The relative impact of parental and current environment on plant transcriptomes depends on type of stress and genotype.

Through developmental plasticity, an individual organism integrates influences from its immediate environment with those due to the environment of its parents. While both effects on phenotypes are well documented, their relative impact has been little studied in natural systems, especially at the level of gene expression. We examined this issue in four genotypes of the annual plant Persicaria maculosa by varying two key resources-light and soil moisture-in both generations. Transcriptomic analyses showed that the relative effects of parent and offspring environment on gene expression (i.e. the number of differentially expressed transcripts, DETs) varied both for the two types of resource stress and among genotypes. For light, immediate environment induced more DETs than parental environment for all genotypes, although the precise proportion of parental versus immediate DETs varied among genotypes. By contrast, the relative effect of soil moisture varied dramatically among genotypes, from 8-fold more DETs due to parental than immediate conditions to 10-fold fewer. These findings provide evidence at the transcriptomic level that the relative impacts of parental and immediate environment on the developing organism may depend on the environmental factor and vary strongly among genotypes, providing potential for the interplay of these developmental influences to evolve.

Perioperative care for internationally adopted children: Medical, surgical, and psychosocial considerations for a population of concern.

The overall number of international adoptions has dropped in the last 20 years, but a relative increase in the proportion of these children with special and surgical needs has occurred. Cleft lip/palate and anorectal malformations are two common surgical pathologies for internationally adopted children. Internationally adopted children with cleft lip/palate have high rates of speech impairment and frequent need for reoperation, and children with anorectal malformation commonly need multiple reoperations. For both groups, surgery prior to adoption may have actually contributed to morbidity. Both speech impairment and anorectal malformation negatively affect quality of life, independent of adoption. Additionally, internationally adopted children frequently have experienced trauma, single or complex, and institutionalization. Each of these can independently contribute to impaired psychosocial and behavioral development. These children face surgery, sometimes multiple surgeries, while adapting to a new culture, learning a new language, and bonding with a new family. The impact of prior medical experiences without the presence of a caregiver and/or while institutionalized is understudied. The surgical experience and perioperative outcomes within this population warrant research, and clinical coordination between teams may help improve care for this uniquely vulnerable population.

Genomics Analysis of L-DOPA Exposure in Drosophila sechellia.

Drosophila sechellia is a dietary specialist fruit fly that evolved from a generalist ancestor to specialize on the toxic fruit of Morinda citrifolia This species pair has been the subject of numerous studies where the goal has largely been to determine the genetic basis of adaptations associated with host specialization. Because one of the most striking features of M. citrifolia fruit is the production of toxic volatile compounds that kill insects, most genomic studies in D. sechellia to date have focused on gene expression responses to the toxic compounds in its food. In this study, we aim to identify new genes important for host specialization by profiling gene expression response to 3,4-dihydroxyphenylalanine (L-DOPA). Recent work found it to be highly abundant in M. citrifolia, critical for reproductive success of D. sechellia, and supplementation of diet with the downstream pathway product dopamine can influence toxin resistance phenotypes in related species. Here we used a combination of functional genetics and genomics techniques to identify new genes that are important for D. sechellia ecological adaptation to this new niche. We show that L-DOPA exposure can affect toxin resistance phenotypes, identify genes with plastic responses to L-DOPA exposure, and functionally test an identified candidate gene. We found that knock-down of Esterase 6 (Est6) in a heterologous species alters toxin resistance suggesting Est6 may play an important role in D. sechellia host specialization.