Jan Custers

Ectopic Expression of BABY BOOM Triggers a Conversion from Vegetative to Embryonic Growth

The molecular mechanisms underlying the initiation and maintenance of the embryonic pathway in plants are largely unknown. To obtain more insight into these processes, we used subtractive hybridization to identify genes that are upregulated during the in vitro induction of embryo development from immature pollen grains of Brassica napus (microspore embryogenesis). One of the genes identified, BABY BOOM (BBM), shows similarity to the AP2/ERF family of transcription factors and is expressed preferentially in developing embryos and seeds. Ectopic expression of BBM in Arabidopsis and Brassica led to the spontaneous formation of somatic embryos and cotyledon-like structures on seedlings. Ectopic BBM expression induced additional pleiotropic phenotypes, including neoplastic growth, hormone-free regeneration of explants, and alterations in leaf and flower morphology. The expression pattern of BBM in developing seeds combined with the BBM overexpression phenotype suggests a role for this gene in promoting cell proliferation and morphogenesis during embryogenesis.

Temperature controls both gametophytic and sporophytic development in microspore cultures of Brassica napus

SummaryTemperature controls the developmental fate of isolated Brassica napus microspores in vitro. Culture at 32.5°C leads to sporophytic development and the formation of embryos. Here we show that culture at 17.5°C leads to gametophytic development, and the formation of pollen-like structures at high frequencies (up to 80% after 7 days in culture). Early stages of both developmental pathways are observed in culture at 25.0°C, and embryos are produced at low frequencies (0.7%) at that temperature. Culturing B. napus microspores at 32.5°C versus 17.5°C brings the switch from gametophytic to sporophytic development under simple experimental control and provides a convenient tool for investigating the cellular and molecular mechanisms controlling this developmental switch.

Heterologous expression of the BABY BOOM AP2/ERF transcription factor enhances the regeneration capacity of tobacco (Nicotiana tabacum L.)

Gain-of-function studies have shown that ectopic expression of the BABY BOOM (BBM) AP2/ERF domain transcription factor is sufficient to induce spontaneous somatic embryogenesis in Arabidopsis (Arabidopsis thaliana (L.) Heynh) and Brassica napus (B. napus L.) seedlings. Here we examined the effect of ectopic BBM expression on the development and regenerative capacity of tobacco (Nicotiana tabacum L.) through heterologous expression of Arabidopsis and B. napus BBM genes. 35S::BBM tobacco lines exhibited a number of the phenotypes previously observed in 35S::BBM Arabidopsis and B. napus transgenics, including callus formation, leaf rumpling, and sterility, but they did not undergo spontaneous somatic embryogenesis. 35S::BBM plants with severe ectopic expression phenotypes could not be assessed for enhanced regeneration at the seedling stage due to complete male and female sterility of the primary transformants, therefore fertile BBM ectopic expression lines with strong misexpression phenotypes were generated by expressing a steroid-inducible, post-translationally controlled BBM fusion protein (BBM:GR) under the control of a 35S promoter. These lines exhibited spontaneous shoot and root formation, while somatic embryogenesis could be induced from in-vitro germinated seedling hypocotyls cultured on media supplemented with cytokinin. Together these results suggest that ectopic BBM expression in transgenic tobacco also activates cell proliferation pathways, but differences exist between Arabidopsis/B. napus and N. tabacum with respect to their competence to respond to the BBM signalling molecule.

Combined Transcriptome and Proteome Analysis Identifies Pathways and Markers Associated with the Establishment of Rapeseed Microspore-Derived Embryo Development

Microspore-derived embryo (MDE) cultures are used as a model system to study plant cell totipotency and as an in vitro system to study embryo development. We characterized and compared the transcriptome and proteome of rapeseed (Brassica napus) MDEs from the few-celled stage to the globular/heart stage using two MDE culture systems: conventional cultures in which MDEs initially develop as unorganized clusters that usually lack a suspensor, and a novel suspensor-bearing embryo culture system in which the embryo proper originates from the distal cell of a suspensor-like structure and undergoes the same ordered cell divisions as the zygotic embryo. Improved histodifferentiation of suspensor-bearing MDEs suggests a new role for the suspensor in driving embryo cell identity and patterning. An MDE culture cDNA array and two-dimensional gel electrophoresis and protein sequencing were used to compile global and specific expression profiles for the two types of MDE cultures. Analysis of the identities of 220 candidate embryo markers, as well as the identities of 32 sequenced embryo up-regulated protein spots, indicate general roles for protein synthesis, glycolysis, and ascorbate metabolism in the establishment of MDE development. A collection of 135 robust markers for the transition to MDE development was identified, a number of which may be coregulated at the gene and protein expression level. Comparison of the expression profiles of preglobular-stage conventional MDEs and suspensor-bearing MDEs identified genes whose differential expression may reflect improved histodifferentiation of suspensor-bearing embryos. This collection of early embryo-expressed genes and proteins serves as a starting point for future marker development and gene function studies aimed at understanding the molecular regulation of cell totipotency and early embryo development in plants.

Quantitative trait loci for glucosinolate accumulation in Brassica rapa leaves

Glucosinolates and their breakdown products have been recognized for their effects on plant defense, human health, flavor and taste of cruciferous vegetables. Despite this importance, little is known about the regulation of the biosynthesis and degradation in Brassica rapa. Here, the identification of quantitative trait loci (QTL) for glucosinolate accumulation in B. rapa leaves in two novel segregating double haploid (DH) populations is reported: DH38, derived from a cross between yellow sarson R500 and pak choi variety HK Naibaicai; and DH30, from a cross between yellow sarson R500 and Kairyou Hakata, a Japanese vegetable turnip variety. An integrated map of 1068 cM with 10 linkage groups, assigned to the international agreed nomenclature, is developed based on the two individual DH maps with the common parent using amplified fragment length polymorphism (AFLP) and single sequence repeat (SSR) markers. Eight different glucosinolate compounds were detected in parents and F(1)s of the DH populations and found to segregate quantitatively in the DH populations. QTL analysis identified 16 loci controlling aliphatic glucosinolate accumulation, three loci controlling total indolic glucosinolate concentration and three loci regulating aromatic glucosinolate concentrations. Both comparative genomic analyses based on Arabidopsis-Brassica rapa synteny and mapping of candidate orthologous genes in B. rapa allowed the selection of genes involved in the glucosinolate biosynthesis pathway that may account for the identified QTL.

Analysis of microspore-specific promoters in transgenic tobacco

In order to modify the early stages of pollen development in a transgenic context microspore-specific promoters are required. We tested two putatively microspore-specific promoters, the Bp4 promoter from rapeseed and the NTM19 promoter from tobacco. Expression of the gus and barnase reporter genes under the control of these two promoters was studied in transgenic tobacco. Contrary to expectations, the Bp4 promoter became active only after the first pollen mitosis, and not in the microspores. The NTM19 promoter turned out to be highly microspore-specific and directed very high levels of gus expression to the unicellular microspores. The NTM19-barnase transgene caused cell-autonomous death at the mid-unicellular microspore stage, whereas Bp4-barnase induced cell ablation of early to mid-bicellular pollen. Both promoter-barnase transgenes did not affect the sporophyte and were inherited through the female germline. These results show that both the NTM19 and Bp4 promoters are expressed only in the male germline, and that the NTM19 promoter is an excellent tool to direct high levels of transgene expression exclusively to the microspores. This may have important biotechnological applications.

Regeneration of zygotic-like microspore-derived embryos suggests an important role for the suspensor in early embryo patterning

The inaccessibility of the zygote and proembryos of angiosperms within the surrounding maternal and filial tissues has hampered studies on early plant embryogenesis. Somatic and gametophytic embryo cultures are often used as alternative systems for molecular and biochemical studies on early embryogenesis, but are not widely used in developmental studies due to differences in the early cell division patterns with seed embryos. A new Brassica napus microspore embryo culture system, wherein embryogenesis highly mimics zygotic embryo development, is reported here. In this new system, the donor microspore first divides transversely to form a filamentous structure, from which the distal cell forms the embryo proper, while the lower part resembles the suspensor. In conventional microspore embryogenesis, the microspore divides randomly to form an embryonic mass that after a while establishes a protoderm and subsequently shows delayed histodifferentiation. In contrast, the embryo proper of filament-bearing microspore-derived embryos undergoes the same ordered pattern of cell division and early histodifferentiation as in the zygotic embryo. This observation suggests an important role for the suspensor in early zygotic embryo patterning and histodifferentiation. This is the first in vitro system wherein single differentiated cells in culture can efficiently regenerate embryos that are morphologically comparable to zygotic embryos. The system provides a powerful in vitro tool for studying the diverse developmental processes that take place during the early stages of plant embryogenesis.

Induction of microspore embryogenesis in Brassica napus L. is accompanied by specific changes in protein synthesis

Culture temperature determines the developmental fate of isolated microspores from Brassica napus L. At 18°C, tricellular pollen develops, whereas culture at 32°C for 8 h leads to the quantitative and synchronous induction of embryogenesis, and ultimately to the formation of embryos. We investigated the changes in protein synthesis that are associated with this 8-h inductive period by using in-situ [35S]methionine labeling, followed by two-dimensional (2-D) gel electrophoretic analysis of the radiolabeled proteins. Qualitative and quantitative computer analyses of 2-D [35S]methionine protein patterns showed six polypeptides specifically labeled under embryogenic culture conditions. Eighteen polypeptides incorporated [35S]methionine at a statistically significant higher rate under embryogenic culture conditions (32°C) than in the controls (18°C), whereas one protein was preferentially labeled under non-embryogenic culture conditions (18°C). These results indicate that only a limited number of proteins detectable in the 2-D gels of microspore extracts are associated with the early induction of embryogenesis. The reproducible identification of the differentially radiolabeled proteins in the 2-D gels allow the sequencing of representative peptides and the isolation of the corresponding cDNAs. This may lead to the identification and characterization of proteins associated with the very first stages of plant embryogenesis.

The 35S-CaMV promoter is silent during early embryogenesis but activated during nonembryogenic sporophytic development in microspore culture

SummaryThe cauliflower mosaic virus 35S (35S-CaMV) promoter, which is generally used as a constitutive promoter in plants, is known to be silent during microspore and pollen development. Here we analyzed whether the 35S-CaMV promoter fused to thegus (β-glucuronidase) gene can be used as a marker for early sporophytic development in embryogenic microspore cultures of tobacco andBrassica napus. In microspore culture ofB. napus, the 35S-CaMV promoter remained off from the start of embryogenic culture up to the mid-cotyledonary embryo stage. 35S-CaMV promoter activity was only present in those microspores that initiated sporophytic development, but failed to enter embryogenic development. Similar results were also obtained with shed-microspore cultures of tobacco, in which rapid, direct embryogenesis takes place. In isolated-microspore cultures, in which embryogenesis is delayed, an intermitting period of sporophytic development was observed, characterized by extensive 35S-CaMV promoter activity. Therefore, the 35S-CaMV promoter discriminates between two classes of sporophytic development: it is activated in microspores which change fate from gametophytic into (temporarily) nonembryogenic sporophytic development, whereas the promoter is silent in sporophytic microspores that enter embryogenic development directly. This mirrors our observation that the 35S-CaMV promoter is also silent in young zygotic embryos.

Molecular and biochemical events during the induction of microspore embryogenesis

The life cycle of higher plants alternates between a diploid sporophytic phase and a haploid gametophytic phase. The gametophytic generation begins after meiosis with two types of haploid gametophytes or spores: microspores, which develop into pollen grains within the anther (male gametogenesis), and megaspores, which form the embryo sac within the ovule (female gametogenesis). During male gametogenesis microspores undergo a precisely defined and often synchronous sequence of cell divisions that lead to the formation of highly specialized cells: a large vegetative cell and two sperm cells. Although this tightly controlled developmental pathway consists of only two cell divisions, under certain experimental conditions, immature male gametophytes can be induced to undergo an altered development leading to the production of haploid embryos. During this process, known as androgenesis or microspore embryogenesis, the male gametophyte develops directly into an embryo, without an intervening fertilization. In this review, several recent findings on microspore embryogenesis will be described. A central issue will be what triggers microspores or pollen to change their developmental fate to produce sporophytes. The emphasis will be on molecular events that occur during the initial stages of microspore embryogenesis. Two main questions that still remain to be answered are: what is the genetic basis for embryogenic potential, and how is embryogenic development induced?