Pollination: Multimodal signaling in a co-dependent thermogenic gymnosperm system.

Plant-pollinator interaction research commonly focuses on more apparent traits, floral morphology and odor. A new study of a thermogenic gymnosperm brood-site pollination system via a specialist beetle reveals intricate long- and short-range multimodal signals are involved in host finding.

Phylogenomics and the evolution of hemipteroid insects.

Hemipteroid insects (Paraneoptera), with over 10% of all known insect diversity, are a major component of terrestrial and aquatic ecosystems. Previous phylogenetic analyses have not consistently resolved the relationships among major hemipteroid lineages. We provide maximum likelihood-based phylogenomic analyses of a taxonomically comprehensive dataset comprising sequences of 2,395 single-copy, protein-coding genes for 193 samples of hemipteroid insects and outgroups. These analyses yield a well-supported phylogeny for hemipteroid insects. Monophyly of each of the three hemipteroid orders (Psocodea, Thysanoptera, and Hemiptera) is strongly supported, as are most relationships among suborders and families. Thysanoptera (thrips) is strongly supported as sister to Hemiptera. However, as in a recent large-scale analysis sampling all insect orders, trees from our data matrices support Psocodea (bark lice and parasitic lice) as the sister group to the holometabolous insects (those with complete metamorphosis). In contrast, four-cluster likelihood mapping of these data does not support this result. A molecular dating analysis using 23 fossil calibration points suggests hemipteroid insects began diversifying before the Carboniferous, over 365 million years ago. We also explore implications for understanding the timing of diversification, the evolution of morphological traits, and the evolution of mitochondrial genome organization. These results provide a phylogenetic framework for future studies of the group.

Odor-mediated push-pull pollination in cycads.

The reproductive organs of some plants self-heat, release scent, and attract pollinators. The relations among these processes are not well understood, especially in the more ancient, nonflowering gymnosperm lineages. We describe the influence of plant volatiles in an obligate pollination mutualism between an Australian Macrozamia cycad (a gymnosperm with male and female individuals) and its specialist thrips pollinator, Cycadothrips chadwicki. Pollen-laden thrips leave male cycad cones en masse during the daily thermogenic phase, when cone temperatures and volatile emissions increase dramatically and thrips are repelled. As thermogenesis declines, total volatile emissions diminish and cones attract thrips, resulting in pollination of female cones. Behavioral and electrophysiological tests on thrips reveal that variations in b-myrcene and ocimene emissions by male and female cones are sufficient to explain the observed sequential thrips' repellence (push) and attraction (pull). These dynamic interactions represent complex adaptations that enhance the likelihood of pollination and may reflect an intermediate state in the evolution of biotic pollination.

Experimental evaluation and thermo-physical analysis of thermogenesis in male and female cycad cones.

Thermogenically elevated cone temperatures were measured in two Macrozamia cycad species that differ in their daily heating time. Mathematical models of the cones' thermo-physics were tested for their accuracy in predicting these cone temperatures and for comparison of the energetics of both species and the sexes within species. These models accurately predicted temperatures over approximately 8-h periods with average errors of: 0.46 degrees C for Macrozamia lucida, pollinated by the thrips, Cycadothrips chadwicki, that moves during mid-day concurrent with cone heating; and 0.38 degrees C for Macrozamia machinii, pollinated by the weevil, Tranes sp., that moves after sunset during cone heating. The combination of models and experiments revealed a thermogenic sexual dimorphism in both species. For M. lucida, the estimated female mass specific metabolisms, and their theoretically possible and actual temperature increases due to thermogenic metabolism were only 57, 67, and 76% of males. In addition, female thermogenic metabolisms began and peaked much earlier and lasted significantly longer than males (all differences >1 h), and female metabolic peaks preceded their temperature peaks by 65 vs. 46 min for males. The timing of almost all male cone metabolic peaks was optimized with respect to the diurnal ambient heating cycle so that cone temperatures achieved a maximum temperature gain, whereas most female metabolic peaks occurred much earlier than optimal. In M. machinii, thermogenic sexual dimorphism is much larger since its male peak metabolisms are larger, and its females' peaks are much smaller compared to those of M. lucida. This study provides new information regarding the energetics of cycad cones that is relevant to understanding the interactions of the plant traits with their obligate pollinators' behavior.