Vegetative rescue potential of Brazil nut through epicormic shoots on detached branches

Obtaining juvenile material may favor the clonal propagation of Brazil nut, Bertholletia excelsa. We aimed to assess the emission of epicormic shoots on detached branches of Brazil nut trees as a function of the mother tree and branch diameter, in order to provide juvenile material for use in clonal multiplication. The experimental design was completely randomized in a 6 (mother trees) x 3 (stem diameter: < 20 20-40 and 40-80 mm) factorial design, with four replicates. Every five days the number of shoots emitted was counted and the sprouting speed index and average sprouting time were calculated. The number of epicormic shoots and the sprouting speed index were dependent on the interaction between mother tree and branch diameter. Branches with larger diameter (20-40 and 40-80 mm) showed higher potential for obtaining propagules for use in Brazil nut clonal multiplication (cutting, grafting and in vitro cultivation). (AU)

An advanced protocol for the establishment of plantlets originating from somatic embryos in Pinus massoniana.

This study describes critical factors affecting germination of somatic embryos and plantlet regeneration in Pinus massoniana. Somatic embryos from the same embryogenic line 27 of P. massoniana were used as test materials. The supplementation of activated charcoal (AC) in the medium was essential for the germination of mature somatic embryos, while the addition of excessive AC to the medium was prohibitive for somatic embryo germination. The highest germination rate was found on the medium containing 10 g/l AC, and the addition of 5 g/l AC to the medium was optimal to the growth of germinating somatic embryos. Thidiazuron (TDZ) was linearly related to the number of sprouting axillary buds. However, the growth of sprouting buds was retarded when > 4 µmol/l TDZ was added into culture medium. Exogenous plant growth regulators added to the medium significantly improved the root regeneration capacity of shoots. The highest root regeneration rate was observed under the treatment of 1.2 µmol/l ɑ-naphthaleneacetic acid (NAA) plus 2 µmol/l paclobutrazol (PBZ), reaching 96.3%. One year after the field transfer, the growth performance of plant height, caliper, and survival rate for rooted shoots was significantly better than that of plantlets directly developed via somatic embryogenesis. The presented results provide useful instruction for the establishment of plantlets originating from somatic embryos, and would be able to make a great contribution to the clonal forestry of P. massoniana.

Genotype-by-environment interaction in coast redwood outside natural distribution - search for environmental cues.

BACKGROUND: Effective matching of genotypes and environments is required for the species to reach optimal productivity and act effectively for carbon sequestration. A common garden experiment across five different environments was undertaken to assess genotype x environment interaction (GxE) of coast redwood in order to understand the performance of genotypes across environments. RESULTS: The quantitative genetic analysis discovered no GxE between investigated environments for diameter at breast height (DBH). However, no genetic component was detected at one environment possibly due to stressful conditions. The implementation of universal response function allowed for the identification of important environmental factors affecting species productivity. Additionally, this approach enabled us to predict the performance of species across the New Zealand environmental conditions. CONCLUSIONS: In combination with quantitative genetic analysis which identified genetically superior material, the URF model can directly identify the optimal geographical regions to maximize productivity. However, the finding of ideally uncorrelated climatic variables for species with narrow ecological amplitude is rather challenging, which complicates construction of informative URF model. This, along with a small number of tested environments, tended to overfit a prediction model which resulted in extreme predictions in untested environments.

Rooting of eucalypt cuttings as a problem-solving oriented model in plant biology.

Species of Eucalyptus are some of the most planted trees in the world, providing fiber, cellulose, energy, and wood for construction and furniture in renewable fashion, with the added advantage of fixing large amounts of atmospheric carbon. The efficiency of eucalypts in forestry relies mostly on the clonal propagation of selected genotypes both as pure species and interspecific hybrids. The formation of new roots from cambium tissues at the base of cuttings, referred to as adventitious rooting (AR), is essential for accomplishing clonal propagation successfully. AR is a highly complex, multi-level regulated developmental process, affected by a number of endogenous and environmental factors. In several cases, highly desirable genotypes from an industrial point of view carry along the undesirable trait of difficulty-to-root (recalcitrance). Understanding the bases of this phenotype is needed to identify ways to overcome recalcitrance and allow efficient clonal propagation. Herein, an overview of the state-of-the-art on the basis of AR recalcitrance in eucalypts addressed at various levels of regulation (transcript, protein, metabolite and phenotype), and OMICs techniques is presented. In addition, a focus is also provided on the gaps that need to be filled in order to advance in this strategic biological problem for global forestry industry relying on eucalypts.