Medicago truncatula-derived calcium oxalate crystals have a negative impact on chewing insect performance via their physical properties

Plant structural traits often act as defenses against herbivorous insects, causing them to avoid feeding on a given plant or tissue. Mineral crystals of calcium oxalate in Medicago truncatula Gaertn. (Fabaceae) leaves have previously been shown to be effective deterrents of lepidopteran insect feeding. They are also inhibitors of conversion of plant material into insect body mass during or after consumption. Growth of beet armyworm, Spodoptera exigua Hübner (Lepidoptera: Noctuidae), larvae was correspondingly greater on calcium oxalate‐defective (cod) mutants of M. truncatula with lower levels of crystal accumulation. Data presented here show that insects feeding on M. truncatula leaves with calcium oxalate crystals experience greater negative effects on growth and mandible wear than those feeding on artificial diet amended with smaller amorphous crystals from commercial preparations. Commercial calcium oxalate can be added to insect artificial diet at levels up to 7.5‐fold higher than levels found in wild‐type M. truncatula leaves with minimal effect on insect growth or lepidopteran mandibles. These data suggest that negative impacts of calcium oxalate in the diet of larvae are due to physical factors, and not toxicity of the compound, as high levels of the commercial crystals are readily tolerated. In contrast to the dramatic physical effects that M. truncatula‐derived crystals have on insect mandibles, we could detect no damage to insect peritrophic gut membranes due to consumption of these crystals. Taken together, the data indicate that the size and shape of prismatic M. truncatula oxalate crystals are important factors in determining effects on insect growth. If manipulation of calcium oxalate is to be used in developing improved insect resistance in plants, then our findings suggest that controlling not only the overall amount, but also the size and shape of crystals, could be valuable traits in selecting desirable plant lines.     

Medicago truncatula mutants demonstrate the role of plant calcium oxalate crystals as an effective defense against chewing insects

Calcium oxalate is the most abundant insoluble mineral found in plants and its crystals have been reported in more than 200 plant families. In the barrel medic Medicago truncatula Gaertn., these crystals accumulate predominantly in a sheath surrounding secondary veins of leaves. Mutants of M. truncatula with decreased levels of calcium oxalate crystals were used to assess the defensive role of this mineral against insects. Caterpillar larvae of the beet armyworm Spodoptera exigua Hübner show a clear feeding preference for tissue from calcium oxalate-defective (cod) mutant lines cod5 and cod6 in choice test comparisons with wild-type M. truncatula. Compared to their performance on mutant lines, larvae feeding on wild-type plants with abundant calcium oxalate crystals suffer significantly reduced growth and increased mortality. Induction of wound-responsive genes appears to be normal in cod5 and cod6, indicating that these lines are not deficient in induced insect defenses. Electron micrographs of insect mouthparts indicate that the prismatic crystals in M. truncatula leaves act as physical abrasives during feeding. Food utilization measurements show that, after consumption, calcium oxalate also interferes with the conversion of plant material into insect biomass during digestion. In contrast to their detrimental effects on a chewing insect, calcium oxalate crystals do not negatively affect the performance of the pea aphid Acyrthosiphon pisum Harris, a sap-feeding insect with piercing-sucking mouthparts. The results confirm a long-held hypothesis for the defensive function of these crystals and point to the potential value of genes controlling crystal formation and localization in crop plants.     

Single nucleotide polymorphism-mismatch primer development for rapid molecular identification of selected microalgal species

Microalgae have been a great source for food, cosmetic, pharmacological, and biofuel production. The adoption of effective diagnostic assays for monitoring all stages of algal cultivation has become essential. In addition to microscopy identification, molecular assays can aid greatly in the identification and monitoring of algal species of interest. In this study the 18S ribosomal RNA (rRNA) sequences of 12 microalgal species and/or strains were used to design algal identification primers. Sequence alignment revealed five highly variable regions and multiple unique single nucleotide polymorphisms (SNPs). To design target algae specific primers, a SNP identified as unique to each microalgal species was incorporated into the 3’-terminus of forward and reverse primer pairs, respectively. To further enhance primer specificity, transverse mutation was introduced into each primer at the third base upstream of the respective SNP. The SNP-mismatch primer pairs yield size-specific amplicons, enabling the rapid molecular detection of 12 microalgae by circumventing cloning and sequencing. To verify the primer specificity, two SNP-mismatch primer pairs designed for Chlorella sorokiniana DOE1412 and wildtype species of Scenedesmus were tested in the outdoor reactor run inoculated with C. sorokiniana DOE1412. The primer pairs were able to identify C. sorokiniana DOE1412 as well as the environmental invader Scenedesmus sp. Furthermore, the “relative concentration” of two microalgae was accessed throughout the entire cultivation run. The use of SNPs primers designed in this study offers a cost-effective, easy to use alternative for routine monitoring of microalgal cultures in laboratories, in scale-ups, and in cultivation reactors, independent of the production platform.