Breeding of lilies and tulips-Interspecific hybridization and genetic background.

Lilies and tulips (Liliaceae family) are economically very important ornamental bulbous plants. Here, we summarize major breeding goals, the role of an integrated method of cut-style pollination and fertilization followed by embryo rescue and mitotic and meiotic polyploidization involved in new assortment development. Both crops have been subjected to extensive interspecific hybridization followed by selection. Additionally, spontaneous polyploidization has played a role in their evolution. In lilies, there is a tendency to replace diploids with polyploid cultivars, whereas in tulip a majority of the cultivars that exist today are still diploid except for triploid Darwin hybrid tulips. The introduction of molecular cytogenetic techniques such as genomic in situ hybridization (GISH) permitted the detailed studies of genome composition in lily and tulip interspecific hybrids and to follow the chromosome inheritance in interspecific crosses. In addition, this review presents the latest information on phylogenetic relationship in lily and tulip and recent developments in molecular mapping using different DNA molecular techniques.

A low-pungency S3212 genotype of Capsicum frutescens caused by a mutation in the putative aminotransferase (p-AMT) gene.

The purpose of this study was to identify the genetic mechanism underlying capsinoid biosynthesis in S3212, a low-pungency genotype of Capsicum frutescens. Screening of C. frutescens accessions for capsaicinoid and capsiate contents by high-performance liquid chromatography revealed that low-pungency S3212 contained high levels of capsiate but no capsaicin. Comparison of DNA coding sequences of pungent (T1 and Bird Eye) and low-pungency (S3212) genotypes uncovered a significant 12-bp deletion mutation in exon 7 of the p-AMT gene of S3212. In addition, p-AMT gene transcript levels in placental tissue were positively correlated with the degree of pungency. S3212, the low-pungency genotype, exhibited no significant p-AMT transcript levels, whereas T1, one of the pungent genotypes, displayed high transcript levels of this gene. We therefore conclude that the deletion mutation in the p-AMT gene is related to the loss of pungency in placental tissue and has given rise to the low-pungency S3212 C. frutescens genotype. C. frutescens S3212 represents a good natural source of capsinoids. Finally, our basic characterization of the uncovered p-AMT gene mutation should contribute to future studies of capsinoid biosynthesis in Capsicum.

Molecular characterization of an isoamylase 1-type starch debranching enzyme (DBEI) in grain amaranth (Amaranthus cruentus L.).

The purpose of this study was to characterize the molecular profile of a starch debranching enzyme (DBE) in grain amaranth. A cDNA clone that encodes a putative DBE was isolated from amaranth perisperm and then sequenced. This amaranth DBE appears to be an ISA1-type DBE (DBEI), based on its substrate specificity and the sequence similarity between the 2,391-bp cDNA clone and ISA1 s from potato and Arabidopsis. The mature DBEI of amaranth consists of 796 amino acids (90.5 kDa). We analyzed the transcript levels of the DBEI gene in amaranth seeds during various developmental stages and in plant tissues by qRT-PCR and RT-PCR analyses. The transcript levels of the DBEI gene rapidly increased at the middle stage of seed maturation. This result indicates that the enzyme encoded by the amaranth DBEI gene plays an important role in starch accumulation throughout the seed during the middle stage of seed development. We detected DBEI transcripts in storage and non-storage tissues. At the six-leaf stage, there were high levels of the DBEI transcripts in leaves, petioles, and the stem, and low levels in the root. Therefore, we suggest that the DBEI expression is not specific to non-storage and/or storage tissues. This summary of the basic characteristics of the DBEI gene will contribute to further studies on starch biosynthesis in Amaranthus.

A rapid and reliable PCR-restriction fragment length polymorphism (RFLP) marker for the identification of Amaranthus cruentus species.

A rapid and reliable PCR-restriction fragment length polymorphism (RFLP) marker was developed to identify the Amaranthus cruentus species by comparing sequences of the starch branching enzyme (SBE) locus among the three cultivated grain amaranths. We determined the partial SBE genomic sequence in 72 accessions collected from diverse locations around the world by direct sequence analysis. Then, we aligned the gene sequences and searched for restriction enzyme cleavage sites specific to each species for use in the PCR-RFLP analysis. The result indicated that MseI would recognize the sequence 5'-T/TAA-3' in intron 11 from A. cruentus SBE. A restriction analysis of the amplified 278-bp portion of the SBE gene using the MseI restriction enzyme resulted in species-specific RFLP patterns among A. cruentus, Amaranthus caudatus and Amaranthus hypochondriacus. Two different bands, 174-bp and 104-bp, were generated in A. cruentus, while A. caudatus and A. hypochondriacus remained undigested (278-bp). Thus, we propose that the PCR-RFLP analysis of the amaranth SBE gene provides a sensitive, rapid, simple and useful technique for identifying the A. cruentus species among the cultivated grain amaranths.

Rapid identification of Amaranthus caudatus and Amaranthus hypochondriacus by sequencing and PCR-RFLP analysis of two starch synthase genes.

The objective of this study was to develop a PCR-RFLP method to identity the cultivated species of grain amaranth based on variations in the sequences of their starch synthase genes. We sequenced the SSSI and GBSSI loci in 126 accessions of cultivated grain amaranth collected from diverse locations around the world. We aligned the gene sequences and searched for restriction enzyme cleavage sites specific to each species for use in the PCR-RFLP analysis. Our analyses indicated that EcoRI would recognize the sequence 5'-GAATT/C-3' in the SSSI gene from Amaranthus caudatus L., and TaqI would recognize the sequence 5'-T/CGA-3' in the GBSSI gene from Amaranthus hypochondriacus L. The PCR products obtained using gene-specific primers were 423 bp (SSSI) and 627 or 635 bp (GBSSI) in length. These products were cut with different restriction enzymes resulting in species-specific RFLP patterns that could be used to distinguish among the cultivated grain amaranths. The results clearly showed that A. caudatus and A. hypochondriacus were easily differentiated at the species level using this method. Therefore, the PCR-RFLP method targeting amaranth starch synthase genes is simple and rapid, and it will be a useful tool for the identification of cultivated species of grain amaranth.

Characterization and expression analysis of the starch synthase gene family in grain amaranth (Amaranthus cruentus L.).

Characterization and expression analysis of the starch synthase gene family was performed from grain amaranth. Extensive searches for sequence data for amaranth starch synthase genes were done in the literature and in GenBank, and identified four genes encoding GBSSI, SSSI, SSSII, and SBE. Alignment of predicted amino acid sequences showed that there were low levels of sequence identity among these four genes (10.6-34.5%). There was higher homology in the C-terminal region and lower homology in the N-terminal region of the amaranth starch synthases. Starch synthases in plants can be classified into six groups, and phylogenetic analyses showed that the starch synthases from amaranth were in four of these groups; GBSSs, SSSIs, SSSIIs, and SBEs of dicot plants. Interestingly, all amaranth starch synthases were sister to the subgroup consisting of the rest of the dicot plants, clustering more closely with dicots than with monocots. Analysis of the expression patterns of starch synthase genes in storage and non-storage tissues of amaranth revealed two types of expression patterns; (1) GBSSI was rapidly expressed at the middle or mid-late stages of seed development; and (2) SSSI, SSSII and SBE genes were expressed constitutively during seed maturation. These four genes were expressed in non-storage tissues as well as in storage tissue, suggesting that non-storage and storage tissues of amaranth share a common mechanism for expression of starch synthase genes. This summary of the basic characteristics of starch synthase genes will contribute further studies on amaranth starch.

Substitution of the gene for chloroplast RPS16 was assisted by generation of a dual targeting signal.

Organelle (mitochondria and chloroplasts in plants) genomes lost a large number of genes after endosymbiosis occurred. Even after this major gene loss, organelle genomes still lose their own genes, even those that are essential, via gene transfer to the nucleus and gene substitution of either different organelle origin or de novo genes. Gene transfer and substitution events are important processes in the evolution of the eukaryotic cell. Gene loss is an ongoing process in the mitochondria and chloroplasts of higher plants. The gene for ribosomal protein S16 (rps16) is encoded in the chloroplast genome of most higher plants but not in Medicago truncatula and Populus alba. Here, we show that these 2 species have compensated for loss of the rps16 from the chloroplast genome by having a mitochondrial rps16 that can target the chloroplasts as well as mitochondria. Furthermore, in Arabidopsis thaliana, Lycopersicon esculentum, and Oryza sativa, whose chloroplast genomes encode the rps16, we show that the product of the mitochondrial rps16 has dual targeting ability. These results suggest that the dual targeting of RPS16 to the mitochondria and chloroplasts emerged before the divergence of monocots and dicots (140-150 MYA). The gene substitution of the chloroplast rps16 by the nuclear-encoded rps16 in higher plants is the first report about ongoing gene substitution by dual targeting and provides evidence for an intermediate stage in the formation of this heterogeneous organelle.

Genetic variation in the chloroplast genome suggests multiple domestication of cultivated Asian rice (Oryza sativa L.).

Two hundred and seventy-five accessions of cultivated Asian rice and 44 accessions of AA genome Oryza species were classified into 8 chloroplast (cp) genome types (A-H) based on insertion-deletion events at 3 regions (8K, 57K, and 76K) of the cp genome. The ancestral cp genome type was determined according to the frequency of occurrence in Oryza species and the likely evolution of the variable 57K region of the cp genome. When 2 nucleotide substitutions (AA or TT) were taken into account, these 8 cp types were subdivided into 11 cp types. Most indica cultivars had 1 of 3 cp genome types that were also identified in the wild relatives of rice, O. nivara and O. rufipogon, suggesting that the 3 indica cp types had evolved from distinct gene pools of the O. rufipogon - O. nivara complex. The majority of japonica cultivars had 1 of 3 different cp genome types. One of these 3 was identified in O. rufipogon, suggesting that at least 1 japonica type is derived from O. rufipogon with the same cp genome type. These results provide evidence to support a polyphyletic origin of cultivated Asian rice from at least 4 principal lineages in the O. rufipogon - O. nivara complex.

Phylogenetic analysis of Oryza species, based on simple sequence repeats and their flanking nucleotide sequences from the mitochondrial and chloroplast genomes.

Simple sequence repeats (SSR) and their flanking regions in the mitochondrial and chloroplast genomes were sequenced in order to reveal DNA sequence variation. This information was used to gain new insights into phylogenetic relationships among species in the genus Oryza. Seven mitochondrial and five chloroplast SSR loci equal to or longer than ten mononucleotide repeats were chosen from known rice mitochondrial and chloroplast genome sequences. A total of 50 accessions of Oryza that represented six different diploid genomes and three different allopolyploid genomes of Oryza species were analyzed. Many base substitutions and deletions/insertions were identified in the SSR loci as well as their flanking regions. Of mononucleotide SSR, G (or C) repeats were more variable than A (or T) repeats. Results obtained by chloroplast and mitochondrial SSR analyses showed similar phylogenetic relationships among species, although chloroplast SSR were more informative because of their higher sequence diversity. The CC genome is suggested to be the maternal parent for the two BBCC genome species (O. punctata and O. minuta) and the CCDD species O. latifolia, based on the high level of sequence conservation between the diploid CC genome species and these allotetraploid species. This is the first report of phylogenetic analysis among plant species, based on mitochondrial and chloroplast SSR and their flanking sequences.

The complete nucleotide sequence of wild rice (Oryza nivara) chloroplast genome: first genome wide comparative sequence analysis of wild and cultivated rice.

We determined the complete nucleotide sequence of the chloroplast genome of wild rice, Oryza nivara and compared it with the corresponding published sequence of relative cultivated rice, Oryza sativa. The genome was 134,494 bp long with a large single-copy region of 80,544 bp, a small single-copy region of 12,346 bp and two inverted repeats of 20,802 bp each. The overall A+T content was 61.0%. The O. nivara chloroplast genome encoded identical functional genes to O. sativa in the same order along the genome. On the other hand, detailed analysis revealed 57 insertion, 61 deletion and 159 base substitution events in the entire chloroplast genome of O. nivara. Among substitutions, transversions were much higher than transitions with the former even more frequent than the latter in the coding region. Most of the insertions/deletions were single-base but a few large length mutations were also detected. The frequency of insertion/deletion events was more in the coding region within inverted repeats. In contrast, a very few substitution events were identified in the coding region. Polymorphism was observed among rice cultivars at loci of large insertion/deletion events. This is the first report describing comparative and genome wide chloroplast analysis between a wild and cultivated crop.

Molecular phylogeny of the genus Hordeum using three chloroplast DNA sequences.

The genus Hordeum consists of three cytotypes (2x, 4x, and 6x). Its reproductive isolation has been incomplete between closely related species and hence the genetic relationship is reticulate and complex. We used 32 taxa of Hordeum and three chloroplast DNA sequences, matK, atpB-rbcL, and trnL-trnF in the current study. Molecular phylogenetic analysis based on sequence data of the three chloroplast DNA regions clearly demonstrated genetic relationships among taxa and origin of polypoids. The formation of H. secalinum likely involved hybridization between Hordeum marinum subsp. marinum and a Eurasian diploid possessing the H genome. The formation of hexaploid Hordeum brachyantherum involved hybridization between tetraploid H. brachyantherum and diploid H. marinum subsp. gussoneanum. The formation of three tetraploids, H. brachyantherum, Hordeum jubatum, and Hordeum guatemalense, probably involved hybridization between H. brachyantherum subsp. californicum and an altered H genome diploid. The formation of Hordeum arizonicum involved the two taxa Hordeum pusillum and H. jubatum.