Degeneration pattern in somatic embryos of <Emphasis Type="Italic">Pinus sylvestris</Emphasis> L.

Somatic embryos can be used for propagating forest trees vegetatively, which is of great importance for capturing the genetic gain in breeding programs. However, many economically important Pinus species are difficult or impossible to propagate via somatic embryogenesis. In order to get a better understanding of the difficulties to propagate Pinus species via somatic embryogenesis, we are studying the developmental pathway of somatic embryos in different cell lines. In a previous study, we showed that the morphology of early somatic embryos in Scots pine (Pinus sylvestris) differs between cell lines giving rise to normal or abnormal cotyledonary embryos. In this study, we have compared the proliferation and degeneration pattern of early and late embryos in a normal and abnormal cell line. In both cell lines, a high frequency of the embryos degenerated. Among the degenerating embryos, two main degeneration patterns could be distinguished. In the normal cell line, the embryos degenerated similar to how the subordinate embryos are degraded in the seed. In the abnormal cell line, the degeneration of the embryos resulted in a continuous loop of embryo degeneration and differentiation of new embryos. We observed a similar degeneration pattern when embryogenic tissue was initiated from megagametophytes containing zygotic embryos at the stage of cleavage polyembryony. Based on our results, we suggest that the degeneration pattern in abnormal cell lines starts during initiation of embryogenic cultures.     

Plasticity in Cell Division Patterns and Auxin Transport Dependency during in Vitro Embryogenesis in Brassica napus

In Arabidopsis thaliana, zygotic embryo divisions are highly regular, but it is not clear how embryo patterning is established in species or culture systems with irregular cell divisions. We investigated this using the Brassica napus microspore embryogenesis system, where the male gametophyte is reprogrammed in vitro to form haploid embryos in the absence of exogenous growth regulators. Microspore embryos are formed via two pathways: a zygotic-like pathway, characterized by initial suspensor formation followed by embryo proper formation from the distal cell of the suspensor, and a pathway characterized by initially unorganized embryos lacking a suspensor. Using embryo fate and auxin markers, we show that the zygotic-like pathway requires polar auxin transport for embryo proper specification from the suspensor, while the suspensorless pathway is polar auxin transport independent and marked by an initial auxin maximum, suggesting early embryo proper establishment in the absence of a basal suspensor. Polarity establishment in this suspensorless pathway was triggered and guided by rupture of the pollen exine. Irregular division patterns did not affect cell fate establishment in either pathway. These results confirm the importance of the suspensor and suspensor-driven auxin transport in patterning, but also uncover a mechanism where cell patterning is less regular and independent of auxin transport.     

Polar auxin transport controls suspensor fate

Polar auxin transport is critical for normal embryo development in angiosperms. It has been proposed that auxin accumulates dynamically at specific positions, which in early Arabidopsis embryos correlates with developmental decisions such as specification of the apical cell lineage, specification of the hypophysis, and differentiation of the two cotyledons. In conifers, pattern formation during embryo development is different, and includes a free nuclear stage, nondividing suspensor cells, presence of tube cells, lack of hypophysis and formation of a crown of cotyledons surrounding the shoot apical meristem. We have recently shown that polar auxin transport is important for normal embryo development also in conifers. Here we suggest a model where auxin is transported from the suspensor cells to the embryonal mass during early embryogeny in conifers. This transport is essential for the developmental decisions of the tube cells and the suspensor, and affects both the amount of programmed cell death and the embryo patterning.Key words: conifer, embryo development, 1-N-naphtylphthalamic acid (NPA), patterning, polar auxin transport, programmed cell death, somatic embryogenesis, suspensorIn the model plant Arabidopsis thaliana auxin is transported, already from the first cell division of the zygote, from the basal cell to the apical cell, where it is involved in establishing the identity of the apical cell lineage. At the 32-cell stage the polar auxin transport is reversed, leading to an auxin accumulation in the uppermost suspensor cell, which occurs concomitantly with the specification of the hypophysis. During the heart stage auxin is transported towards the cotyledonary primordia, giving positional information about the cotyledon outgrowth.¹ Formation of the apical-basal embryonic pattern during early embryogeny in conifers is quite different from that in Arabidopsis and proceeds through the establishment of three major cell types: the meristematic cells of the embryonal mass, the embryonal tube cells and terminally differentiated nondividing suspensor cells.²The somatic embryo system of Picea abies (Norway spruce) includes a stereotyped sequence of developmental stages, resembling zygotic embryogeny, which can be synchronized by specific treatments.^3,4 We are using this as a model system for elucidating the regulation of embryo development in conifers.² Early somatic embryos differentiate from proembryonic masses (PEMs) after withdrawal of the plant growth regulators (PGRs) auxin and cytokinin (Fig. 1A and B). We have previously shown that the organisation of the apical-basal polarity in early embryos is dependent on a gradient of PCD from the embryonal tube cells committed to death, to the cell corpses at the basal end of the suspensor.^5–7 Dysregulation of the PCD leads to aberrant apical-basal patterning.Open in a separate windowFigure 1Model for polar auxin transport control of early embryo patterning in conifers. (A) Embryogenic cultures proliferate as proembryonic masses (PEMs) in the presence of the plant growth regulators (PGRs) auxin and cytokinin. (B) Early embryos start to differentiate from PEMs after withdrawal of PGRs. Endogenous auxin is transported to the newly formed embryonal mass. (C) Early embryos are formed within two weeks in PGR-free medium. Early embryos have a distinct embryonal mass, tube cells and a suspensor. IAA is transported from the suspensor and the tube cells to the embryonal mass. (D) Fully matured cotyledonary embryos are formed after 5–6 weeks on maturation medium. (E) Treatment with NPA blocks the polar auxin transport to the embryonal mass, leading to an IAA accumulation in the suspensor cells, tube cells and perhaps also in the cells of the embryonal mass most adjacent to the tube cells. (F) Embryos with supernumerary suspensor cells are formed if polar auxin transport is inhibited only during the earliest stages of suspensor differentiation. (G) Embryos with meristematic cells in the suspensor are formed if polar auxin transport is inhibited during both differentiation and elongation of the suspensor. We assume that these abnormalities abort further development and maturation of viable embryos. em, embryonal mass; s, suspensor; tc, tube cells. Green arrows indicate polar auxin transport, T indicates blocked polar auxin transport, green shadings indicate auxin accumulation.We recently showed that in embryogenic cultures of Norway spruce treated with the polar auxin transport inhibitor NPA, the number of cells undergoing PCD decreases. As a consequence the balance between the number of cells in the embryonal mass and the number of cells in the suspensor develop abnormally, and concomitantly the endogenous free IAA content increases almost two-fold.⁸In order to visualise the IAA accumulation within the embryos we used a -318 bp deletion of the auxin-responsive IAA4/5 promoter from Pisum sativum (pea), previously characterized by Oeller et al.,⁹ and Ballas et al.,¹⁰ fused to the GUS reporter gene.¹¹ In tobacco (Nicotiana tabacum) the promoter is expressed in rapidly elongating hypocotyls,¹² (our unpublished observations) and strong induction by auxin is clear in elongating zones of both roots and hypocotyls in transgenic pIAA4/5-GUS Arabidopsis plants.¹¹ However, to our knowledge, expression of IAA4/5 has not been reported in embryonal shoot apical meristems. Hence, the pIAA4/5-GUS may preferentially be used as a biosensor of auxin activity in non-meristematic cells during spruce embryo development. During normal somatic embryo development in spruce, pIAA4/5-GUS activity is detected in PEMs, tube cells and suspensor cells, but not in the embryonal mass. Early embryos of Norway spruce that are treated with NPA show increased pIAA4/5-GUS activity in tube cells and suspensor cells (unpublished), well in line with the increment of free IAA levels.Our results indicate that IAA under normal conditions is transported from the suspensor cells to the cells in the embryonal mass (Fig. 1B and C). NPA-treatment blocks this polar transport of endogenous IAA, which results in an accumulation of IAA and increased pIAA4/5-GUS activity in the suspensor cells, the tube cells, and perhaps also in the cells of the embryonal mass most adjacent to the tube cells (Fig. 1F and G). Blocked polar auxin transport during early differentiation of the suspensor stimulates abnormal cell divisions of the meristematic cells most adjacent to the tube cells or perhaps even of the tube cells themselves. Consequently, embryos with supernumerary tube and suspensor cells are formed (Fig. 1F). If the polar auxin transport is blocked for a longer time, i.e., during both differentiation and elongation of the suspensor, the auxin accumulation leads to maintenance of meristematic fate and a failure to undergo PCD (Fig. 1G).It has been proposed that the fate of the suspensor cells is regulated by signals from the embryo proper which impede developmental potential and initiate PCD.¹³ In accordance, we assume that the abnormal embryo morphologies formed after NPA-treatment may result from adverse inhibitory signals from the embryonal mass.     

The role of auxins in somatic embryogenesis of <Emphasis Type="Italic">Abies alba</Emphasis>

The somatic embryogenesis of conifers is a process susceptible to exogenous phytohormonal treatments. We report the effects of the synthetic auxin 2,4-dichlorophenoxyacetic acid (2,4-D) and the auxin inhibitor p-chlorophenoxyisobutyric acid (PCIB) on the endogenous level of the auxin indole-3-acetic acid (IAA) and on the anatomical composition of early somatic embryos of Abies alba (European silver fir). The embryogenic suspensor mass (ESM) of Abies alba proliferated on a medium supplemented by 2,4-D as well as on an auxin-free medium. The endogenous level of IAA was significantly higher in the ESM cultivated on a medium supplemented by 2,4-D. The decrease in the endogenous level of IAA in the first week of maturation is one of the most important stimuli responsible for the subsequent development of embryos. However, suppression of IAA synthesis by an auxin inhibitor did not stimulate the development of embryos. The maturation of somatic embryos from the globular to the cotyledonary stage occurs when the concentration of endogenous auxin in the ESM (including the embryos) increases. Early somatic embryos proliferating on a medium supplemented by auxin had an increased probability of maturing successfully. Exogenous auxin treatment during maturation did not compensate for the auxin deficiency during proliferation.     

Developmental anatomy and ultrastructure of early somatic embryos in European black pine (Pinus nigra Arn.)

Summary Embryogenic callus cultures of European black pine (Pinus nigra Arn.) were established on megagametophytes containing zygotic embryos in early developmental stage. In addition to many elongated cells and disorganized growing clumps they contained early somatic embryos at various stages of development. At all stages of embryogenesis the embryos were organized as bipolar structures. Cell pairs composed of one isodiametric cell with dense cytoplasm and a second large vacuolated cell were the simplest bipolar system. The vacuolated cell underwent senescence. The cytoplasm-rich cell and its derivates divided transversally, resulting in several cytoplasmic cells arranged in row. An early embryonal cylindrical mass was formed by longitudinal division of the cells in a filament. Proximally localized cells in the early embryonal mass became vacuolized and elongated gradually giving rise to the secondary suspensor. Distal cells remained cytoplasmic in character and formed an embryonal mass along the axis of long early somatic embryos. Differences in the proportion of organelles and heterochromatin clumps, thickness of cell walls and number of plasmodesmata between cells at various stages of early somatic embryogenesis were described.     

Handling culture medium composition for optimizing plant cell suspension culture in shake flasks

Douglas-fir is a conifer species of major economic importance worldwide, including Western Europe and New Zealand. Herein we describe some characterization and significant refinement of somatic embryogenesis in Douglas-fir, with focus on maturation. The most typical structures observed in the embryonal masses were large polyembryogenic centres (up to 800–1500 µm) with a broad meristem, creating a compact cell “package” with suspensor cells. Singulated somatic embryos composed of both a embryonal head (300–400 µm) and long, tightly arranged suspensor were also frequent. Embryo development was enhanced following embryonal mass dispersion on filter paper discs at low density (50–100 mg fresh mass). Moreover, increasing gellan gum concentration in maturation medium (up to 10 g L^?1) improved both the quantity and quality of cotyledonary somatic embryos (SEs), which were subsequently able to germinate and develop into plantlets at high frequency. Embryogenic yield was highly variable among the seven embryogenic lines tested (27–1544 SE g^?1 fresh mass). Interestingly secondary somatic embryogenesis could be induced from cotyledonary SEs of both low- and highly-productive lines with some useful practical outcomes: secondary lines from low-performance lines (30–478 SE g^?1 fresh mass) displayed significantly higher embryogenic yield (148–1343 SE g^?1 fresh mass). In our best conditions, the total protein content in cotyledonary SEs increased significantly with maturation duration (up to 150 µg mg^?1 fresh mass after 7 weeks) but remained below that of mature zygotic embryos (300 µg mg^?1). The protein pattern was similar in both somatic and zygotic embryos, with major storage proteins identified as 7S-vicilin- and legumin-like proteins.     

Effects of carbohydrate source, polyethylene glycol and gellan gum concentration on embryonal-suspensor mass (ESM) proliferation and maturation of maritime pine somatic embryos

Summary The influence of carbon sources and polyethylene glycol combined with 0.45 and 0.9% (w/v) of gellan gum on the maturation of maritime pine somatic embryos was tested. The effect of the carbon source and polyethylene glycol varied widely between lines. One out of the five lines tested showed a striking response to polyethylene glycol (PEG) treatment; the addition of this osmoticum limited the embryonal-suspensor mass (ESM) proliferation while it enhanced the maturation rate. Conversely, the ESM proliferation was stimulated by PEG in the other lines without subsequent improvement of the maturation rate. The use of a high concentration of gellan gum (0.9%) improved the maturation of the five ESM lines. It was concluded that the most efficient culture medium to recover cotyledonary embryos from all lines is one supplemented with sucrose at 6% (w/v) and gellan gum at 0.9% (w/v) without PEG. The determining factor in the maturation of maritime pine somatic embryos is the genotype and/or the quality of ESM. The possible relationship between maturation performances and ESM morphology, particularly the suspensor organization, is discussed.     

In vitro plant regeneration from immature zygotic embryos and repetitive somatic embryogenesis in kohlrabi (Brassica oleracea var. gongylodes)

A simple and efficient protocol for direct somatic embryogenesis and plant regeneration of kohlrabi (Brassica oleracea var. gongylodes) was developed. Somatic embryos were induced from immature zygotic embryos at different developmental stages cultured on Murashige and Skoog medium supplemented with 0, 0.5, 1.0, or 1.5 mg/l 2,4-dichlorophenoxyacetic acid. Zygotic embryos at the early cotyledonary stage, which were cultured for 4 wk on plant growth regulator-free (PGR-free) medium, displayed the highest percentage of somatic embryogenesis (80.7%). Embryogenic tissue could be subcultured on the same medium for over 1 yr. Embryogenic lines derived from early cotyledonary stage zygotic embryos displayed the highest intensity of secondary embryogenesis (highest mean number of new somatic embryos per responsive somatic embryo explant). Histological analyses confirmed the direct origin of the secondary somatic embryos. Prolonged culturing of embryogenic tissue on PGR-free medium led to somatic embryo development into plantlets that were successfully acclimated in the greenhouse with a survival rate of 72.5%. Flow cytometry analysis showed no ploidy variation in 96.7% of the acclimated plants.     

Mitochondrial heat-shock cognate protein 70 contributes to auxin-mediated embryo development

In Arabidopsis thaliana, mitochondrial-localized heat-shock cognate protein 70-1 (mtHSC70-1) plays an important role in vegetativegrowth. However, whether mtHSC70-1 affects reproductive growth remains unknown. Here, we found that the mtHSC70-1 gene was expressed in the provascular cells of the embryo proper from the early heart stage onward during embryogenesis. Phenotypic analyses of mthsc70-1 mutants revealed that mtHSC70 deficiency leads to defective embryo development and that this effect is mediated by auxin. In addition to a dwarf phenotype, the mthsc70-1 mutant displayed defects in flower morphology, anther development, and embryogenesis. At early developmental stages, the mthsc70-1 embryos exhibited abnormal cell divisions in both embryo proper and suspensor cells. From heart stage onward, they displayed an abnormal shape such as with no or very small cotyledon protrusions, had aberrant number of cotyledons, or were twisted. These embryo defects were associated with reduced or ectopic expression of auxin responsive reporter DR5_rev:GFP. Consistently, the expression of auxin biosynthesis and polar auxin transport genes were markedly altered in mthsc70-1. On the other hand, mitochondrial retrograde regulation (MRR) was enhanced in mthsc70-1. Treatment of wild-type plants with an inhibitor that activates mitochondrial retrograde signaling reduced the expression level of auxin biosynthesis and polar auxin transport genes and induced phenotypes similar to those of mthsc70-1. Taken together, our data reveal that loss of function of mtHSC70-1 induces MRR, which inhibits auxin biosynthesis and polar auxin transport, leading to abnormal auxin gradients and defective embryo development.

mtHSC70-1 dysfunction induces mitochondrial retrograde regulation, which inhibits auxin biosynthesis and polar auxin transport, leading to abnormal auxin gradients and defective embryo development.     

Somatic embryogenesis of safflower: influence of auxin and ontogeny of somatic embryos

Influence of auxin type and concentration on somatic embryogenesis from cotyledonary explants of safflower was investigated. Embryogenic frequency as well as number of somatic embryos was dependent on auxin type and concentration. NAA at 10.74 M (2 mg l^–1) was optimum for high frequency of somatic embryos, whereas IAA provided the maximum number of somatic embryos per responding culture. Somatic embryo development was asynchronous and strongly affected by auxin type and concentration. Maximum numbers of well developed somatic embryos at the cotyledonary stage were obtained with 5.37 M (1 mg l^–1 ) NAA + 2.22 M (0.5 mgl ^–1) BA. Histological studies confirmed the unicellular origin of somatic embryos from the adaxial epidermis of the cotyledon. Broad base attachment of somatic embryos to the epidermis indicated the absence of a suspensor.     

Inhibited polar auxin transport results in aberrant embryo development in Norway spruce

Current hypotheses concerning the role of polar auxin transport in embryo development are entirely based on studies of angiosperms, while little is known about how auxin regulates pattern formation in gymnosperms. In this study, different developmental stages of somatic embryos of Norway spruce (Picea abies) were treated with the polar auxin transport inhibitor 1-N-naphtylphthalamic acid (NPA). Effects of the treatments on auxin content, embryo differentiation and programmed cell death (PCD) were analysed. During early embryo development, NPA-treatment led to increased indole-3-acetic acid (IAA) content, abnormal cell divisions and decreased PCD, resulting in aberrant development of embryonal tube cells and suspensors. Mature embryos that had been treated with NPA showed both apical and basal abnormalities. Typically the embryos had abnormal cotyledon formation and irregular cell divisions in the area of the root meristem. Our results show that polar auxin transport is essential for the correct patterning of both apical and basal parts of conifer embryos throughout the whole developmental process. Furthermore, the aberrant morhologies of NPA-treated spruce embryos are comparable with several auxin response and transport mutants in Arabidopsis. This suggests that the role of polar auxin transport is conserved between angiosperms and gymnosperms.     

An expanded role for the TWN1 gene in embryogenesis: defects in cotyledon pattern and morphology in the twn1 mutant of Arabidopsis (Brassicaceae)

The suspensor is a specialized basal structure that differentiates early in plant embryogenesis to support development of the embryo proper. Suspensor differentiation in Arabidopsis is maintained in part by the TWIN1 (TWN1) gene, which suppresses embryogenic development in suspensor cells: twn1 mutants produce supernumerary embryos via suspensor transformation. To better understand mechanisms of suspensor development and further investigate the function of TWN1, we have characterized late-embryo and post-embryonic development in the twn1 mutant, using seedling culture, microscopy, and genetics. We report here that the twn1 mutation disrupts cotyledon number, arrangement, and morphology and occasionally causes partial conversion of cotyledons into leaves. These defects are not a consequence of suspensor transformation. Thus, in addition to its basal role in suspensor differentiation, TWN1 influences apical pattern and morphology in the embryo proper. To determine whether other genes can similarly affect both suspensor and cotyledon development, we looked for twinning in Arabidopsis mutants previously identified by their abnormal cotyledon phenotypes. One such mutant, amp1, produced a low frequency of twin embryos by suspensor transformation. Our results suggest that mechanisms that maintain suspensor identity also function later in development to influence organ formation at the embryonic shoot apex. We propose that TWN1 functions in cell communication pathways that convey local positional information in both the apical and basal regions of the Arabidopsis embryo.     

Expression of a plastid-localized sugar transporter in the suspensor is critical to embryogenesis

Plant growth and development rely on sugar transport between source and sink cells and between different organelles. The plastid-localized sugar transporter GLUCOSE-6-PHOSPHATE TRANSLOCATER1 (GPT1) is an essential gene in Arabidopsis (Arabidopsis thaliana). Using a partially rescued gpt1 mutant and cell-specific RNAi suppression of GPT1, we demonstrated that GPT1 is essential to the function of the embryo suspensor and the development of the embryo. GPT1 showed a dynamic expression/accumulation pattern during embryogenesis. Inhibition of GPT1 accumulation via RNAi using a suspensor-specific promoter resulted in embryos and seedlings with defects similar to auxin mutants. Loss of function of GPT1 in the suspensor also led to abnormal/ectopic cell division in the lower part of the suspensor, which gave rise to an ectopic embryo, resulting in twin embryos in some seeds. Furthermore, loss of function of GPT1 resulted in vacuolar localization of PIN-FORMED1 (PIN1) and altered DR5 auxin activity. Proper localization of PIN1 on the plasma membrane is essential to polar auxin transport and distribution, a key determinant of pattern formation during embryogenesis. Our findings suggest that the function of GPT1 in the embryo suspensor is linked to sugar and/or hormone distribution between the embryo proper and the maternal tissues, and is important for maintenance of suspensor identity and function during embryogenesis.

Specific expression of a sugar transporter that localizes to the plastids of cells in the embryo suspensor affects auxin activity and embryo development.     

湿地松体细胞胚胎发生和植株再生

以湿地松的未成熟合子胚为外植体,在附加８ｍｇ／Ｌ,２,４－Ｄ和４ｍｇ／Ｌ ＢＡ的ＬＰ培养基上诱导出胚性愈伤组织。在含１ｍｇ／Ｌ,２,４－Ｄ和０．５ｍｇ／Ｌ ＢＡ的培养基上保持并增殖。提高培养基的渗透压后,愈伤组织内大量的胚性胚柄细胞团和早期原胚。     

Re-organisation of the cytoskeleton during developmental programmed cell death in Picea abies embryos

Cell and tissue patterning in plant embryo development is well documented. Moreover, it has recently been shown that successful embryogenesis is reliant on programmed cell death (PCD). The cytoskeleton governs cell morphogenesis. However, surprisingly little is known about the role of the cytoskeleton in plant embryogenesis and associated PCD. We have used the gymnosperm, Picea abies, somatic embryogenesis model system to address this question. Formation of the apical-basal embryonic pattern in P. abies proceeds through the establishment of three major cell types: the meristematic cells of the embryonal mass on one pole and the terminally differentiated suspensor cells on the other, separated by the embryonal tube cells. The organisation of microtubules and F-actin changes successively from the embryonal mass towards the distal end of the embryo suspensor. The microtubule arrays appear normal in the embryonal mass cells, but the microtubule network is partially disorganised in the embryonal tube cells and the microtubules disrupted in the suspensor cells. In the same embryos, the microtubule-associated protein, MAP-65, is bound only to organised microtubules. In contrast, in a developmentally arrested cell line, which is incapable of normal embryonic pattern formation, MAP-65 does not bind the cortical microtubules and we suggest that this is a criterion for proembryogenic masses (PEMs) to passage into early embryogeny. In embryos, the organisation of F-actin gradually changes from a fine network in the embryonal mass cells to thick cables in the suspensor cells in which the microtubule network is completely degraded. F-actin de-polymerisation drugs abolish normal embryonic pattern formation and associated PCD in the suspensor, strongly suggesting that the actin network is vital in this PCD pathway.     

低温预处理对水曲柳体细胞胚胎发生的影响

用4℃低温预处理未成熟的水曲柳种子0-30d,取出种子内的合子胚为外植体诱导体胚发生,研究低温预处理影响体胚发生的结果表明：低温预处理过的外植体其体胚发生总数和子叶胚发生数均低于未作低温预处理的;随着预处理时间的延长,畸形胚发生数和发生比率与总的体胚发生数和发生率的变化趋势基本相同;处理20d的正常胚发生数和发生比率的绝对数虽然很低,但远高于不作低温预处理的。说明4℃低温预处理对水曲柳体胚发生没有促进作用,对畸形胚的发生也不能控制,总的来讲,适当的低温处理有一定的改善正常体胚发生的潜力。