Recent advances in conifer somatic embryogenesis: improving somatic embryo quality

Somatic embryogenesis of coniferous species was first reported more than 20 years ago. Since then, there has been an explosion of research aimed at developing and optimizing protocols for efficient regeneration of plantlets. Although routinely used both as a means of propagation, as well as a valuable model system for investigating the structural, physiological, and molecular events occurring during embryo development, in vitro embryogenesis is still problematic for some coniferous species. Major problems include: low number of embryos generated; and low frequency of mature embryos able to convert into viable plantlets. Until recent years, despite the fact that embryogenesis is comprised of a sequence of defined steps which include proliferation of embryogenic tissue, embryo maturation, and germination, attempts at improving the whole procedure have been made almost exclusively during the maturation stage. This strategy was based on the assumption that successful regeneration is related to treatments provided during the development of the embryos. Major optimizations of the maturation medium have involved judicious selections of type and concentration of growth regulators, namely abscisic acid, and adjustments of the osmoticum of the culture medium. Extensive work has been conducted in defining the effects of plasmolysing and non-plasmolysing osmoticum agents during maturation, as well as in improving desiccation techniques required for the completion of the maturation program. In the last 2 years, however, work on spruce has clearly demonstrated that the early events in embryogenesis are crucial for the successful completion of the overall embryogenic program. The use of cell tracking techniques, implemented by physiological and molecular studies, has revealed that manipulations of the culture conditions early in the process can increase both number and quality of embryos produced in culture. Additional manipulations of the germination medium can also enhance germination and conversion frequency of somatic embryos matured in a sub-optimal environment. These new findings, together with the unraveling of molecular mechanisms involved in the control/regulation of embryo development hold considerable promise for clonal propagation in conifers.     

Factors controlling somatic embryogenesis

Histological and ultrastructural, molecular and elemental distribution changes were investigated during the induction of direct somatic embryogenesis using theCamellia japonica leaf culture system. In this culture system, direct somatic embryogenesis is induced in a controlled way in a specific leaf region (leaf blade) within a leaf. Embryogenic and non-embryogenic leaf regions have characteristic energy-dispersive X-ray spectra already before induction. According to these results electron probe X-ray microanalysis (EPMA) can be a tool for early diagnosis of embryogenic competence. Histological studies showed that severe fluctuations in the number of calcium oxalate crystals and in starch accumulation occur after induction but only in induced tissues. Changes in the cell wall composition of competent cells occur shortly after the induction treatment. The induction of morphogenesis is linked to the appearance of callose covering the surface cells of induced leaves and calluses. A 2^nd deposition of material (cutin) is necessary for normal somatic embryogenesis to occur. The involvement of lipid transfer proteins in the appearance of cutin in the embryogenic regions of the explant is suggested.     

microRNAs和体细胞重编程

体细胞重编程与microRNAs(miRNAs)均为近年来研究的热点问题。到目前为止,能成功诱导体细胞形成多能性干细胞的体细胞重编程方法有核移植(nuclear transfer,NT)和外源因子诱导形成多能干细胞(induced pluripotent stem cells,iPSc)两种,这两种方法让人们看到了体细胞重编程在细胞治疗方面具有诱人的应用前景。miRNAs是真核生物中存在的一类长度为22nt左右起调控作用的内源性非编码RNA,它在转录后水平调节靶基因的表达,是细胞内基因表达的基本调控机制之一。近年的研究结果表明,miRNAs在干细胞干性维持和分化过程中具有重要的调节作用,从miRNAs角度研究体细胞重编程机理将对体细胞重编程的应用具有重要意义。     

Targeting of somatic hypermutation

Somatic hypermutation (SHM) introduces mutations in the variable region of immunoglobulin genes at a rate of approximately 10(-3) mutations per base pair per cell division, which is 10(6)-fold higher than the spontaneous mutation rate in somatic cells. To ensure genomic integrity, SHM needs to be targeted specifically to immunoglobulin genes. The rare mistargeting of SHM can result in mutations and translocations in oncogenes, and is thought to contribute to the development of B-cell malignancies. Despite years of intensive investigation, the mechanism of SHM targeting is still unclear. We review and attempt to reconcile the numerous and sometimes conflicting studies on the targeting of SHM to immunoglobulin loci, and highlight areas that hold promise for further investigation.     

Long-term somatic embryogenesis and maturation of somatic embryos in Hevea brasiliensis

A high frequency of secondary embryogenesis was induced from isolated early cotyledonary-stage somatic embryos of Hevea brasiliensis. A long-term embryogenic line was established by the use of recurrent embryogenesis and maintained for 3 years on hormone-free medium by the transfer of selected proembryogenic masses every 10 days.

The addition of 234 mM sucrose as stress with sucrose and 10⁻⁵ M abscisic acid (ABA) to the culture medium enhanced the maturation of somatic embryos. Under these culture conditions, the embryo population was composed of 45% globular, 18% oblong and 37% torpedo-stage embryos. These somatic embryos had well-formed tissue structure, a well-defined epidermis, protein storage bodies, and a high accumulation of starch. The triglyceride content was five times as high in the torpedo-stage embryos that developed on medium supplemented with 234 mM sucrose and 10⁻⁵ M ABA as in embryos obtained on basal medium with 58 mM sucrose.     

Genetic control of somatic cell differentiation in Volvox analysis of somatic regenerator mutants

The somatic regenerator (reg) mutants of Volvox carteri affect the ability of the normally terminally differentiated somatic cells to establish and/or maintain the differentiated state. Thirty-nine reg mutants of four phenotypic classes have been mapped to two, unlinked genes, regA and regB. Mutants at the regA locus have one of three phenotypes: All somatic cells regenerate new spheroids, somatic cells in the spheroid posterior region regenerate while those in the anterior region differentiate as somatic cells, or regenerating and nonregenerating cells are randomly intermixed. The regB mutant has a random intermixture of regenerating and nonregenerating cells. Somatic cells regenerate new Volvox spheroids in two ways; the cells lose their characteristic shape, become immotile, enlarge and undergo cleavage similar to that of normal reproductive cells or undergo cell division without prior enlargement or loss of cell shape. Temperature shift experiments on a cold-sensitive reg mutant suggest that the gene product acts after the somatic cell initials are formed at the end of cleavage.     

Genetic transformation of alfalfa somatic embryos and their clonal propagation through repetitive somatic embryogenesis

Genetically transformed alfalfa (Medicago sativa L., cv. Zajearska 83) plantlets were obtained by inoculating somatic embryos with Agrobacterium tumefaciens strains A281/pGA472 and LBA4404/pBI121. Single somatic embryos, 5–7 mm long, were released from a repetitively embryogenic culture, wounded, and cocultivated with the bacteria. The agar-solidified culture medium contained mineral salts, vitamins, 40 g l^–1 sucrose, 1 g l^–1 yeast extract and 0.05 mg l^–1 BA. Five clones, transformed with A281/pGA472, and 4 clones transformed with LBA4404/pBI121, were selected for proliferation by repetitive somatic embryogenesis, on media containing 100 mg l^–1 of kanamycin. The transformation of kanamycin-resistant clones was confirmed by assaying the activity of neomycin phosphotransferase II and/or -glucuronidase enzymes, and by the Southern blot analysis. It is suggested that the transformation/regeneration system based on somatic embryogenesis may be suitable for establishing transgenic alfalfa lines. The relatively low frequency of embryo transformation is compensated for by abundant proliferation in secondary somatic embryogenesis.Abbreviations BA 6-benzyladenine - GUS -glucuronidase - Km kanamycin - NPTII neomycin phosphotransferase II - X-gluc 5-bromo-4-chloro-3-indolyl--glucuronic acid - BM basal medium     

Automation of somatic embryo production

Automation could enhance the use of somatic embryogenesis for micropropagation in two ways: as effective tools for research on somatic embryogenesis, and for improving the efficiency of embryo production by reducing labor costs. Processes expected to be automated for somatic embryo production are: (1) evaluation of embryogenic cultures, (2) embryo development, (3) harvesting, (4) post-harvesting (pre-delivery) processes for enhancing conversion and preparing for delivery. In this review, the techniques related to the automation of each process are introduced and discussed. This revised version was published online in June 2006 with corrections to the Cover Date.     

Noninvasive evaluation of somatic embryogenesis

Callus Suspension Cultures of Ipomea batates Poir. cv. White Star were grown in an airlift bioreactor. A machine vision system was used to monitor nondestructively callus growth during a 10 day culture period. Growth data obtained with this system included the overall reactor population and population estimates for the 200-1200-mum fractions at 200-mum intervals. A model of callus growth was developed to explain the mechanics of callus enlargement. The model was based on the assumptions that (1) the calli could not subdivide or shrink, (2) there was a fixed percentage of the initial population for each fraction that was nonviable, and (3) growth rates did not vary with time during the culture period. It was determined that the growth rates and nonviable ratios decreased as fraction size increased.     

Developmental pathways of somatic embryogenesis

Somatic embryogenesis is defined as a process in which a bipolar structure, resembling a zygotic embryo, develops from a non-zygotic cell without vascular connection with the original tissue. Somatic embryos are used for studying regulation of embryo development, but also as a tool for large scale vegetative propagation. Somatic embryogenesis is a multi-step regeneration process starting with formation of proembryogenic masses, followed by somatic embryo formation, maturation, desiccation and plant regeneration. Although great progress has been made in improving the protocols used, it has been revealed that some treatments, coinciding with increased yield of somatic embryos, can cause adverse effects on the embryo quality, thereby impairing germination and ex vitro growth of somatic embryo plants. Accordingly, ex vitro growth of somatic embryo plants is under a cumulative influence of the treatments provided during the in vitro phase. In order to efficiently regulate the formation of plants via somatic embryogenesis it is important to understand how somatic embryos develop and how the development is influenced by different physical and chemical treatments. Such knowledge can be gained through the construction of fate maps representing an adequate number of morphological and molecular markers, specifying critical developmental stages. Based on this fate map, it is possible to make a model of the process. The mechanisms that control cell differentiation during somatic embryogenesis are far from clear. However, secreted, soluble signal molecules play an important role. It has long been observed that conditioned medium from embryogenic cultures can promote embryogenesis. Active components in the conditioned medium include endochitinases, arabinogalactan proteins and lipochitooligosaccharides.     

Modeling somatic evolution in tumorigenesis

Tumorigenesis in humans is thought to be a multistep process where certain mutations confer a selective advantage, allowing lineages derived from the mutated cell to outcompete other cells. Although molecular cell biology has substantially advanced cancer research, our understanding of the evolutionary dynamics that govern tumorigenesis is limited. This paper analyzes the computational implications of cancer progression presented by Hanahan and Weinberg in The Hallmarks of Cancer. We model the complexities of tumor progression as a small set of underlying rules that govern the transformation of normal cells to tumor cells. The rules are implemented in a stochastic multistep model. The model predicts that (i) early-onset cancers proceed through a different sequence of mutation acquisition than late-onset cancers; (ii) tumor heterogeneity varies with acquisition of genetic instability, mutation pathway, and selective pressures during tumorigenesis; (iii) there exists an optimal initial telomere length which lowers cancer incidence and raises time of cancer onset; and (iv) the ability to initiate angiogenesis is an important stage-setting mutation, which is often exploited by other cells. The model offers insight into how the sequence of acquired mutations affects the timing and cellular makeup of the resulting tumor and how the cellular-level population dynamics drive neoplastic evolution.     

Cellular reprogramming of somatic cells

The process of 'cell reprogramming' can be achieved by somatic cell nuclear transfer, cell fusion with embryonic stem cells, exposure to stem cell extracts, or by inducing pluripotentcy mediated by defined factors giving rise to what are termed induced pluripotent stem cells. More recently, the fate of a somatic cell can be directly induced to uptake other cell fates, termed lineage-specific reprogramming, without the need to de-differentiate the cells to a pluripotent state. In this review we will describe the different methods of reprogramming somatic cells.