Control of root meristem establishment in conifers

The evolution of terrestrial plant life was made possible by the establishment of a root system, which enabled plants to migrate from aquatic to terrestrial habitats. During evolution, root organization has gradually progressed from a very simple to a highly hierarchical architecture. Roots are initiated during embryogenesis and branch afterward through lateral root formation. Additionally, adventitious roots can be formed post‐embryonically from aerial organs. Induction of adventitious roots (ARs) forms the basis of the vegetative propagation via cuttings in horticulture, agriculture and forestry. This method, together with somatic embryogenesis, is routinely used to clonally multiply conifers. In addition to being utilized as propagation techniques, adventitious rooting and somatic embryogenesis have emerged as versatile models to study cellular and molecular mechanisms of embryo formation and organogenesis of coniferous species. Both formation of the embryonic root and the AR primordia require the establishment of auxin gradients within cells that coordinate the developmental response. These processes also share key elements of the genetic regulatory networks that, e.g. are triggering cell fate. This minireview gives an overview of the molecular control mechanisms associated with root development in conifers, from initiation in the embryo to post‐embryonic formation in cuttings.     

iTRAQ Protein Profiling of Adventitious Root Formation in Mulberry Hardwood Cuttings

The ability to form mature adventitious roots (AR) provides a competitive advantage for clonal multiplication of elite genotypic plant species, because high economic losses occur as a result of insufficient rooting. To better understand potential mechanisms involved in AR formation, we utilized an iTRAQ-based proteomic approach on mulberry hardwood cuttings. A total of 4427 proteins were identified from the base of cuttings, of which 595 and 231 proteins showed differential accumulations in the two periods of rooting, respectively. Three differentially expressed enzyme proteins were validated by an enzyme assay and qPCR. Functional annotation analysis showed that dysregulated proteins were involved in glucose metabolism, flavonoids biosynthesis, cell wall modification, and hormone regulation, indicating potential contributions to adventitious rooting. These results provide fundamental and important information for research on the molecular mechanism of AR development in mulberry cuttings and facilitate rooting efficiency in agricultural practice.     

Distribution of indole-3-acetic acid in Petunia hybrida shoot tip cuttings and relationship between auxin transport, carbohydrate metabolism and adventitious root formation

To determine the contribution of polar auxin transport (PAT) to auxin accumulation and to adventitious root (AR) formation in the stem base of Petunia hybrida shoot tip cuttings, the level of indole-3-acetic acid (IAA) was monitored in non-treated cuttings and cuttings treated with the auxin transport blocker naphthylphthalamic acid (NPA) and was complemented with precise anatomical studies. The temporal course of carbohydrates, amino acids and activities of controlling enzymes was also investigated. Analysis of initial spatial IAA distribution in the cuttings revealed that approximately 40 and 10 % of the total IAA pool was present in the leaves and the stem base as rooting zone, respectively. A negative correlation existed between leaf size and IAA concentration. After excision of cuttings, IAA showed an early increase in the stem base with two peaks at 2 and 24 h post excision and, thereafter, a decline to low levels. This was mirrored by the expression pattern of the auxin-responsive GH3 gene. NPA treatment completely suppressed the 24-h peak of IAA and severely inhibited root formation. It also reduced activities of cell wall and vacuolar invertases in the early phase of AR formation and inhibited the rise of activities of glucose-6-phosphate dehydrogenase and phosphofructokinase during later stages. We propose a model in which spontaneous AR formation in Petunia cuttings is dependent on PAT and on the resulting 24-h peak of IAA in the rooting zone, where it induces early cellular events and also stimulates sink establishment. Subsequent root development stimulates glycolysis and the pentose phosphate pathway.     

Maternal control of vertebrate development before the midblastula transition: mutants from the zebrafish I

Maternal factors control development prior to the activation of the embryonic genome. In vertebrates, little is known about the molecular mechanisms by which maternal factors regulate embryonic development. To understand the processes controlled by maternal factors and identify key genes involved, we embarked on a maternal-effect mutant screen in the zebrafish. We identified 68 maternal-effect mutants. Here we describe 15 mutations in genes controlling processes prior to the midblastula transition, including egg development, blastodisc formation, embryonic polarity, initiation of cell cleavage, and cell division. These mutants exhibit phenotypes not previously observed in zygotic mutant screens. This collection of maternal-effect mutants provides the basis for a molecular genetic analysis of the maternal control of embryogenesis in vertebrates.     

Inhibition of adventitious root development in apple rootstocks by cytokinin is based on its suppression of adventitious root primordia formation

Cytokinin (CK) inhibits adventitious root (AR) formation in stem cuttings. Little is known, however, about the mechanism underlying the inhibitory effect. In this study, 2 mg l^?1 of exogenous 6‐benzyl adenine (6‐BA) was administered to 3 and 7‐day‐old apple rootstocks ‘M.26’ cuttings (3 and 7 days 6‐BA) by transferring them from a rooting medium containing indole‐3‐butanoic acid to the medium containing 6‐BA. Anatomical and morphological observations revealed that the exogenous application of 6‐BA inhibited primordia formation in the 3 days 6‐BA but not the 7 days 6‐BA group. The concentration of auxin (IAA), the ratios of IAA/CK and IAA/abscisic acid were lower in 3 days 6‐BA than in 7 days 6‐BA. Expression analysis of genes known to be associated with AR formation was also analyzed. In the 3 days 6‐BA group, high level of CK inhibited the synthesis and transport of auxin, as a result, low endogenous auxin level suppressed the auxin signaling pathway genes, as were other AR development and cell cycle related genes; all of which had an inhibitory impact on AR primordium formation. On the contrary, low CK level in the 7 days 6‐BA, reduced the inhibitory impact on auxin levels, leading to an upregulated expression of genes known to promote AR primordia formation. Collectively, our data indicated that 3–7 days is the time period in which AR primordia formation occurs in cuttings of ‘M.26’ and that the inhibition of AR development by CK is due to the suppression of AR primordia development over 3–7 days period after culturing in rooting medium.     

Staphylococcus aureus CidA and LrgA proteins exhibit holin-like properties

The Staphylococcus aureus cid and lrg operons are known to be involved in biofilm formation by controlling cell lysis and the release of genomic DNA, which ultimately becomes a structural component of the biofilm matrix. Although the molecular mechanisms controlling cell death and lysis are unknown, it has been hypothesized that the cidA and lrgA genes encode holin- and antiholin-like proteins and function to regulate these processes similarly to bacteriophage-induced death and lysis. In this study, we focused on the biochemical and molecular characterization of CidA and LrgA with the goal of testing the holin model. First, membrane fractionation and fluorescent protein fusion studies revealed that CidA and LrgA are membrane-associated proteins. Furthermore, similarly to holins, CidA and LrgA were found to oligomerize into high-molecular-mass complexes whose formation was dependent on disulfide bonds formed between cysteine residues. To determine the function of disulfide bond-dependent oligomerization of CidA, an S. aureus mutant in which the wild-type copy of the cidA gene was replaced with the cysteine mutant allele was generated. As determined by β-galactosidase release assays, this mutant exhibited increased cell lysis during stationary phase, suggesting that oligomerization has a negative impact on this process. When analyzed for biofilm development and maturation, this mutant displayed increased biofilm adhesion in a static assay and a greater amount of dead-cell accumulation during biofilm maturation. These studies support the model that CidA and LrgA proteins are bacterial holin-/antiholin-like proteins that function to control cell death and lysis during biofilm development.     

Developmental paradigms in terminal lung development

Late lung development comprises the formation of the terminal sac followed by the subdivision of the terminal sac by septa into alveoli and results in the formation of the gas-exchange surface of the lung. This developmentally regulated process involves a complex epithelium-mesenchyme interaction via evolutionarily conserved molecular signaling pathways. In addition, there is a continuous process of vascular growth and development. Currently there are large gaps in our understanding of the molecular mechanisms involved in the formation of the gas-exchange surface. In this review, we attempt to integrate and reconcile the morphologic features in late lung development with what is known about the molecular basis for these processes. We describe the formation of the terminal sac and the subsequent formation of the septa, which divide the terminal sac into alveoli, in terms of the classically described developmental stages of induction, morphogenesis and differentiation. We believe that evolutionarily conserved pathways regulate this process and that morphogen gradients are likely to be a central mechanism. In addition, we highlight the importance of the molecular mechanisms involved in the simultaneous development of the vascular bed and its importance in the late development of the lungs.     

Petunia as model for elucidating adventitious root formation and mycorrhizal symbiosis: at the nexus of physiology,genetics, microbiology and horticulture

Adventitious root formation in cuttings and establishment of arbuscular mycorrhizal symbiosis reflect the enormous plasticity of plants and are key factors in the efficient and sustainable clonal propagation and production of ornamental crops. Based on the high importance of Petunia hybrida for the European and US annual bedding plant markets and its suitability as a model for basic plant sciences, petunia has been established as an experimental system for elucidating the molecular and physiological processes underlying adventitious root formation and mycorrhizal symbiosis. In the present review, we introduce the tools of the Petunia model system. Then, we discuss findings regarding the hormonal and metabolic control of adventitious rooting in the context of diverse environmental factors as well as findings on the function of arbuscular mycorrhiza related to nutrient uptake and resistance to root pathogens. Considering the recent publication of the genomes of the parental species of P. hybrida and other tools available in the petunia scientific community, we will outline the quality of petunia as a model for future system‐oriented analysis of root development and function in the context of environmental and genetic control, which are at the heart of modern horticulture.     

Gibberellins inhibit adventitious rooting in hybrid aspen and Arabidopsis by affecting auxin transport

Knowledge of processes involved in adventitious rooting is important to improve both fundamental understanding of plant physiology and the propagation of numerous plants. Hybrid aspen (Populus tremula × tremuloïdes) plants overexpressing a key gibberellin (GA) biosynthesis gene (AtGA20ox1) grow rapidly but have poor rooting efficiency, which restricts their clonal propagation. Therefore, we investigated the molecular basis of adventitious rooting in Populus and the model plant Arabidopsis. The production of adventitious roots (ARs) in tree cuttings is initiated from the basal stem region, and involves the interplay of several endogenous and exogenous factors. The roles of several hormones in this process have been characterized, but the effects of GAs have not been fully investigated. Here, we show that a GA treatment negatively affects the numbers of ARs produced by wild‐type hybrid aspen cuttings. Furthermore, both hybrid aspen plants and intact Arabidopsis seedlings overexpressing AtGA20ox1, PttGID1.1 or PttGID1.3 genes (with a 35S promoter) produce few ARs, although ARs develop from the basal stem region of hybrid aspen and the hypocotyl of Arabidopsis. In Arabidopsis, auxin and strigolactones are known to affect AR formation. Our data show that the inhibitory effect of GA treatment on adventitious rooting is not mediated by perturbation of the auxin signalling pathway, or of the strigolactone biosynthetic and signalling pathways. Instead, GAs appear to act by perturbing polar auxin transport, in particular auxin efflux in hybrid aspen, and both efflux and influx in Arabidopsis.     

茶树嫩枝扦插的高效方法

茶(Camellia sinensis)是世界上最重要的饮料作物之一, 随着种植面积的扩大, 茶苗的需求量也日益增加。传统的扦插育苗方式存在着生根难、周期长和取材难等问题, 因此优化扦插生根的方法十分重要。该研究以较易获得、但传统方法难以生根的绿色嫩枝为扦插材料, 首先对培养介质进行改良。与土培和水培相比, 利用海绵培养可以使茶树幼嫩插穗在1个月之内快速生根, 生根率达32.2%。其次, 对海绵培方法做进一步优化, 确定一芽一叶的幼嫩短穗生根潜力更佳; 同时, 添加生根粉能够促进茶树茎部愈伤组织与根系的形成, 其中1.25 g∙L ^-1生根粉处理48小时对茶树扦插快速生根最有效, 生根率达42.0%。综上, 通过优化培养介质和扦插材料以及适当添加生根粉等措施, 建立了一种茶树高效嫩枝扦插生根的方法。该方法能够显著缩短嫩枝插穗的生根时间, 突破了扦插材料的限制, 有效降低了扦插成本, 具有重要的应用前景。     

茶树嫩枝扦插的高效方法

茶(Camellia sinensis)是世界上最重要的饮料作物之一, 随着种植面积的扩大, 茶苗的需求量也日益增加。传统的扦插育苗方式存在着生根难、周期长和取材难等问题, 因此优化扦插生根的方法十分重要。该研究以较易获得、但传统方法难以生根的绿色嫩枝为扦插材料, 首先对培养介质进行改良。与土培和水培相比, 利用海绵培养可以使茶树幼嫩插穗在1个月之内快速生根, 生根率达32.2%。其次, 对海绵培方法做进一步优化, 确定一芽一叶的幼嫩短穗生根潜力更佳; 同时, 添加生根粉能够促进茶树茎部愈伤组织与根系的形成, 其中1.25 g?L ^-1生根粉处理48小时对茶树扦插快速生根最有效, 生根率达42.0%。综上, 通过优化培养介质和扦插材料以及适当添加生根粉等措施, 建立了一种茶树高效嫩枝扦插生根的方法。该方法能够显著缩短嫩枝插穗的生根时间, 突破了扦插材料的限制, 有效降低了扦插成本, 具有重要的应用前景。     

Multiple factors influence adventitious rooting in carnation (<Emphasis Type="Italic">Dianthus caryophyllus</Emphasis> L.) stem cuttings

Efficient propagation of uniform starting material is a critical requirement for mass production of most ornamental plants, including carnation. For some elite cultivars, the production of young plantlets is limited by poor adventitious root formation from stem cuttings. We previously characterized the molecular signature during adventitious rooting in two carnation cultivars, 2101-02 MFR and 2003 R 8, which were selected because of their contrasting rooting performance. To determine additional factors that contribute to the differences observed in adventitious rooting during the commercial scaling-up of this species, we characterized rooting performance and endogenous hormone levels in stem cuttings of these two cultivars during one production season. We found that stem cutting production declined during the harvest season in a cultivar-dependent manner. In addition, the initiation of adventitious roots in the stem cutting base depended on its endogenous auxin and cytokinin levels at harvest time, while their subsequent growth and development was mainly influenced by the physiological status of the mother plant at harvest time and of the stem cutting during the rooting process.