Phylogeny and divergence of basal angiosperms inferred from<Emphasis Type="Italic"> APETALA3</Emphasis>- and<Emphasis Type="Italic"> PISTILLATA</Emphasis>-like MADS-box genes

The B-class MADS-box genes composed of APETALA3 (AP3) and PISTILLATA (PI) lineages play an important role in petal and stamen identity in previously studied flowering plants. We investigated the diversification of the AP3-like and PI-like MADS-box genes of eight species in five basal angiosperm families: Amborella trichopoda (Amborellaceae); Brasenia schreberi and Cabomba caroliniana (Cabombaceae); Euryale ferox, Nuphar japonicum, and Nymphaea tetragona (Nymphaeaceae); Illicium anisatum (Illiciaceae); and Kadsura japonica (Schisandraceae). Sequence analysis showed that a four amino acid deletion in the K domain, which was found in all previously reported angiosperm PI genes, exists in a PI homologue of Schisandraceae, but not in six PI homologues of the Amborellaceae, Cabombaceae, and Nymphaeaceae, suggesting that the Amborellaceae, Cabombaceae, and Nymphaeaceae are basalmost lineages in angiosperms. The results of molecular phylogenetic analyses were not inconsistent with this hypothesis. The AP3 and PI homologues from Amborella share a sequence of five amino acids in the 5 region of exon 7. Using the linearized tree and likelihood methods, the divergence time between the AP3 and PI lineages was estimated as somewhere between immediately after to several tens of millions of years after the split between angiosperms and extant gymnosperms. Estimates of the age of the most recent common ancestor of all extant angiosperms range from ~140–210 Ma, depending on the trees used and assumptions made.     

Analyses of the floral organ morphogenesis and the differentially expressed genes of an apetalous flower mutant in <Emphasis Type="Italic">Brassica napus</Emphasis>

The floral organ morphogenesis of the apetalous flower mutant Apet33-10 in Brassica napus was investigated and the result showed that all the floral organ morphogenesis was normal except that petal primordium was not observed during flower development. Eighteen genes were found to be down regulated in early floral buds (less than 200 μm in length) of Apet33-10 at the stage of floral organ initiation by means of suppressive subtraction hybridization (SSH) and RT-PCR. These genes were involved in petal identity, calcium iron signal transduction, mRNA processing, protein synthesis and degradation, construction of cytoskeleton, hydrogen transportation, nucleic acid binding, alkaloid biosynthesis and unknown function. Three overall coding region cDNAs of APETALA3 (AP3) gene, BnAP3-2, BnAP3-3 and BnAP3-4 were obtained by RT-PCR, respectively. Real-time quantitative PCR analysis showed that the expression ratio among BnAP3-2, BnAP3-3 and BnAP3-4 was 3.67:3.68:1 in early floral buds of wild type Pet33-10. The expression level of BnAP3-2, BnAP3-3 and BnAP3-4 in early floral buds of Apet33-10 was down-regulated to 36.6, 28.3 and 66.8% with the comparison of that of wild type, respectively, and the overall expression level of AP3 genes in apetalous mutant amounted to 45.0% of that in wild type. The difference in the expression level of each AP3 gene in stamen between apetalous and wild type lines was not significant. It is suggested that lower abundant expression of AP3 genes during the early flower development might be enough for stamen primordium initiation, but not enough for petal primordium initiation in the apetalous line Apet33-10. Y.T. Zhou and H.Y. Wang are committed as the first author.     

Ectopic over-expression of two apple <Emphasis Type="Italic">Flowering Locus T</Emphasis> homologues, <Emphasis Type="Italic">MdFT1</Emphasis> and <Emphasis Type="Italic">MdFT2</Emphasis>, reduces juvenile phase in <Emphasis Type="Italic">Arabidopsis</Emphasis>

To get insight into mechanism by which apple tree (Malus domestica Borkh.) regulates flowering, two apple flowering locus T (FT) homologues, MdFT1 and MdFT2, were isolated from the leaf cDNAs of cultivar Gala. The open reading frames (ORFs) of two MdFTs encoded 174 amino acids. The deduced amino acid sequence of MdFT1 and MdFT2 showed 94.3 % similarity to each other, while 72.6 and 76.0 % to AtFT protein, respectively. Semi-quantitative RT-PCR indicated their specific expression in leaves. Visualization of MdFT2-GFP fusion protein demonstrated its localization on membrane. Ectopic overexpression of either MdFT1 or MdFT2 in Arabidopsis significantly induced early flowering by activating the downstream flowering-related genes.     

Identification of candidate genes of QTLs for seed weight in <Emphasis Type="Italic">Brassica napus</Emphasis> through comparative mapping among <Emphasis Type="Italic">Arabidopsis</Emphasis> and <Emphasis Type="Italic">Brassica</Emphasis>species

Background

Map-based cloning of quantitative trait loci (QTLs) in polyploidy crop species remains a challenge due to the complexity of their genome structures. QTLs for seed weight in B. napus have been identified, but information on candidate genes for identified QTLs of this important trait is still rare.

Results

In this study, a whole genome genetic linkage map for B. napus was constructed using simple sequence repeat (SSR) markers that covered a genetic distance of 2,126.4 cM with an average distance of 5.36 cM between markers. A procedure was developed to establish colinearity of SSR loci on B. napus with its two progenitor diploid species B. rapa and B. oleracea through extensive bioinformatics analysis. With the aid of B. rapa and B. oleracea genome sequences, the 421 homologous colinear loci deduced from the SSR loci of B. napus were shown to correspond to 398 homologous loci in Arabidopsis thaliana. Through comparative mapping of Arabidopsis and the three Brassica species, 227 homologous genes for seed size/weight were mapped on the B. napus genetic map, establishing the genetic bases for the important agronomic trait in this amphidiploid species. Furthermore, 12 candidate genes underlying 8 QTLs for seed weight were identified, and a gene-specific marker for BnAP2 was developed through molecular cloning using the seed weight/size gene distribution map in B. napus.

Conclusions

Our study showed that it is feasible to identify candidate genes of QTLs using a SSR-based B. napus genetic map through comparative mapping among Arabidopsis and B. napus and its two progenitor species B. rapa and B. oleracea. Identification of candidate genes for seed weight in amphidiploid B. napus will accelerate the process of isolating the mapped QTLs for this important trait, and this approach may be useful for QTL identification of other traits of agronomic significance.

     

Intertribal somatic hybrids between <Emphasis Type="Italic">Brassica napus</Emphasis> and <Emphasis Type="Italic">Camelina sativa</Emphasis> with high linolenic acid content

Intertribal somatic hybrids of Brassica napus and Camelina sativa were developed by protoplast electrofusion. Hybrid identity of the regenerants was determined using flow cytometric analysis of nuclear DNA content and simple sequence repeat (SSR) marker analysis. Three hybrids exhibited specific bands for B. napus and C. sativa. These hybrids showed intermediate leaf, flower and seed morphology compared with the two parental species. The seeds of these three hybrids had a modified fatty acid profile, indicating higher level of linolenic and eicosanoic acids than those of B. napus. Our results suggest that somatic hybridization offers opportunities for transferring entire genomes between B. napus and C. sativa in improving rapeseed breeding.     

Evolution of nematode-resistant <Emphasis Type="Italic">Mi</Emphasis>-<Emphasis Type="Italic">1</Emphasis> gene homologs in three species of <Emphasis Type="Italic">Solanum</Emphasis>

Plants have evolved several defense mechanisms, including resistance genes. Resistance to the root-knot nematode Meloidogyne incognita has been found in wild plant species. The molecular basis for this resistance has been best studied in the wild tomato Solanum peruvianum and it is based on a single dominant gene, Mi-1.2, which is found in a cluster of seven genes. This nematode attacks fiercely several crops, including potatoes. The genomic arrangement, number of copies, function and evolution of Mi-1 homologs in potatoes remain unknown. In this study, we analyzed partial genome sequences of the cultivated potato species S. tuberosum and S. phureja and identified 59 Mi-1 homologs. Mi-1 homologs in S. tuberosum seem to be arranged in clusters and located on chromosome 6 of the potato genome. Previous studies have suggested that Mi-1 genes in tomato evolved rapidly by frequent sequence exchanges among gene copies within the same cluster, losing orthologous relationships. In contrast, Mi-1 homologs from cultivated potato species (S. tuberosum and S. phureja) seem to have evolved by a birth-and-death process, in which genes evolve mostly by mutations and interallelic recombinations in addition to sequence exchanges.     

Cloning and Expression of the Insecticidal Crystal Protein Gene <Emphasis Type="Italic">Cry</Emphasis>1Ca9 of <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> G10-01A from Taiwan Granaries

A new cry gene (cry1Ca9) was cloned and sequenced from a Bacillus thuringiensis isolate native to Taiwan (G10-01A). The cry1C-type gene, designated cry1Ca9, consisted of an open reading frame of 3,567 bp, encoding a protein of 1,189 amino acid residues. The polypeptide has the deduced amino acid sequences predicting molecular masses of 134.7 kDa. The gene sequence was compared against the GenBank nucleotide sequence data base. It was found that the cry1Ca9 gene coded for a 134.7-kDa protoxin which had greater than 99.8% homology with the previously reported cry1Ca1 gene, as only three mismatches were found between the two amino acid sequences. When the Cry1Ca9 toxin was expressed in a crystal-negative strain of B. thuringiensis (cryB^-), elliptical crystals were produced. Cell extracts from this recombinant strain appear to have high insecticidal activity against lepidopteran larvae (Plutella xylostella).Received: 23 September 2002 / Accepted: 6 December 2002     

Nutritional regulation of <Emphasis Type="Italic">ANR1</Emphasis> and other root-expressed MADS-box genes in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

The ANR1 MADS-box gene in Arabidopsis thaliana (L.) Heynh. has previously been identified as a key regulator of lateral root growth in response to signals from external nitrate (NO₃⁻). We have used quantitative real-time PCR to investigate the responsiveness of ANR1 and 11 other root-expressed MADS-box genes to fluctuations in the supply of N, P and S. ANR1 expression in roots of hydroponically grown Arabidopsis plants was specifically regulated by changes in the N supply, being induced by N deprivation and rapidly repressed by N re-supply. This pattern of N responsiveness differs from the NO₃⁻ -inducibility of ANR1 previously observed in Arabidopsis root cultures [H.M. Zhang and B.G. Forde (1998) Science 279:407–409]. Seven of the other MADS-box genes responded to N in a manner similar to ANR1, but less strongly, while four (AGL12, AGL17, AGL18 and AGL79) were unaffected. Six of the N-regulated genes (ANR1, AGL14, AGL16, AGL19, SOC1 and AGL21) belong to just two clades within the type II MADS-box lineage, while the other two (AGL26 and AGL56) belong to the poorly characterized type I lineage. Only SOC1 was additionally found to respond to changes in the P and S supply, suggesting a possible role in a general response to nutrient stress. Studies with an ANR1 transposon-insertion mutant provided no evidence for regulatory interactions between ANR1 and the other root-expressed MADS-box genes. The implications of the current data for our understanding of the role of ANR1 and other MADS box genes in the nutritional regulation of lateral root growth are discussed.     

Molecular cloning and characterization of an F-box family gene <Emphasis Type="Italic">CarF</Emphasis>-<Emphasis Type="Italic">box1</Emphasis> from chickpea (<Emphasis Type="Italic">Cicer arietinum</Emphasis> L.)

F-box protein family has been found to play important roles in plant development and abiotic stress responses via the ubiquitin pathway. In this study, an F-box gene CarF-box1 (for Cicer arietinum F-box gene 1, Genbank accession no. GU247510) was isolated based on a cDNA library constructed with chickpea seedling leaves treated by polyethylene glycol. CarF-box1 encoded a putative protein with 345 amino acids and contained no intron within genomic DNA sequence. CarF-box1 is a KFB-type F-box protein, having a conserved F-box domain in the N-terminus and a Kelch repeat domain in the C-terminus. CarF-box1 was localized in the nucleus. CarF-box1 exhibited organ-specific expression and showed different expression patterns during seed development and germination processes, especially strongly expressed in the blooming flowers. In the leaves, CarF-box1 could be significantly induced by drought stress and slightly induced by IAA treatment, while in the roots, CarF-box1 could be strongly induced by drought, salinity and methyl jasmonate stresses. Our results suggest that CarF-box1 encodes an F-box protein and may be involved in various plant developmental processes and abiotic stress responses.