis¹

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Clitoria ternatea (butterfly pea) is currently the only species in the Fabaceae plant family that is known to produce a suite of small circular peptides called cyclotides that are implicated in plant defence. C. ternatea has been shown to produce upwards of 70 cyclotides. With their ultrastable structures, cyclotides have attracted significant interest for use as scaffolds for the production of peptide-based pharmaceuticals. Similarly, their native insecticidal activity has attracted interest for use in agriculture, resulting in the commercial release of an eco-friendly bio-insecticide (Sero-X ® ) derived from C. ternatea extracts. With the biotechnological potential of C. ternatea evident, this thesis aims to characterise the key gene regulatory factors that guide cyclotide peptide expression levels, diversity, and bioactivity.Chapter 1 of this thesis provides background literature on cyclotides, their biological properties and the potential factors that can regulate their expression. Chapter 2 describes the diversity of cyclotides uncovered in extracts from C. ternatea accessions sourced worldwide. Notable variations in the cyclotide peptide profiles were observed. For instance, some accessions do not produce detectable Cter M, typically observed as the most highly expressed cyclotide in C. ternatea.Genomic and cDNA sequencing of these unique accessions revealed that the CterM precursor genes exhibited missense mutations, presumably leading to the lack of observed Cter M peptide expression.Other cyclotides also varied significantly in relative abundance between accessions which translated to differences in insecticidal properties, with extracts from C. ternatea accessions with the highest cyclotide content being the most potent. Despite the diversity of cyclotides uncovered, the overall genetic diversity of C. ternatea accessions was found to be very similar, as measured using randomly amplified polymorphic DNA marker analysis. This suggests that cyclotides are probably diversifying faster than the background diversification rate.Factors that contribute to the diversity of cyclotide expression were subsequently elucidated in Chapter 3. Using a combination of genome walking and nanopore sequencing, the promoter regions of six cyclotides (CterM, cliotideT1, Cter6, Cter14, Cter16, and cliotideT9) were sequenced and the cis-regulatory elements (CREs) were characterised. Across the six promoters, there was substantial variation in the CREs composition. However, the most abundant CREs identified were shown to associate with seed development and storage, vegetative tissue-related expression, and abiotic and biotic stress response, suggesting these are key regulatory roles for cyclotides in C. ternatea. Further experiments provided evidence for the role of cyclotides in plant defence, with significant upregulation of C. ternatea cyclotide expression detected upon exogenous application of the three defence hormones in plants: jasmonate, ethylene and salicylic acid.iii The differences in cyclotide peptide expression leve...

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Organization and regulation of triterpene saponin biosynthesis in Medicago truncatula

Mertens

Goossens

2019

The Model Legume Medicago Truncatula

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Genome-wide analysis identifies gain and loss/change of function within the small multigenic insecticidal Albumin 1 family of Medicago truncatula

Cited by 16 publications

References 70 publications

Genome-Wide Identification and Comparative Analysis of Albumin Family in Vertebrates

Genome-Wide Identification and Comparative Analysis of Albumin Family in Vertebrates

Clitoria ternatea (butterfly pea) cyclotides: insights on functional diversity, regulation and biotechnological applications

Organization and regulation of triterpene saponin biosynthesis in Medicago truncatula

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