Differential Expression of Two Distinct Phenylalanine Ammonia-Lyase Genes in Condensed Tannin-Accumulating and Lignifying Cells of Quaking Aspen

Lignins, along with condensed tannins (CTs) and salicylate-derived phenolic glycosides, constitute potentially large phenylpropanoid carbon sinks in tissues of quaking aspen (Populus tremuloides Michx.). Metabolic commitment to each of these sinks varies during development and adaptation, and depends on l-phenylalanine ammonia-lyase (PAL), an enzyme catalyzing the deamination of l-phenylalanine to initiate phenylpropanoid metabolism. In Populus spp., PAL is encoded by multiple genes whose expression has been associated with lignification in primary and secondary tissues. We now report cloning two differentially expressed PAL cDNAs that exhibit distinct spatial associations with CT and lignin biosynthesis in developing shoot and root tissues of aspen. PtPAL1 was expressed in certain CT-accumulating, non-lignifying cells of stems, leaves, and roots, and the pattern of PtPAL1 expression varied coordinately with that of CT accumulation along the primary to secondary growth transition in stems. PtPAL2 was expressed in heavily lignified structural cells of shoots, but was also expressed in non-lignifying cells of root tips. Evidence of a role for Pt4CL2, encoding 4-coumarate:coenzyme A ligase, in determining CT sink strength was gained from cellular co-expression analysis with PAL1 and CTs, and from experiments in which leaf wounding increased PAL1 and 4CL2 expression as well as the relative allocation of carbon to CT with respect to phenolic glycoside, the dominant phenolic sink in aspen leaves. Leaf wounding also increased PAL2 and lignin pathway gene expression, but to a smaller extent. The absence of PAL2 in most CT-accumulating cells provides in situ support for the idea that PAL isoforms function in specific metabolic milieus

The enactment of risk categories: the role of information systems in organizing and re-organizing risk management practices in the energy industry

This research explores the role of information systems in risk management during a twenty year period when new governance arrangements led to enterprise-wide change in the UK energy markets. We present a longitudinal case study documenting the role of "A-Trade" transaction and risk management software in the adaptation of energy organizations to competitive demands associated with a simultaneous process of privatization and liberalization. During the design, development and implementation of A-Trade, multiple forms of expertise were brought together in what we describe as organizational encounters with risk. The story of "A-Trade" highlights the shift from a traditional engineer-led culture of risk cognition to marketoriented financial risk management. Our findings are that, firstly, that energy transaction and risk management software development provided an important learning ground during periods of paradigmatic change. Secondly, we provide insights into the enactment of risk categories and the challenges associated with establishing an information infrastructure to support risk management

Regulation of carotenoid biosynthesis in photosynthetic organs

A substantial proportion of the dazzling diversity of colors displayed by living organisms throughout the tree of life is determined by the presence of carotenoids, which most often provide distinctive yellow, orange and red hues. These metabolites play fundamental roles in nature that extend far beyond their importance as pigments. In photosynthetic lineages, carotenoids are essential to sustain life, since they have been exploited to maximize light harvesting and protect the photosynthetic machinery from photooxidative stress. Consequently, photosynthetic organisms have evolved several mechanisms that adjust the carotenoid metabolism to efficiently cope with constantly fluctuating light environments. This chapter will focus on the current knowledge concerning the regulation of the carotenoid biosynthetic pathway in leaves, which are the primary photosynthetic organs of most land plants.My research is mainly funded by the EC Marie Curie research project CarotenActors (FP7-PEOPLE-2011-IIF 300862) and the MINECO Postdoctoral Grant (FPDI-2013-018882). I also acknowledge the support from grants from MINECO (BIO2011-23680) and CYTED (Ibercarot-112RT0445).Peer reviewe

Asynchronous Circuit Synthesis by Direct Mapping: Interfacing to Environment

info:eu-repo/semantics/publishe