We present the 1.06 Gb sequenced genome of Gastrodia elata, an obligate mycoheterotrophic plant, which contains 18,969 protein-coding genes. Many genes conserved in other plant species have been deleted from the G. elata genome, including most of those for photosynthesis. Additional evidence of the influence of genome plasticity in the adaptation of this mycoheterotrophic lifestyle is evident in the large number of gene families that are expanded in G. elata, including glycoside hydrolases and urease that likely facilitate the digestion of hyphae are expanded, as are genes associated with strigolactone signaling, and ATPases that may contribute to the atypical energy metabolism. We also find that the plastid genome of G. elata is markedly smaller than that of green plant species while its mitochondrial genome is one of the largest observed to date. Our report establishes a foundation for studying adaptation to a mycoheterotrophic lifestyle.
Summary
Human health is dependent upon environmental exposures, yet the diversity and variation in exposures is poorly understood. We developed a sensitive method to monitor personal airborne biological and chemical exposures and followed the personal exposomes of 15 individuals for up to 890 days and over 66 distinct geographical locations. We found that individuals are potentially exposed to thousands of pan-domain species and chemical compounds, including insecticides and carcinogens. Personal biological and chemical exposomes are highly dynamic and vary spatial-temporally, even for individuals located in the same general geographical region. Integrated analysis of biological and chemical exposomes revealed strong location-dependent relationships. Finally, construction of an exposome interaction network demonstrated the presence of distinct yet interconnected human- and environment-centric clouds, comprised of interacting ecosystems such as human, flora, pets and arthropods. Overall, we demonstrate that human exposomes are diverse, dynamic, spatiotemporally-driven interaction networks with the potential to impact human health.
An outbreak of Streptococcus suis serotype 2 emerged in the summer of 2005 in Sichuan Province, and sporadic infections occurred in 4 additional provinces of China. In total, 99 S. suis strains were isolated and analyzed in this study: 88 isolates from human patients and 11 from diseased pigs. We defined 98 of 99 isolates as pulse type I by using pulsed-field gel electrophoresis analysis of SmaI-digested chromosomal DNA. Furthermore, multilocus sequence typing classified 97 of 98 members of the pulse type I in the same sequence type (ST), ST-7. Isolates of ST-7 were more toxic to peripheral blood mononuclear cells than ST-1 strains. S. suis ST-7, the causative agent, was a single-locus variant of ST-1 with increased virulence. These findings strongly suggest that ST-7 is an emerging, highly virulent S. suis clone that caused the largest S. suis outbreak ever described.
C-glycosyltransferases (CGTs) are important enzymes that are responsible for the synthesis of the C-glycosides of flavonoids and isoflavonoids. Flavonoid CGTs have been molecularly characterized from several plant species; however, to date, no gene encoding an isoflavonoid CGT has been reported from any plant species. A significant example of an isoflavonoid C-glycoside is puerarin, a compound that contributes to the major medicinal effects of Pueraria lobata. Little is known about the C-glucosylation that occurs during puerarin biosynthesis. One possible route for puerarin synthesis is via the C-glucosylation of daidzein. This study describes the molecular cloning and functional characterization of a novel glucosyltransferase (PlUGT43) from P. lobata. Biochemical analyses revealed that PlUGT43 possesses an activity for the C-glucosylation of daidzein to puerarin; it shows activity with the isoflavones daidzein and genistein, but displays no activity towards other potential acceptors, including flavonoids. To validate the in vivo function of PlUGT43, the PlUGT43 gene was over-expressed in soybean hairy roots that naturally synthesize daidzein but that do not produce puerarin. The expression of PlUGT43 led to the production of puerarin in the transgenic soybean hairy roots, confirming a role for PlUGT43 in puerarin biosynthesis.
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