Single primer amplification reaction (SPAR) reveals inter- and intra-specific natural genetic variation in five species of Cymbidium (Orchidaceae)

A total of 53 primers belonging to three SPAR methods, viz. RAPD, ISSR and DAMD, collectively produced 456 polymorphic amplicons with 96.6% polymorphism at inter-specific level in five species of Cymbidium, viz. C. aloifolium, C. mastersii, C. elegans, C. eburneum and C. tigrinum, whereas at intra-specific level, the observed polymorphism ranged from 51.2% to 77.1% among them. Three SPARs collectively revealed 25 unique species-specific amplicons; most of them were amplified with RAPD and DAMD primers besides few bands which were either missed (absent) or lost (heterozygosity). UPGMA clustering evidently distinguished the representatives of C. aloifolium and C. tigrinum, with distinct genetic distance, which may be due to their entirely different habitats as well as discrete morphological characteristics. Upon analysis of the data generated, all the three SPAR methods, either independently and/or in combination, revealed wide range of genetic variation between and within five species of Cymbidium. Comparison of matrix of individual SPAR method revealed that analysis of natural genetic variation using combination of SPAR methods, rather than an isolated approach, is highly effective. The critical analyses of the amplicon data are indicative of DAMD as the most powerful SPAR method by showing highest resolving power (Rp) followed by ISSR and RAPD. Alternatively, the total polymorphic information content was highest in case of RAPD followed by other two SPAR methods. Thus, the present investigation for the first time provides a valuable baseline data for genetic variation at inter- and intra-specific levels in horticultural Cymbidiums and also addresses conservation concerns.     

Structural basis for autoinhibition of ESCRT-III CHMP3

Endosomal sorting complexes required for transport (ESCRT-0, ESCRT-I, ESCRT-II, and ESCRT-III) are selectively recruited to cellular membranes to exert their function in diverse processes, such as multivesicular body biogenesis, enveloped virus budding, and cytokinesis. ESCRT-III is composed of members of the charged multivesicular body protein (CHMP) family—cytosolic proteins that are targeted to membranes via yet unknown signals. Membrane targeting is thought to result in a membrane-associated protein network that presumably acts at a late budding step. Here we provide structural evidence based on small-angle X-ray scattering data that ESCRT-III CHMP3 can adopt two conformations in solution: a closed globular form that most likely represents the cytosolic conformation and an open extended conformation that might represent the activated form of CHMP3. Both the closed and open conformations of CHMP3 interact with AMSH with high affinity. Although the C-terminal region of CHMP3 is required for AMSH interaction, a peptide thereof reveals only weak binding to AMSH, suggesting that other regions of CHMP3 contribute to the high-affinity interaction. Thus, AMSH, including its MIT (microtubule interacting and transport) domain, interacts with ESCRT-III CHMP3 differently from reported Vps4 MIT domain-CHMP protein interactions.     

Detection,characterization and evolutionary aspects of S54LP of SP (SAP54 Like Protein of Sesame Phyllody): a phytoplasma effector molecule associated with phyllody development in sesame ( Sesamum indicum L.)

SAP54, an effector protein secreted by phytoplasmas has been reported to induce phyllody. S54LP of SP (SAP54 Like Protein of Sesame Phyllody), a SAP54 ortholog from phyllody and witches’ broom affected sesame (Sesamum indicum L.) was amplified, cloned and sequenced. Comparative sequence and phylogenetic analysis of diverse phytoplasma strains was carried out to delineate the evolution of S54LP of SP. The degree of polymorphism across SAP54 orthologs and the evolutionary forces acting on this effector protein were ascertained. Site-specific selection across SAP54 orthologs was estimated using Fixed Effects Likelihood (FEL) approach. Nonsynonymous substitutions were detected in the SAP54 orthologs’ sequences from phytoplasmas belonging to same (sub) group. Phylogenetic analysis based on S54LP of SP grouped phytoplasmas belonging to same 16SrDNA (sub) groups into different clusters. Analysis of selection forces acting on SAP54 orthologs from nine different phytoplasma (sub)groups, affecting plant species belonging to twelve different families across ten countries showed the orthologs to be under purifying (negative) selection. One amino acid residue was found to be under pervasive diversifying (positive) selection and a total of three amino acid sites were found to be under pervasive purifying (negative) selection. The location of these amino acids in the signal peptide and mature protein was studied with an aim to understand their role in protein–protein interaction. Asparagine residues (at positions 68 and 84) were found to be under pervasive purifying selection suggesting their functional importance in the effector protein. Our study suggests lack of coevolution between SAP54 and 16SrDNA. Signal peptide appears to evolve at a rate slightly higher than the mature protein. Overall, SAP54 and its orthologs are evolving under purifying selection confirming their functional importance in phytoplasma virulence.     

Long-Term Differential Changes in Mouse Intestinal Metabolomics after γ and Heavy Ion Radiation Exposure

Tissue consequences of radiation exposure are dependent on radiation quality and high linear energy transfer (high-LET) radiation, such as heavy ions in space is known to deposit higher energy in tissues and cause greater damage than low-LET γ radiation. While radiation exposure has been linked to intestinal pathologies, there are very few studies on long-term effects of radiation, fewer involved a therapeutically relevant γ radiation dose, and none explored persistent tissue metabolomic alterations after heavy ion space radiation exposure. Using a metabolomics approach, we report long-term metabolomic markers of radiation injury and perturbation of signaling pathways linked to metabolic alterations in mice after heavy ion or γ radiation exposure. Intestinal tissues (C57BL/6J, female, 6 to 8 wks) were analyzed using ultra performance liquid chromatography coupled with electrospray quadrupole time-of-flight mass spectrometry (UPLC-QToF-MS) two months after 2 Gy γ radiation and results were compared to an equitoxic ⁵⁶Fe (1.6 Gy) radiation dose. The biological relevance of the metabolites was determined using Ingenuity Pathway Analysis, immunoblots, and immunohistochemistry. Metabolic profile analysis showed radiation-type-dependent spatial separation of the groups. Decreased adenine and guanosine and increased inosine and uridine suggested perturbed nucleotide metabolism. While both the radiation types affected amino acid metabolism, the ⁵⁶Fe radiation preferentially altered dipeptide metabolism. Furthermore, ⁵⁶Fe radiation caused upregulation of ‘prostanoid biosynthesis’ and ‘eicosanoid signaling’, which are interlinked events related to cellular inflammation and have implications for nutrient absorption and inflammatory bowel disease during space missions and after radiotherapy. In conclusion, our data showed for the first time that metabolomics can not only be used to distinguish between heavy ion and γ radiation exposures, but also as a radiation-risk assessment tool for intestinal pathologies through identification of biomarkers persisting long after exposure.     

Functional significance of an evolutionarily conserved alanine (GCA) resume codon in tmRNA in Escherichia coli

Occasionally, ribosomes stall on mRNAs prior to the completion of the polypeptide chain. In Escherichia coli and other eubacteria, tmRNA-mediated trans-translation is a major mechanism that recycles the stalled ribosomes. The tmRNA possesses a tRNA-like domain and a short mRNA region encoding a short peptide (ANDENYALAA in E. coli) followed by a termination codon. The first amino acid (Ala) of this peptide encoded by the resume codon (GCN) is highly conserved in tmRNAs in different species. However, reasons for the high evolutionary conservation of the resume codon identity have remained unclear. In this study, we show that changing the E. coli tmRNA resume codon to other efficiently translatable codons retains efficient functioning of the tmRNA. However, when the resume codon was replaced with the low-usage codons, its function was adversely affected. Interestingly, expression of tRNAs decoding the low-usage codon from plasmid-borne gene copies restored efficient utilization of tmRNA. We discuss why in E. coli, the GCA (Ala) is one of the best codons and why all codons in the short mRNA of the tmRNA are decoded by the abundant tRNAs.     

Menthol tolerant clones of Mentha arvensis: approach for in vitro selection of menthol rich genotypes

In vitro raised shoots of Mentha arvensis L. were screened for menthol tolerance level by growing them in media containing 0–100 g ml^–1 menthol. A total of 2850 regenerated shoots were step wise screened for menthol tolerance at the concentrations of 50 g ml^–1 followed by 60 and 70 g ml^–1. In this screening, only 30 individual regenerated shoots were able to survive. The clones from the primary screen were inoculated into rooting medium and, after rooting, transferred to pots in the greenhouse. Ultimately, these 30 menthol tolerant clones were multiplied and grown in the field in replicated plots of 2.5×2.5 m sizes. Twigs of 30 clones from the replicated trials were rechecked for tolerant phenotypes at a concentration of 70 g ml^–1 menthol wherein, these survived even after 7 days (secondary screening). These clones were checked for oil and menthol content and were found to be better than the control plants. Out of these 30 plants, five tolerated 80 g ml^–1 menthol (tertiary level screening) and were found to contain the highest amount of menthol per g leaf biomass. Molecular analysis through RAPD showed distinct variation in the profiles of these five plants, in comparison to the control. Using this method the relationship between the primer OPT 04, menthol tolerance and high menthol content character of the genotype was established. Further, a cultivar `Saksham' was released from the selections by CIMAP for superior performance.     

Carnivorous Plants as a Source of Potent Bioactive Compound: Naphthoquinones

Carnivorous plants are among the curiosities of nature being different from the normal plants in their mode of nutrition. These plants have fascinated several researchers for centuries. They are also characterized by synthesis of bioactive compounds which are used as a mechanism for self defense. These compounds possess a broad spectrum of biological activities such as antiparasitic, antibacterial, insecticidal, fungicidal, anti-inflammatory, antipyretic, antiproliferative activities. Although, several antimicrobial drugs have been introduced during the recent decades, the problems of microbial infections resistant to synthetic pesticides still exist which necessitate the introduction of novel antimicrobial agents with additional modes of actions than the currently available therapeutic agents. Naphthoquinones are one of the most studied bioactive compounds which have been reported to inhibit the growth of proliferative cells and microbes. Efforts have been made to induce the biosynthesis of naphthoquinone in different species of carnivorous plants. It has been demonstrated that the accumulation of naphthoquinones in carnivorous plants was increased by injecting chitin into the plant tissues. Also, their biosynthesis could be enhanced by the incorporation of elicitors in in vitro cultures of plants. In the present review, we discuss the applications of naphthoquinones and its biosynthesis in carnivorous plants.