The Castanea sativa SCL1 gene (CsSCL1) has previously been shown to be induced by auxin during adventitious root (AR) formation in rooting-competent microshoots. However, its expression has not previously been analyzed in rooting-incompetent shoots. This study focuses on the regulation of CsSCL1 during maturation and the role of the gene in the formation of AR. The expression of CsSCL1 in rooting-incompetent microshoots and other tissues was investigated by quantitative reverse transcriptase--polymerase chain reaction. The analysis was complemented by in situ hybridization of the basal segments of rooting-competent and --incompetent microshoots during AR induction, as well as in AR and lateral roots. It was found that CsSCL1 is upregulated by auxin in a cell-type- and phase-dependent manner during the induction of AR. In root-forming shoots, CsSCL1 mRNA was specifically located in the cambial zone and derivative cells, which are rooting-competent cells, whereas in rooting-incompetent shoots the hybridization signal was more diffuse and evenly distributed through the phloem and parenchyma. CsSCL1 expression was also detected in lateral roots and axillary buds. The different CsSCL1 expression patterns in rooting-competent and -incompetent microshoots, together with the specific location of transcripts in cell types involved in root meristem initiation and in the root primordia of AR and lateral roots, indicate an important role for the gene in determining whether certain cells will enter the root differentiation pathway and its involvement in meristem maintenance.
The genus Castanea includes several tree species that are relevant because of their geographical extension and their multipurpose character, that includes nut and timber production. However, commercial exploitation of the trees is hindered by several factors, particularly by their limited regeneration ability. Regardless of recent advances, there exists a serious limitation for the propagation of elite genotypes of chestnut due to decline of rooting ability as the tree ages. In the present review, we summarize the research developed in this genus during the last three decades concerning the formation of adventitious roots (ARs). Focusing on cuttings and in vitro microshoots, we gather the information available on several species, particularly C. sativa, C. dentata and the hybrid C.sativa × C. crenata, and analyze the influence of several factors on the achievements of the applied protocols, including genotype, auxin treatment, light regime and rooting media. We also pay attention to the acclimation phase, as well as compile the information available about biochemical and molecular related aspects. Furthermore, we considerate promising biotechnological approaches that might enable the improvement of the current protocols.
In eukaryotes, trithorax group proteins play critical roles in the regulation of transcription, cell proliferation, differentiation and development. In this work we report the molecular cloning and characterization of SEPR11, a cDNA from the conifer Monterrey pine (Pinus radiata) encoding a polypeptide homologue of a trithorax group member described in animals and yeast. A full-length clone was isolated from RNA prepared from somatic embryos and contained a 1,239 bp ORF encoding 412 amino acids. Characterization of the isolated sequence revealed that it contains a SPRY domain in the C-terminal region. A comparison of the pine sequence with homologous proteins from plants, animals and yeast revealed that SEPR11 is phylogenetically related to the trithorax group members and not a SPRY-domain containing protein. RT-PCR analyses of transcript abundance in pine tissues demonstrated that SEPR11 is particularly abundant in embryos, suggesting that this gene could be involved during embryo development. The spatial localization of SEPR11 transcripts revealed that gene expression was restricted to the vascular bundle and apical and radicular meristems, suggesting a possible function of this gene in meristem control and vascular bundle development. This work is the first report of the presence of a trithorax group homologue gene in gymnosperm.
The aim of this study was to propagate axillary shoots of Cannabis sativa L. using liquid medium in temporary immersion bioreactors. The effect of immersion frequency (3 or 6 immersions per day), explant type (apical or basal sections), explant number (8, 10, and 16 explants), mineral medium (Murashige and Skoog half-strength nitrates, β-A and β-H, all supplemented with 2-μM metatopoline), sucrose supplementation (2, 0.5, and 0% sucrose), culture duration (4 and 6 weeks), and bioreactor type (RITA® and Plantform™) were investigated. As a result, we propose a protocol for the proliferation of cannabis apical segments in RITA® or Plantform™ bioreactors. The explants (8 per RITA® and 24 per Plantform™) are immersed for 1 min, 3 times per day in β-A medium supplemented with 2-μM metatopoline and 0.5% of sucrose and subcultured every 4 weeks. This is the first study using temporary immersion systems in C. sativa production, and our results provide new opportunities for the mass propagation of this species.
Somatic embryogenesis is a powerful tool for plant regeneration and also provides a suitable material for investigating the molecular events that control the induction and development of somatic embryos. This study focuses on expression analysis of the QrCPE gene (which encodes a glycine rich protein) during the initiation of oak somatic embryos from leaf explants and also during the histodifferentiation of somatic embryos. Northen blot and in situ hybridization were used to determine the specific localization of QrCPE mRNA. The results showed that the QrCPE gene is developmentally regulated during the histodifferentiation of somatic embryos and that its expression is tissue-and genotype-dependent. QrCPE was strongly expressed in embryogenic cell aggregates and in embryogenic nodular structures originated in leaf explants as well as in the protodermis of somatic embryos from which new embryos are generated by secondary embryogenesis. This suggests a role for the gene during the induction of somatic embryos and in the maintenance of embryogenic competence. The QrCPE gene 2 was highly expressed in actively dividing cells during embryo development, suggesting that it participates in embryo histodifferentiation. The localized expression in the root cap initial cells of cotyledonary somatic embryos and in the root cap of somatic seedlings also suggests that the gene may be involved the fate of root cap cells.
Medical cannabis (Cannabis sativa L.) is a source of bioactive phytochemicals with promising pharmacological and therapeutic applications. Enhancing the accumulation of valuable bioactive compounds is potentially a way of increasing the economic importance of this crop. Signaling molecules like salicylic acid (SA), jasmonic acid (JA), and γ-aminobutyric acid (GABA) are involved in the regulation of plant development and responses to biotic and abiotic stresses. Moreover, several phytohormones regulate plant trichome formation and elicit the synthesis of secondary metabolites in many plant species in both in vitro and in vivo systems. Therefore, exogenously delivered plant signaling molecules have the potential to modify the chemical profiles of medical cannabis. In this study, we found that the foliar application of SA, methyl jasmonate (MeJA), and GABA produces changes in the accumulation of the two major cannabinoids, cannabidiolic acid (CBDA) and Δ9- tetrahydrocannabinolic acid (THCA), in leaves and inflorescences of a medical cannabis variety. MeJA at 0.1 mM increased the CBDA content in inflorescences by 15.6%, while SA and MeJA at 0.1 mM increased CBDA and THCA accumulation in leaves by up to 57.3%. Treatments did not change the expression of genes participating in the final steps of the biosynthetic pathway of cannabinoids: olivetolic acid cyclase (CsOAC-1 and CsOAC-2), 2-acylphloroglucinol 4-prenyltransferase (CsPT4), cannabidiolic acid synthase (CsCBDAS), and tetrahydrocannabinolic acid synthase (CsTHCAS). Trichome density was not significantly different from the control plants in any treatment. Besides, we found strong correlations between several plant growth parameters and cannabinoid yields, showing a direct link between plant fitness and the production of cannabinoids.
El cultivo in vitro es una herramienta útil para la conservación y la propagación de germoplasma valioso, como es el caso de los árboles singulares. Además de lograr la clonación de sus genotipos y permitir su conservación a medio y largo plazo, presenta otras ventajas como la disponibilidad de material vegetal en cualquier momento del año para realizar estudios fisiológicos, genéticos y epigenéticos, y para ser utilizado en eventos de divulgación científica en centros educativos, ferias de la ciencia, etc.Por otra parte, la micropropagación de ejemplares de edad avanzada, como es el caso de los árboles singulares, puede resultar difícil debido a problemas como un nº limitado de brotes disponibles para la instalación, altos niveles de microorganismos endógenos y exógenos, baja capacidad de multiplicación durante la prolongada etapa de estabilización y bajos porcentajes de formación de raíces.En este trabajo presentamos algunas actuaciones dirigidas a la instalación in vitro de ejemplares singulares de nogal, roble, alcornoque, abedul y eucalipto de Galicia, algunos de los cuales están recogidos en el “Catálogo de Árbores Senlleiras” de esta comunidad. En algunos de ellos se ha conseguido sobrepasar las fases de establecimiento y estabilización del cultivo y se están realizando ensayos de mantenimiento en frío, de enraizamiento y aclimatación en fitotrón e invernadero.
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