Mitochondrial regulation of flower development.

Flower development in plants depends not only on a set of nuclear genes but also on the coordinate action of the mitochondrion. Certain mitochondrial genomes in combination with certain nuclear genomes lead to the expression of cytoplasmic male-sterility (CMS). Both mitochondrial genes that determine male-sterility and nuclear Restorer-of-fertility genes that suppress the male-sterile phenotype have been cloned. Lately, the interactions between mitochondrial and nuclear genes through retrograde signalling in CMS-systems have been dissected. Of special interest are the altered expression patterns of floral homeotic genes in certain CMS-systems. Here, we review the mitochondrial influence on flower development and give examples from CMS-systems developed in Brassica, Daucus carota, Nicotiana tabacum and Triticum aestivum.

Mitochondrial genotypes with variable parts of Arabidopsis thaliana DNA affect development in Brassica napus lines.

Phenotypic, genetic and molecular studies were made of Brassica napus lines with mitochondrial genomes consisting of DNA from both B. napus and Arabidopsis thaliana. The lines were isogenic regarding the nuclear and plastid genomes. Out of 21 lines, 10 were male-sterile, 3 semi-sterile and 8 male-fertile. Screening of the mitochondrial genomes with a dense set of A. thaliana specific markers showed that most lines contained large but variable portions of A. thaliana mitochondrial DNA. Several of the A. thaliana sequences in the mitochondrial genomes lead to the accumulation of novel transcripts. In addition, the restorer line showed different ability to restore male-fertility in the male-sterile lines. These results indicate that CMS is caused by several mitochondrial loci or combinations of loci. Beside petal and stamen morphology, growth rate and adenylate content varied among the lines. Furthermore, we found that the mitochondrial background had a distinct influence on nuclear gene expression. A clear example is the reduced expression of the two B-genes APETALA3 and PISTILATA in the male-sterile lines. From the studies made comparing the mitochondrial loci and the observed phenotypic alterations, our interpretation is that different loci in the mitochondrial genome influence nuclear gene expression via several retrograde signalling pathways.

Microarray analysis reveals altered expression of a large number of nuclear genes in developing cytoplasmic male sterile Brassica napus flowers.

To gain new insights into the mechanism underlying cytoplasmic male sterility (CMS), we compared the nuclear gene expression profiles of flowers of a Brassica napus CMS line with that of the fertile B. napus maintainer line using Arabidopsis thaliana flower-specific cDNA microarrays. The CMS line used has a B. napus nuclear genome, but has a rearranged mitochondrial (mt) genome consisting of both B. napus and A. thaliana DNA. Gene expression profiling revealed that a large number of genes differed in expression between the two lines. For example, nuclear genes coding for proteins that are involved in protein import into organelles, genes expressed in stamens and pollen, as well as genes implicated in either cell-wall remodeling or architecture, were repressed in the CMS line compared with B. napus. These results show that the mt genome of the CMS line strongly influences nuclear gene expression, and thus reveal the importance of retrograde signalling between the mitochondria and the nucleus. Furthermore, flowers of the CMS line are characterized by a replacement of stamens with carpelloid organs, and thus partially resemble the APETALA3 (AP3) and PISTILLATA (PI) mutants. In accordance with this phenotype, AP3 expression was downregulated in the stamens, shortly before these organs developed carpelloid characteristics, even though it was initiated correctly. Repression of PI succeeded that of AP3 and might be a consequence of a loss of AP3 activity. These results suggest that AP3 expression in stamens depends on proper mt function and a correct nuclear-mt interaction, and that mt alterations cause the male sterility phenotype of the CMS line.

Direct regulation of the floral homeotic APETALA1 gene by APETALA3 and PISTILLATA in Arabidopsis.

The floral homeotic gene APETALA1 (AP1) specifies floral meristem identity and sepal and petal identity in Arabidopsis. Consistent with its multiple roles during floral development, AP1 is initially expressed throughout the floral meristem, and later its expression becomes restricted to sepal and petal primordia. Using chromatin immunoprecipitation, we show that the floral homeotic PISTILLATA (PI) protein, required for petal and stamen development, has the ability to bind directly to the promoter region of AP1. In support of the hypothesis that PI, and its interacting partner APETALA3 (AP3), regulates the transcription of AP1, we show that AP1 transcript levels are elevated in strong ap3-3 mutant plants. Kinetic studies, using transgenic Arabidopsis plants in which both AP3 and PI are under post-translational control, show that AP1 transcript levels are down regulated within 2 h of AP3/PI activation. This implies that the reduction in AP1 transcripts is an early event in the cascade following AP3/PI induction and provides independent support for the hypothesis that AP1 is a direct target of the AP3/PI heterodimer. Together these results suggest a model whereby AP3/PI directly acts, in combination with other factors, to restrict the expression of AP1 during early stages of floral development.

Expression levels of meristem identity and homeotic genes are modified by nuclear-mitochondrial interactions in alloplasmic male-sterile lines of Brassica napus.

Homeotic conversions of anthers were found in cytoplasmic male sterile (CMS) plants of Brassica napus derived from somatic hybrids of B. napus and Arabidopsis thaliana. CMS line flowers displayed petals reduced in size and width and stamens replaced by carpelloid structures. In order to investigate when these developmental aberrations appeared, flower development was analysed histologically, ultrastructurally and molecularly. Disorganized cell divisions were detected in the floral meristems of the CMS lines at stage 4. As CMS is associated with mitochondrial aberrations, ultrastructural analysis of the mitochondria in the floral meristems was performed. Two mitochondrial populations were found in the CMS lines. One type had disrupted cristae, while the other resembled mitochondria typical of B. napus. Furthermore, expression patterns of genes expressed in particular floral whorls were determined. In spite of the aberrant development of the third whorl organs, BnAP3 was expressed as in B. napus during the first six stages of development. However, the levels of BnPI were reduced. At later developmental stages, the expression of both BnAP3 and BnPI was strongly reduced. Interestingly the expression levels of genes responsible for AP3 and PI activation such as LFY, UFO and ASK1 were higher in the CMS lines, which indicates that activation of B-genes in the CMS lines does not occur as in B. napus. Disrupted and dysfunctional mitochondria seem to be one of the first aberrations manifested in CMS which result in a retrograde influence of the expression levels of genes responsible for the second and third whorl organ differentiation.

Alloplasmic effects on mitochondrial transcriptional activity and RNA turnover result in accumulated transcripts of Arabidopsis orfs in cytoplasmic male-sterile Brassica napus.

Mitochondrial transcription was investigated in a cytoplasmic male-sterile (CMS) Brassica napus line with rearranged mitochondrial (mt) DNA mostly inherited from Arabidopsis thaliana. The transcript patterns were compared with the corresponding male-fertile progenitors, B. napus and A. thaliana, and a fertility-restored line. Transcriptional activities, gene stoichiometry and transcript steady-state levels were analysed for all protein and rRNA coding genes and for several orfs present in the A. thaliana mitochondrial genome. The transcriptional activities were highly variable when comparing the parental species, while the CMS and restored lines displayed similar activities. For several ribosomal protein genes transcriptional activity was reduced while it was increased for orf139 in comparison with the parental species. The differences in transcriptional activity observed could be related to differences in relative promoter strength, as gene stoichiometry between lines was very limited. Transcript steady-state levels were more homogenous than the transcriptional activities demonstrating RNA turnover as a compensating mechanism. In the CMS line higher transcript abundance and novel transcript patterns in comparison with the parental lines were found for several genes. Of those, the transcripts for orf139, orf240a and orf294 were less abundant in the fertility-restored line. These putative CMS-associated transcripts were mapped by cRT-PCR. In conclusion we show that (mt) DNA from A. thaliana was non-correctly transcribed and processed/degraded in the B. napus nuclear background. Furthermore, the introgressed nuclear A. thaliana DNA in the fertility-restored line contributes to a more rapid degradation of transcripts accumulated from A. thaliana derived orfs in the CMS line.

Modified sucrose, starch, and ATP levels in two alloplasmic male-sterile lines of B. napus.

Alloplasmic lines of Brassica napus with rearranged Arabidopsis thaliana mitochondrial DNA are male sterile and vegetatively altered compared with B. napus cv. Hanna. The CMS lines contain pure nuclear and plastid genomes from B. napus. Cross-sections of leaves revealed elevated starch accumulation and a higher number of chloroplasts per cell area in CMS plants compared with B. napus. The increase in chloroplast density was found to be the result of the smaller mesophyll cells. Sucrose concentration in the leaves of the CMS lines was reduced both in green leaves as well as in leaves from 2 d-etiolated plants. Flower meristem, flower buds, and leaves from green and 2 d-etiolated plants were analysed for ATP and ADP contents. All CMS plant tissues, except for green leaves, possessed lower ATP levels than B. napus. The results indicate that the reduced availability of energy, i.e. ATP and sucrose in the CMS plants, limits plant growth. This is supported by the reduced levels of two D-type cyclin transcripts and the reduced capacity of the CMS plants to recover after etiolation.

Restoration of stamen development and production of functional pollen in an alloplasmic CMS tobacco line by ectopic expression of the Arabidopsis thaliana SUPERMAN gene.

The alloplasmic male-sterile tobacco line Nta(rep)S, combining the nucleus of Nicotiana tabacum with the cytoplasm of Nicotiana repanda, exhibits cadastral-type anomalies due to a fusion of several stamens with the pistil. These anomalies share similarities with Arabidopsis superman mutants. SUPERMAN (SUP) is a cadastral gene controlling the boundary between whorls 3 (androecium) and 4 (gynoecium). Thus we hypothesized that the expression of the tobacco SUP orthologue might be impaired in the alloplasmic Nta(rep)S line, and that the deficiency could be complemented by the Arabidopsis SUP gene. Here we show that the ectopic expression of SUP in the alloplasmic male-sterile tobacco line Nta(rep)S significantly increases the frequency of flowers possessing free stamens, inducing the recovery of a proper structure for whorls 3 and 4. Furthermore, flowers of transgenic plants show a significant improvement of the morphology of stamens, and more particularly of the anthers, which are able to produce few but functional pollen. The data show that ectopic expression of Arabidopsis SUP reactivates the regulatory cascade of anther development. The plausible causes of the developmental defects of anthers in the alloplasmic male-sterile tobacco line are discussed in relation to the model of regulation of the Arabidopsis SUP gene.

Bioengineering of a phytoremediation plant by means of somatic hybridization.

Phytoremediation is a technology that exploits a plant's ability to remove contaminants from the environment or render toxic compounds harmless. An efficient metal phytoremediating plant must combine high biomass production and established cultivation methods with high tolerance to a specific contaminant and ability for root uptake, translocation, and compartmentalization of contaminants in the above-ground biomass. Symmetric and asymmetric somatic hybridizations were used to introduce toxic metal-resistant traits from Thlaspi caerulescens into Brassica juncea. B. juncea hypocotyl protoplasts were fused with T. caerulescens mesophyll protoplasts. The hypocotyl protoplasts of B. juncea were stained with CFDA before fusion and thus fluoresced green under UV, whereas the mesophyll protoplasts of T. caerulescens had red autofluorescense. Heteroplasmic fusion products were identified and selected by flow cytometry and cell sorting. All putative hybrids grown in the greenhouse had morphological characteristics of B. juncea. A Thlaspi-specific repetitive sequence was hybridized to total DNA of plants, including the parental species. All plants from both symmetric and asymmetric fusions showed Thlaspi-specific hybridization patterns while B. juncea did not exhibit any hybridization signal. Hybrid plants, produced by asymmetric somatic hybridization between the two species, demonstrated high metal accumulation potential, tolerance to toxic metals, and good biomass production.

Electroporation of rapeseed protoplasts - transient and stable transformation.

Protoplasts of Brassica napus hypocotyls were transfected using electroporation. Parameters such as discharge potential, protoplast density and buffer constituents were tested to determine the most suitable conditions for gene transfer. To monitor the introduction of DNA into protoplasts a plasmid containing the ß-glucuronidase (EC 3.2.1.31), and the neomycin phospotransferase (EC 2.7.1.95) genes was used. By using this construct, expression of a screenable marker gene for transient expression analysis as well as an antibiotic resistance marker gene for selection of stable transformants were obtained. Refined electroporation conditions resulted in a frequency of 0.1% transiently transformed protoplasts. Microcalluses were cultured under selective conditions in a bead-type culture system. Resistant callus, with an absolute transformation frequency of 4.9 × 10-5 and a relative transformation frequency of 0.3% could be achieved. X-ray irradiation of newly electroporated protoplasts did not enhance absolute transformation frequencies. From some of the resistant calluses, transgenic plants could be regenerated which were characterized by molecular analysis.