Structural characterization of dioicin 1 from Phytolacca dioica L. gains novel insights into phylogenetic relationships of Phytolaccaceae type 1 RIPs.

Ribosome-inactivating proteins are plant cytotoxic enzymes, also present in fungi, algae and bacteria, mainly known for their ability to inhibit protein synthesis. We previously purified and structurally characterized three type 1 RIPs (PD-S1-3) from Phytolacca dioica seeds and four type 1 RIPs (PD-L1-4) from adult plant leaves. Two additional RIPs, named dioicin 1 and dioicin 2, were isolated from leaves of young plants and developing leaves of adult plants. The evidence that P. dioica synthesizes and accumulates these RIPs isoforms suggests that these proteins have been conserved during evolution. Though several aspects of P. dioica type 1 RIP characterization have been studied, some important questions remain to be answered especially with respect to Phytolaccaceae RIP evolution. One of the major problems encountered in approaching RIPs phylogeny concerns the availability of their sequences. In this study, we report the characterization of biological and structural properties of dioicin 1, including the determination of its primary structure by using a combined approach based on Edman degradation, de novo sequencing by ESI-Q-TOF-MS/MS and peptide mapping by MALDI-TOF MS. Knowledge of dioicin 1 primary structure provide us a mean to deepen Phytolaccaceae's RIPs phylogeny. We speculate that both dioicins 1 and 2 share common ancestors with PAP-II and PAP icos-II and that dioicin 1 is not closely related to other members of this clade, thus shedding lights on evolutionary relationships among type 1 RIPs from Phytolaccaceae.

Differential expression of saporin genes upon wounding, ABA treatment and leaf development.

Saporins are type 1 ribosome-inactivating proteins (RIPs: EC 3.2.2.22) produced in various organs of Saponaria officinalis L. Two distinct saporin types, saporin-L and saporin-S isoforms, were respectively purified from the intra- and extra-cellular fractions of soapwort leaves. The saporin-L isoform was lowly identical, differed for toxicity, molecular mass and amino acid composition from saporin-S proteins forming a new monophyletic group. Genes encoding both L- and S-type isoforms were cloned from leaf-specific cDNA library; the encoded products included the N-terminal diversity observed by protein sequencing and showed compatible weights with those from mass spectra. These genes were intron-less belonging to small gene families. Reverse transcription polymerase chain reaction/quantitative reverse transcription polymerase chain reaction experiments evidenced their differential expression during leaf development, wounding and abscisic acid treatment. These results suggest that the saporin-L and -S proteins may play diversified roles during stress responses.

Genome-wide survey of the RIP domain family in Oryza sativa and their expression profiles under various abiotic and biotic stresses.

Ribosome-inactivating proteins (RIPs) are N-glycosidases that inhibit protein synthesis by depurinating rRNA. Despite their identification more than 25 years ago, little is known about their biological functions. Here, we report a genome-wide identification of the RIP family in rice based on the complete genome sequence analysis. Our data show that rice genome encodes at least 31 members of this family and they all belong to type 1 RIP genes. This family might have evolved in parallel to species evolution and genome-wide duplications represent the major mechanism for this family expansion. Subsequently, we analyzed their expression under biotic (bacteria and fungus infection), abiotic (cold, drought and salinity) and the phytohormone ABA treatment. These data showed that some members of this family were expressed in various tissues with differentiated expression abundances whereas several members showed no expression under normal growth conditions or various environmental stresses. On the other hand, the expression of many RIP members was regulated by various abiotic and biotic stresses. All these data suggested that specific members of the RIP family in rice might play important roles in biotic and abiotic stress-related biological processes and function as a regulator of various environmental cues and hormone signaling. They may be potentially useful in improving plant tolerance to various abiotic and biotic stresses by over-expressing or suppressing these genes.