The large vascular meristem of poplar trees with its highly organized secondary xylem enables the boundaries between different developmental zones to be easily distinguished. This property of wood-forming tissues allowed us to determine a unique tissuespecific transcript profile for a well defined developmental gradient. RNA was prepared from different developmental stages of xylogenesis for DNA microarray analysis by using a hybrid aspen unigene set consisting of 2,995 expressed sequence tags. The analysis revealed that the genes encoding lignin and cellulose biosynthetic enzymes, as well as a number of transcription factors and other potential regulators of xylogenesis, are under strict developmental stage-specific transcriptional regulation.T ranscript profiling has the potential to reveal transcriptional hierarchy during development for thousands of genes, as well as providing expression data for many genes of unknown function (1, 2). This is especially true when expression patterns can be obtained for well defined tissues at specific developmental stages. However, this is technically demanding and so far there are no reports demonstrating tissue-specific analysis on cell types from a single developmental sequence. We have studied the developing secondary xylem of poplar, which is highly organized with easily recognized and distinct boundaries between the different developmental stages. Wood formation is initiated in the vascular cambium. Cambial derivatives develop into xylem cells through the processes of division, expansion, secondary wall formation, lignification, and finally, programmed cell death. The large physical size of the vascular meristem in trees offers a unique possibility to obtain samples from defined developmental stages by tangential cryo sectioning (3). To determine the steady-state mRNA levels at specific stages during the ontogeny of wood formation in Populus tremula ϫ Populus tremuloides (hybrid aspen) we sampled 30-m-thick sections through the wood development region and subsequently analyzed the samples by using a spotted cDNA-microarray (4) consisting of 2,995 unique ESTs from hybrid aspen. Our study provides a unique global examination of gene expression patterns that encompasses a developmental gradient within a multicellular organism. Materials and MethodsThe Unigene set was selected from the expressed sequence tags (ESTs) presented in ref. 5, using cluster analysis. ESTs were transformed into Escherichia coli by using TSS competent cells (6), plasmids were prepared by using 96-well Multiscreen FB plates (Millipore), inserts were PCR amplified by using vectorspecific primers, and PCR products were purified on Multiscreen PCR filter plates (Millipore) and spotted in duplicate onto CMT GAPS slides (Corning) by using the GMS 417 Arrayer (Affymetrix, Santa Clara, CA) as described (7). All PCR products were checked on ethidium bromide-stained agarose gels. Nine clones giving double PCR bands were excluded from the analysis.A subset of 2,085 of the 2,995 PCR products in the Unigene set...
Plant growth is the result of cell proliferation in meristems, which requires a careful balance between the formation of new tissue and the maintenance of a set of undifferentiated stem cells. Recent studies have provided important information on several genetic networks responsible for stem cell maintenance and regulation of cell differentiation in the apical meristems of shoots and roots. Nothing, however, is known about the regulatory networks in secondary meristems like the vascular cambium of trees. We have made use of the large size and highly regular layered organization of the cambial meristem to create a high-resolution transcriptional map covering 220 mm of the cambial region of aspen (Populus tremula). Clusters of differentially expressed genes revealed substantial differences in the transcriptomes of the six anatomically homogenous cell layers in the meristem zone. Based on transcriptional and anatomical data, we present a model for the position of the stem cells and the proliferating mother cells in the cambial zone. We also provide sets of marker genes for different stages of xylem and phloem differentiation and identify potential regulators of cambial meristem activity. Interestingly, analysis of known regulators of apical meristem development indicates substantial similarity in regulatory networks between primary and secondary meristems.
SummaryThe establishment of the dormant state in meristems involves considerable physiological and metabolic alterations necessary for surviving unfavourable growth conditions. However, a global molecular analysis of dormancy in meristems has been hampered by the difficulty in isolating meristem cells. We used cryosectioning to isolate purified cambial meristem cells from the woody plant Populus tremula during active growth and dormancy. These samples were used to generate meristem-specific cDNA libraries and for cDNA microarray experiments to define the global transcriptional changes underlying cambial dormancy. The results indicate a significant reduction in the complexity of the cambial transcriptome in the dormant state. Although cell division is terminated in the dormant cambium, the cell cycle machinery appears to be maintained in a skeletal state as suggested by the continued presence of transcripts for several cell cycle regulators. The downregulation of PttPIN1 and PttPIN2 transcripts explains the reduced basipetal polar auxin transport during dormancy. The induction of a member of the SINA family of ubiquitin ligases implicated in auxin signalling indicates a potential mechanism for modulation of auxin sensitivity during cambial dormancy. The metabolic alterations during dormancy are mirrored in the induction of genes involved in starch breakdown and the glyoxysomal cycle. Interestingly, the induction of RGA1 like gene suggests modification of gibberellin signalling in cambial dormancy. The induction of genes such as poplar orthologues of FIE and HAP2 indicates a potential role for these global regulators of transcription in orchestrating extensive changes in gene expression during dormancy.
The plant hormone ethylene is an important signal in plant growth responses to environmental cues. In vegetative growth, ethylene is generally considered as a regulator of cell expansion, but a role in the control of meristem growth has also been suggested based on pharmacological experiments and ethylene-overproducing mutants. In this study, we used transgenic ethylene-insensitive and ethylene-overproducing hybrid aspen (Populus tremula ؋ tremuloides) in combination with experiments using an ethylene perception inhibitor [1-methylcyclopropene (1-MCP)] to demonstrate that endogenous ethylene produced in response to leaning stimulates cell division in the cambial meristem. This ethylenecontrolled growth gives rise to the eccentricity of Populus stems that is formed in association with tension wood.plant hormones ͉ secondary xylem ͉ tension wood ͉ vascular cambium ͉ wood development T he vascular cambium is the meristem that produces secondary xylem and phloem by periclinal cell divisions, and it is responsible for wood production and stem diameter growth in trees. Cambial growth rate along the trunk is correlated with leaf biomass and crown structure (1). Superimposed on this intrinsic control, cambial growth is also strongly influenced by environment, where mechanical and gravitational loads imposed by wind and leaning are important (2). Wind sway induces increased diameter growth that protects against stem breakage (3), whereas a static lean results in a localized growth response known as tension wood (TW) in dicotyledonous angiosperms. TW is formed on the upper side of the leaning stem, resulting in characteristic asymmetric growth, and it serves to correct the stem position (4). In addition to the striking increase in cambial cell divisions, TW has an altered anatomy, and the fibers form an additional inner, cellulose-rich, gelatinous secondary cell wall layer (G layer) (5).Experiments with ethylene applications have revealed that this volatile plant hormone has the potential to both inhibit and stimulate growth (6). Its synthesis from S-adenosylmethionine through the action of 1-aminocyclopropane-1-carboxylate (ACC) synthase (ACS) and ACC oxidase (ACO) is triggered in vegetative tissues in response to many environmental cues. To date, concepts of ethylene function in vegetative growth have mainly implicated its role in primary tissue and cell expansion (6). However, ethylene biosynthesis increases during TW formation because of an asymmetric induction of ACO (7,8), and application of ethylene has been shown to stimulate cambial growth both in trees and herbaceous species (9, 10). Additional observations also support a potential role for ethylene in cell division. Applied ethylene stimulated endoreduplication in cucumber hypocotyls and growth of the intercalary meristem in deepwater rice (11-13). Moreover, the ethylene-overproducing Arabidopsis mutant eto1 exhibits aberrant cell divisions in the quiescent center of the root (14). However, experiments where ethylene homeostasis is artificially manipulated by a...
Breeding progress and preparedness for mass‐scale deployment of perennial lignocellulosic biomass crops switchgrass, miscanthus, willow and poplar
Genetic improvement through breeding is one of the key approaches to increasing biomass supply. This paper documents the breeding progress to date for four perennial biomass crops (PBCs) that have high output–input energy ratios: namely Panicum virgatum (switchgrass), species of the genera Miscanthus (miscanthus), Salix (willow) and Populus (poplar). For each crop, we report on the size of germplasm collections, the efforts to date to phenotype and genotype, the diversity available for breeding and on the scale of breeding work as indicated by number of attempted crosses. We also report on the development of faster and more precise breeding using molecular breeding techniques. Poplar is the model tree for genetic studies and is furthest ahead in terms of biological knowledge and genetic resources. Linkage maps, transgenesis and genome editing methods are now being used in commercially focused poplar breeding. These are in development in switchgrass, miscanthus and willow generating large genetic and phenotypic data sets requiring concomitant efforts in informatics to create summaries that can be accessed and used by practical breeders. Cultivars of switchgrass and miscanthus can be seed‐based synthetic populations, semihybrids or clones. Willow and poplar cultivars are commercially deployed as clones. At local and regional level, the most advanced cultivars in each crop are at technology readiness levels which could be scaled to planting rates of thousands of hectares per year in about 5 years with existing commercial developers. Investment in further development of better cultivars is subject to current market failure and the long breeding cycles. We conclude that sustained public investment in breeding plays a key role in delivering future mass‐scale deployment of PBCs.
Selectable markers enable transgenic plants or cells to be identified
Forests are vital to the world's ecological, social, cultural and economic well-being yet sustainable provision of goods and services from forests is increasingly challenged by pressures such as growing demand for wood and other forest products, land conversion and degradation, and climate change. Intensively managed, highly productive forestry incorporating the most advanced methods for tree breeding, including the application of genetic engineering (GE), has tremendous potential for producing more wood on less land. However, the deployment of GE trees in plantation forests is a controversial topic and concerns have been particularly expressed about potential harms to the environment. This paper, prepared by an international group of experts in silviculture, forest tree breeding, forest biotechnology and environmental risk assessment (ERA) that met in April 2012, examines how the ERA paradigm used for GE crop plants may be applied to GE trees for use in plantation forests. It emphasizes the importance of differentiating between ERA for confined field trials of GE trees, and ERA for unconfined or commercial-scale releases. In the case of the latter, particular attention is paid to characteristics of forest trees that distinguish them from shorter-lived plant species, the temporal and spatial scale of forests, and the biodiversity of the plantation forest as a receiving environment.
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