The photosynthetic characteristics of differently shaped leaves in Populus euphratica Olivier

There is a distinct leaf shape polymorphism within a single plant of P. euphratica Olivier. The anatomical structure, carbon isotope discrimination (Δ¹³C), and stomatal and photosynthetic behaviour were investigated in broad-ovate (BOL) and lanceolate (LL) leaves, located at the top and bottom in crown, respectively, of a mature Euphrates poplar growing in its native habitat. Both types of leaves had a non-Kranz anatomy and low Δ¹³C values. However, Δ¹³C of a LL was in average 3.2‰ larger than that of a BOL. In comparison with the LL, the BOL had a smaller stomatal conductance, causing subsequent decreases in transpiration rate and ratio of CO₂ concentrations in intercellular spaces to air. Carbon assimilation rate and water use efficiency were higher in the BOLs than in the LLs. The BOL exhibited C₄-like enzymological features, the activity of glycollate oxidase, and the ratio of activities of ribulose-1,5-bisphosphate carboxylase (RuBPC) to phosphoenolpyruvate carboxylase (PEPC) was lower in BOL than in LL throughout the whole growing season. The lowered ratio of RuBPC/PEPC in BOL was mainly associated with a marked decline in the activity of RuBPC, and only a slight increase in the activity of PEPC. These differences might contribute to microclimate adaptation in both types of leaves. This revised version was published online in June 2006 with corrections to the Cover Date.     

The role of glycine in determining the rate of glutathione synthesis in poplar. Possible implications for glutathione production during stress

The terminal step of glutathione (GSH) synthesis is the condensation of γ-glutamyl-cysteine (γ-EC) with glycine. Relatively little information exists concerning the importance of photorespiratory glycine in determining the rate of conversion of γ-EC to GSH. Consequently, the effect of exogenous glycine and of illumination on foliar contents of γ-EC and GSH was studied in excised leaves and leaf discs from untransformed poplar ( Populus tremula × P. alba ) and poplar overexpressing γ-glutamylcysteine synthetase (γ-ECS; EC 6.3.2.2). Poplars strongly overexpressing γ-ECS (ggs28) had enhanced levels of γ-EC and GSH compared to untransformed poplars. The relationship between γ-EC and GSH contents in ggs28 was light dependent. In illuminated leaves, GSH contents were up to 50-fold higher than γ-EC. On darkening, γ-EC accumulated markedly and GSH declined, so that the GSH:γ-EC ratio was close to 1. These dark-induced changes were prevented by supplying glycine through the petiole or by incubation of leaf discs on glycine. Dark accumulation of γ-EC in leaf discs from untransformed poplar was also prevented by supplying glycine. Supplying cysteine in the dark to discs from untransformed poplar and ggs28 increased γ-EC levels markedly but GSH levels only slightly. Subsequent illumination caused γ-EC to decrease and GSH to increase. Supplying glycine in concert with cysteine had similar effects to illumination. The data suggest that photorespiratory glycine is essential for GSH synthesis, especially under stress conditions, where increased amounts of GSH are required.     

Re-interpretation of Wexfordia hookense from the Upper Devonian of Ireland as an arborescent lycophyte

New collections of pyritized axes of the lycophyte Wexfordia hookense have been made from the Upper Devonian (uppermost Famennian) type locality at Sandeel Bay, County Wexford, in south-eastern Ireland. The specimens reveal additional histological features that permit reinterpretation of the morphology of this taxon and reevaluation of its taxonomic affinities. Wexfordia is shown to possess both secondary xylem, with narrow, uni- to biseriate rays, and periderm. The range of variation in relative amounts of primary and secondary xylem can be correlated with position in the mature plant. This evidence indicates that Wexfordia was a small tree rather than an herbaceous form. Fine structure of tracheids and additional anatomical features strongly support affinities with Carboniferous arborescent Isoetales, rather than Devonian Protolepidodendrales, and further support the hypothesis that radiation in this lineage was well underway prior to the Carboniferous.  © 2004 The Linnean Society of London, Botanical Journal of the Linnean Society , 2004, 144 , 275–287.     

Developing Markets for Certified Wood Products: Greening the Supply Chain for Construction Materials

A growing worldwide movement is seeking to promote the greening of the construction sector. At the design level, proponents of frameworks such as LEED (Leadership in Energy and Environmental Design) seek to motivate designers and building owners to employ environmentally desirable materials. A prominent component of this approach is boosting availability of “green” building materials through programs that will certify to buyers that materials meet environmental standards. For wood products, this has resulted in several forms of “green certification” for forest management. Increasingly large areas of forest are now being certified worldwide. Yet it remains difficult for designers of green buildings, or consumers seeking green furniture, to obtain certified wood products. Many, if not most, of the logs now being harvested on green certified forest land worldwide are not reaching the store shelf with a certified label. Marketing certified wood all the way to the retail shelf has proved to be much harder than initially thought by proponents of certified products. This article explains the sources of these difficulties and outlines an approach to identifying products with high potential for marketing as certified products. Because of complex, multilevel supply chains for many wood products, support is required at all processing and distribution levels for a product to reach the retail customer with its green label. Market participants' purchase size and frequency, basis for product selection, buying influences, and price sensitivity are evaluated to identify product and market approaches likely to increase success rates for certified wood products. The article concludes with recommendations for expanding markets for green building materials.     

A Genomic and Molecular View of Wood Formation

Wood formation is a process derived from plant secondary growth. Different from primary growth, plant secondary growth is derived from cambium meristem cells in the vascular and cork cambia and leads to the girth increase of the plant trunk. In the secondary growth process, plants convert most of photosynthesized products into various biopolymers for use in the formation of woody tissues. This article summarizes the new developments of genomic and genetic characterization of wood formation in herbaceous model plant and tree plant systems. Genomic studies have categorized a collection of the genes for which expression is associated with secondary growth. During wood formation, the expression of many genes is regulated in a stage-specific manner. The function of many genes involved in wood biosyntheses and xylem differentiation has been characterized. Although great progress has been achieved in the molecular and genomic understanding of plant secondary growth in recent years, the profound genetic mechanisms underlying this plant development remain to be investigated. Completion of the first tree genome sequence (Populus genome) provides a valuable genomic resource for characterization of plant secondary growth.     

Woody Debris in the Mangrove Forests of South Florida1

Woody debris is abundant in hurricane‐impacted forests. With a major hurricane affecting South Florida mangroves approximately every 20 yr, carbon storage and nutrient retention may be influenced greatly by woody debris dynamics. In addition, woody debris can influence seedling regeneration in mangrove swamps by trapping propagules and enhancing seedling growth potential. Here, we report on line‐intercept woody debris surveys conducted in mangrove wetlands of South Florida 9–10 yr after the passage of Hurricane Andrew. The total volume of woody debris for all sites combined was estimated at 67 m³/ha and varied from 13 to 181 m³/ha depending upon differences in forest height, proximity to the storm, and maximum estimated wind velocities. Large volumes of woody debris were found in the eyewall region of the hurricane, with a volume of 132 m³/ha and a projected woody debris biomass of approximately 36 t/ha. Approximately half of the woody debris biomass averaged across all sites was associated as small twigs and branches (fine woody debris), since coarse woody debris >7.5 cm felled during Hurricane Andrew was fairly well decomposed. Much of the small debris is likely to be associated with post‐hurricane forest dynamics. Hurricanes are responsible for large amounts of damage to mangrove ecosystems, and components of associated downed wood may provide a relative index of disturbance for mangrove forests. Here, we suggest that a fine:coarse woody debris ratio ≤0.5 is suggestive of a recent disturbance in mangrove wetlands, although additional research is needed to corroborate such findings.