Critério técnico para determinação da idade ótima de mudas de eucalipto para plantio Technical criterion for the determination of the optimum age of eucalypt cuttings for planting

Atualmente, a produção de mudas de Eucalyptus, em larga escala, é realizada pela miniestaquia, sob condições controladas. Todavia, ainda hoje não existe um critério técnico para determinar a idade ótima das mudas para plantio, o que pode refletir negativamente sobre a qualidade, sobretudo do sistema radicular, e, conseqüentemente, grandes perdas podem ocorrer no campo. Assim, o presente trabalho estabeleceu um critério técnico com base nas curvas de velocidade de crescimento e no intercepto entre as curvas de incremento corrente diário e incremento médio diário das variáveis altura, biomassa radicular e da parte aérea. Em virtude da restrição de volume explorável pelo sistema radicular, constataram-se reduções significativas na velocidade de crescimento das mudas que devem ser plantadas, preferencialmente, com 80 (clone A) a 100 (clone B) dias de idade, uma vez que mudas mais velhas sofrem redução na velocidade de crescimento e tendem a desenvolver problemas de malformação radicular. As implicações da baixa qualidade do sistema radicular residem na mortalidade de plantas, principalmente em períodos menos favoráveis, e na conseqüente influência na operação de replantio, bem como na realização dos testes clonais e na maior suscetibilidade das plantas aos estresses do ambiente.<br>Presently, mass vegetative propagation of Eucalyptus is carried out by mini-cuttings, under controlled conditions. Despite the advances of this technique, there is no criterion to determine the optimum age of the cuttings for planting, which can reflect negatively on the quality, mainly on the root system, and consequently losses may occur in the field. Hence, in the present work was established a technical criteria based on the growth speed curves and intercrossing of daily current increasing curves and daily average increasing for the variables height, root, stem and shoot biomass. Due to the restriction of exploitable volume by the root system, significant reductions in the growth speed of cuttings were found, and they must be planted preferentially from 80 (clone A) to 100 (Clone B) days of age, once older cuttings undergo a reduction in the growth speed and tend to develop root malformation problems. The implications of the low quality of the root system are the mortality of plants in the field, mainly in less favorable periods, and the consequent influence on the replanting operation, as well as on the clonal tests and a greater susceptibility of plants to environment stresses

Mapping species differences for adventitious rooting in a Corymbia torelliana x Corymbia citriodora subspecies variegata hybrid

Quantitative trait loci (QTL) detection was carried out for adventitious rooting and associated propagation traits in a second-generation outbred Corymbia torelliana x Corymbia citriodora subspecies variegata hybrid family (n=186). The parental species of this cross are divergent in their capacity to develop roots adventitiously on stem cuttings and their propensity to form lignotubers. For the ten traits studied, there was one or two QTL detected, with some QTL explaining large amounts of phenotypic variation (e.g. 66% for one QTL for percentage rooting), suggesting that major effects influence rooting in this cross. Collocation of QTL for many strongly genetically correlated rooting traits to a single region on linkage group 12 suggested pleiotropy. A three locus model was most parsimonious for linkage group 12, however, as differences in QTL position and lower genetic correlations suggested separate loci for each of the traits of shoot production and root initiation. Species differences were thought to be the major source of phenotypic variation for some rooting rate and root quality traits because of the major QTL effects and up to 59-fold larger homospecific deviations (attributed to species differences) relative to heterospecific deviations (attributed to standing variation within species) evident at some QTL for these traits. A large homospecific/heterospecific ratio at major QTL suggested that the gene action evident in one cross may be indicative of gene action more broadly in hybrids between these species for some traits

Progress in Myrtacease genetics and genomics: Eucalyptus as the pivotal genus

The status of genomics and genetics research in the Myrtaceae, a large family of dicotyledonous woody plants, is reviewed with Eucalyptus as the focal genus. The family contains over 5,650 species in 130 to 150 genera, predominantly of neo-tropical and Southern Hemisphere distribution. Several genera are well known for their economic importance worldwide. Myrtaceae are typically diploids with small to intermediate genome size. Microsatellites have been developed for several genera while higher throughput marker systems such as diversity arrays technology and single nucleotide polymorphism are available for Eucalyptus. Molecular data have been fundamental to current perspectives on the phylogeny, phylogeography and taxonomy of the Myrtaceae, while numerous studies of genetic diversity have been carried out particularly as it relates to endangered, rare, fragmented, overharvested or economically important species. Large expressed sequence tag collections for species of Eucalyptus have recently become public to support the annotation of the Eucalyptus grandis genome. Transcriptomics in Eucalyptus has advanced by microarrays and next-generation sequencing focusing on wood development. Linkage maps for Eucalyptus display high synteny across species and have been extensively used to map quantitative trait loci for a number of traits including growth, wood quality, disease and insect resistance. Candidate gene-based association genetics have successfully found marker–trait associations for wood and fiber traits. Genomic selection experiments have demonstrated clear potential to improve the efficiency of breeding programs while freeze-tolerant transgenic Eucalyptus trials have recently been initiated. The recently released E. grandis genome, sequenced to an average coverage of 8�, will open up exceptional opportunities to advance Myrtaceae genetics and genomics research