Four TFL1/CEN-Like Genes on Distinct Linkage Groups Show Different Expression Patterns to Regulate Vegetative and Reproductive Development in Apple (Malusxdomestica Borkh.)

Recent molecular analyses in several plant species revealedthat TERMINAL FLOWER1 (TFL1) and CENTRORADIALIS (CEN) homologsare involved in regulating the flowering time and/or maintainingthe inflorescence meristem. In apple (Malusxdomestica Borkh.),four TFL1/CEN-like genes, MdTFL1, MdTFL1a, MdCENa and MdCENb,were found and mapped by a similar position on putatively homoeologouslinkage groups. Apple TFL1/CEN-like genes functioned equivalentlyto TFL1 when expressed constitutively in transgenic Arabidopsisplants, suggesting that they have a potential to complementthe TFL1 function. Because MdTFL1 and MdTFL1a were expressedin the vegetative tissues in both the adult and juvenile phases,they could function redundantly as a flowering repressor anda regulator of vegetative meristem identity. On the other hand,MdCENa was mainly expressed in fruit receptacles, cultured tissuesand roots, suggesting that it is involved in the developmentof proliferating tissues but not in the control of the transitionfrom the juvenile to the adult phase. In contrast, MdCENb wassilenced in most organs probably due to gene duplication bythe polyploid origin of apple. The expression patterns of MdTFL1and MdCENa in apple were also supported by the heterologousexpression of β-glucuronidase fused with their promoterregions in transgenic Arabidopsis. Our results suggest thatfunctional divergence of the roles in the regulation of vegetativemeristem identity may have occurred among four TFL1/CEN-likegenes during evolution in apple.     

CENTRORADIALIS/TERMINAL FLOWER 1 gene homolog is conserved inN. tabacum, a determinate inflorescence plant

A mutation in theCENTRORADIALIS (CEN) gene ofAntirrhinum and in theTERMINAL FLOWER 1 (TFL1) gene ofArabidopsis causes their indeterminate inflorescence to determinate. We clonedCEN/TFL1 homologs fromNicotiana tabacum, the wild-type of which has a determinate inflorescence. TheCEN gene was expressed in the inflorescnece meristem and kept its inflorescence meristem identity, whereas the tobacco homolog (NCH) was expressed at a low level throughout the plant’s development. AlthoughCEN andNCH are highly homologous genes, they may have been recruited to different developmental functions during their evolution. TwoNCH genes are derived from amphidiploidN. tabacum, but both of them hybridized with its diploid parents,N. sylvestris andN. tomentosiformis. Southern blotting, and the genomic organization ofTFL1 inArabidopsis revealed that anotherCEN homolog exists in the genome ofArabidopsis. These results suggest that there are two copies of theCEN homolog per diploid plant. The extended abstract of a paper presented at the 13th International Symposium in Conjugation with Award of the International Prize for Biology “Frontier of Plant Biology” These two authors contributed to this work equally.     

Cloning and Characterization of FLOWERING LOCUS T-Like Genes from the Perennial Geophyte Saffron Crocus (Crocus sativus)

The transition to flowering is one of the most important developmental decisions made by plants. At the molecular level, many genes coordinate this transition. Among these, genes encoding for phosphatidylethanolamine-binding proteins (PEBPs) play important roles in regulating flower time and the fate of inflorescence meristem. To investigate the role of PEBPs in an industrially important crop cultivated for its nutritional and medicinal properties, the monocotyledonous species Crocus sativus L., we have isolated three FLOWERING LOCUS T (FT)-like genes designated as CsatFT1-like, CsatFT2-like, and CsatFT3-like. The isolated genes maintain the exon/intron organization of FT-like genes and encode proteins similar to the members of the PEBP family. Phylogenetic and amino acid analysis at critical positions confirmed that the isolated sequence belongs to the FT clade of the PEBP family phylogeny distinctly from the TERMINAL FLOWER 1 (TFL1) and MOTHER OF FT AND TFL1 clades. Expression analysis indicated differences in the expression of the three FT-like genes in different organs and different expressions during the day–night diurnal clock. Additionally, analysis of isolated promoter sequences using computational methods reveals the preservation of common binding motifs in FT-like promoters from other species, thus suggesting their importance among plant species.     

Characterization and expression analysis of TERMINAL FLOWER1 homologs from cultivated alloteraploid cotton (Gossypium hirsutum) and its diploid progenitors

The seasonal cycle and persistence of a plant is governed by a combination of the determinate or indeterminate status of shoot and root apical meristems. A perennial plant is one in which the apical meristem of at least one of its shoot axes remains indeterminate beyond the first growth season.TERMINAL FLOWER1 (TFL1) genes play important roles in regulating flowering time, the fate of inflorescence meristem and perenniality. To investigate the role of TFL1-like genes in the determination of the apical meristems in an industrially important crop cultivated for its fibers, we isolated and characterized two TFL1 homologs (TFL1a and TFL1b) from tetraploid cultivated cotton (Gossypium hirsutum) and its diploid progenitors (Gossypium arboreum and Gossypium raimondii). All isolated genes maintain the same exon–intron organization. Their phylogenetic analysis at the amino acid level confirmed that the isolated sequences are TFL1-like genes and collocate in the TFL1 clade of the PEBP protein family. Expression analysis revealed that the genes TFL1a and TFL1b have slightly different expression patterns, suggesting different functional roles in the determination of the meristems. Additionally, promoter analysis by computational methods revealed the presence of common binding motifs in TFL1-like promoters. These are the first reported TFL1-like genes isolated from cotton, the most important crop for the textile industry.     

Identification and distribution of the NBS-LRR gene family in the Cassava genome

Background

Plant resistance genes (R genes) exist in large families and usually contain both a nucleotide-binding site domain and a leucine-rich repeat domain, denoted NBS-LRR. The genome sequence of cassava (Manihot esculenta) is a valuable resource for analysing the genomic organization of resistance genes in this crop.

Results

With searches for Pfam domains and manual curation of the cassava gene annotations, we identified 228 NBS-LRR type genes and 99 partial NBS genes. These represent almost 1% of the total predicted genes and show high sequence similarity to proteins from other plant species. Furthermore, 34 contained an N-terminal toll/interleukin (TIR)-like domain, and 128 contained an N-terminal coiled-coil (CC) domain. 63% of the 327 R genes occurred in 39 clusters on the chromosomes. These clusters are mostly homogeneous, containing NBS-LRRs derived from a recent common ancestor.

Conclusions

This study provides insight into the evolution of NBS-LRR genes in the cassava genome; the phylogenetic and mapping information may aid efforts to further characterize the function of these predicted R genes.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1554-9) contains supplementary material, which is available to authorized users.     

Biochemical Genetics of Opossum Aldehyde Dehydrogenase 3: Evidence for Three ALDH3A-Like Genes and an ALDH3B-Like Gene

Mammalian ALDH3 isozymes participate in peroxidic and fatty aldehyde metabolism, and in anterior eye tissue UV-filtration. BLAT analyses were undertaken of the opossum genome using rat ALDH3A1, ALDH3A2, ALDH3B1, and ALDH3B2 amino acid sequences. Two predicted opossum ALDH3A1-like genes and an ALDH3A2-like gene were observed on chromosome 2, as well as an ALDH3B-like gene, which showed similar intron–exon boundaries with other mammalian ALDH3-like genes. Opossum ALDH3 subunit sequences and structures were highly conserved, including residues previously shown to be involved in catalysis and coenzyme binding for rat ALDH3A1. Eleven glycine residues were conserved for all of the opossum ALDH3-like sequences examined, including two glycine residues previously located within the stem of the rat ALDH3A1 active site funnel. Phylogeny studies of human, rat, opossum, and chicken ALDH3-like sequences indicated that the common ancestor for ALDH3A- and ALDH3B-like genes predates the appearance of birds during vertebrate evolution.     

Phylogenetic positions of RH blood group-related genes in cyclostomes

The RH gene family in vertebrates consists of four major genes (RH, RHAG, RHBG, and RHCG). They are thought to have emerged in the common ancestor of vertebrates after two rounds of whole genome duplication (2R-WGD). To analyze the detailed phylogenetic relationships within the RH gene family, we determined three types of cDNA sequence that belong to the RH gene family in lamprey (Lethenteron reissneri) and designated them as RHBG-like, RHCG-like1, and RHCG-like2. Phylogenetic analyses clearly showed that RHCG-like1 and RHCG-like2 genes, which were probably duplicated in the lamprey lineage, are orthologs of gnathostome RHCG. In contrast, the clear phylogenetic position of the RHBG-like gene could not be obtained. Probably some convergent events for cyclostome RHBG-like genes prevented the accurate identification of their phylogenetic positions.     

Genome analysis of phage JS98 defines a fourth major subgroup of T4-like phages in Escherichia coli

Numerous T4-like Escherichia coli phages were isolated from human stool and environmental wastewater samples in Bangladesh and Switzerland. The sequences of the major head gene (g23) revealed that these coliphages could be placed into four subgroups, represented by the phages T4, RB69, RB49, and JS98. Thus, JS98 defines a new major subgroup of E. coli T4-like phages. We conducted an analysis of the 169-kb JS98 genome sequence. Overall, 198 of the 266 JS98 open reading frames (ORFs) shared amino acid sequence identity with the reference T4 phage, 41 shared identity with other T4-like phages, and 27 ORFs lacked any database matches. Genes on the plus strand encoded virion proteins, which showed moderate to high sequence identity with T4 proteins. The right genome half of JS98 showed a higher degree of sequence conservation with T4 and RB69, even for the nonstructural genes, than did the left genome half, containing exclusively nonstructural genes. Most of the JS98-specific genes were found in the left genome half. Two came as a hypervariability cluster, but most represented isolated genes, suggesting that they were acquired separately in multiple acquisition events. No evidence for DNA exchange between JS98 phage and the E. coli host genome or coliphages other than T4 was observed. No undesired genes which could compromise its medical use were detected in the JS98 genome sequence.     

A promoter analysis of MOTHER OF FT AND TFL1 1 (JcMFT1), a seed-preferential gene from the biofuel plant Jatropha curcas

MOTHER OF FT AND TFL1 (MFT)-like genes belong to the phosphatidylethanoamine-binding protein (PEBP) gene family in plants. In contrast to their homologs FLOWERING LOCUS T (FT)-like and TERMINAL FLOWER 1 (TFL1)-like genes, which are involved in the regulation of the flowering time pathway, MFT-like genes function mainly during seed development and germination. In this study, a full-length cDNA of the MFT-like gene JcMFT1 from the biodiesel plant Jatropha curcas (L.) was isolated and found to be highly expressed in seeds. The promoter of JcMFT1 was cloned and characterized in transgenic Arabidopsis. A histochemical β-glucuronidase (GUS) assay indicated that the JcMFT1 promoter was predominantly expressed in both embryos and endosperms of transgenic Arabidopsis seeds. Fluorometric GUS analysis revealed that the JcMFT1 promoter was highly active at the mid to late stages of seed development. After seed germination, the JcMFT1 promoter activity decreased gradually. In addition, both the JcMFT1 expression in germinating Jatropha embryos and its promoter activity in germinating Arabidopsis embryos were induced by abscisic acid (ABA), possibly due to two ABA-responsive elements, a G-box and an RY repeat, in the JcMFT1 promoter region. These results show that the JcMFT1 promoter is seed-preferential and can be used to control transgene expression in the seeds of Jatropha and other transgenic plants.     

p-SINE1-like intron of the CatA catalase homologs and phylogenetic relationships among AA-genome Oryza and related species

 Intron-2 of the Oryza sativa CatA catalase gene is similar in nucleotide sequence to p-SINE1, a retroposon, and seems to have been added to the ancestral genome of rice. To examine when the p-SINE1-like intron was inserted into CatA during the evolutionary divergence of Oryza species, and to elucidate the evolutionary relationships among Oryza species using the sequence of the intron as a marker, we performed polymerase chain reaction (PCR) analyses of 32 accessions of 17 Oryza species with various genome types. Agarose-gel electrophoresis of the PCR products revealed that all the Oryza species with an AA genome have the CatA homolog with the intron, whereas other Oryza species have the CatA homolog without the intron. These results indicate that intron-2 of CatA is a good marker for distinguishing species with an AA genome among Oryza species. Sequencing of the PCR products showed that all the introns are similar to p-SINE1, though with slight variations in length. We also performed PCR analyses using four accessions of three species in genera related to Oryza, and found that there is an intron in the CatA homolog of Leersia perrieri. On the other hand, the CatA homolog of Porteresia coarctata has no intron. Sequence data showed that the L. perrieri homolog has a p-SINE1-like intron similar to that in Oryza species with an AA genome. These results suggest that the p-SINE1-like intron was already present in the common ancestor of Oryza and L. perrieri and was then lost in the ancestors of P. coarctata and of the Oryza species other than those with an AA genome. The phylogenetic tree of Oryza species with an AA genome based on the nucleotide sequences of the introns leads us to propose that Oryza species with an AA genome evolved from an ancestor of Oryza longistaminata. Received: 29 August 1998 / Accepted: 2 November 1998     

Opossum Aldehyde Dehydrogenases: Evidence for Four ALDH1A1-like Genes on Chromosome 6 and ALDH1A2 and ALDH1A3 Genes on Chromosome 1

Evidence is presented for six opossum ALDH1A genes, including four ALDH1A1-like genes on chromosome 6 and ALDH1A2- and ALDH1A3-like genes on chromosome 1. Predicted structures for the opossum aldehyde dehydrogenase (ALDH) subunits and the intron–exon boundaries for opossum ALDH genes showed a high degree of similarity with other mammalian ALDHs. Phylogenetic analyses supported the proposed designation of these opossum class 1 ALDHs as ALDH1A-like, ALDH1A2-like, and ALDH1A3-like and are therefore likely to play important roles in retinal and peroxidic aldehyde metabolism. Alignments of predicted opossum ALDH1A amino acid sequences with sheep ALDH1A1 and rat ALDH1A2 sequences demonstrated conservation of key residues previously shown to participate in catalysis and coenzyme binding. Amino acid substitution rates observed for family 1A ALDHs during vertebrate evolution indicated that ALDH1A2-like genes are evolving slower than ALDH1A1- and ALDH1A3-like genes. It is proposed that the common ancestor for ALDH1A genes predates the appearance of birds during vertebrate evolution.     

Phylogenomic Analysis of the PEBP Gene Family in Cereals

The TFL1 and FT genes, which are key genes in the control of flowering time in Arabidopsis thaliana, belong to a small multigene family characterized by a specific phosphatidylethanolamine-binding protein domain, termed the PEBP gene family. Several PEBP genes are found in dicots and monocots, and act on the control of flowering time. We investigated the evolution of the PEBP gene family in cereals. First, taking advantage of the complete rice genome sequence and EST databases, we found 19 PEBP genes in this species, 6 of which were not previously described. Ten genes correspond to five pairs of paralogs mapped on known duplicated regions of the rice genome. Phylogenetic analysis of Arabidopsis and rice genes indicates that the PEBP gene family consists of three main homology classes (the so-called TFL1-LIKE, MFT-LIKE, and FT-LIKE subfamilies), in which gene duplication and/or loss occurred independently in Arabidopsis and rice. Second, phylogenetic analyses of genomic and EST sequences from five cereal species indicate that the three subfamilies of PEBP genes have been conserved in cereals. The tree structure suggests that the ancestral grass genome had at least two MFT-like genes, two TFL1-like genes, and eight FT-like genes. A phylogenomic approach leads to some hypotheses about conservation of gene function within the subfamilies. [Reviewing Editor: Dr. Yves Van de Peer]     

Evidence for Transitional Stages in the Evolution of Euglenid Group II Introns and Twintrons in the Monomorphina aenigmatica Plastid Genome

Background

Photosynthetic euglenids acquired their plastid by secondary endosymbiosis of a prasinophyte-like green alga. But unlike its prasinophyte counterparts, the plastid genome of the euglenid Euglena gracilis is riddled with introns that interrupt almost every protein-encoding gene. The atypical group II introns and twintrons (introns-within-introns) found in the E. gracilis plastid have been hypothesized to have been acquired late in the evolution of euglenids, implying that massive numbers of introns may be lacking in other taxa. This late emergence was recently corroborated by the plastid genome sequences of the two basal euglenids, Eutreptiella gymnastica and Eutreptia viridis, which were found to contain fewer introns.

Methodology/Principal Findings

To gain further insights into the proliferation of introns in euglenid plastids, we have characterized the complete plastid genome sequence of Monomorphina aenigmatica, a freshwater species occupying an intermediate phylogenetic position between early and late branching euglenids. The M. aenigmatica UTEX 1284 plastid genome (74,746 bp, 70.6% A+T, 87 genes) contains 53 intron insertion sites, of which 41 were found to be shared with other euglenids including 12 of the 15 twintron insertion sites reported in E. gracilis.

Conclusions

The pattern of insertion sites suggests an ongoing but uneven process of intron gain in the lineage, with perhaps a minimum of two bursts of rapid intron proliferation. We also identified several sites that represent intermediates in the process of twintron evolution, where the external intron is in place, but not the internal one, offering a glimpse into how these convoluted molecular contraptions originate.     

Test of intron predictions reveals novel splice sites, alternatively spliced mRNAs and new introns in meiotically regulated genes of yeast

Correct identification of all introns is necessary to discern the protein-coding potential of a eukaryotic genome. The existence of most of the spliceosomal introns predicted in the genome of Saccharomyces cerevisiae remains unsupported by molecular evidence. We tested the intron predictions for 87 introns predicted to be present in non-ribosomal protein genes, more than a third of all known or suspected introns in the yeast genome. Evidence supporting 61 of these predictions was obtained, 20 predicted intron sequences were not spliced and six predictions identified an intron-containing region but failed to specify the correct splice sites, yielding a successful prediction rate of <80%. Alternative splicing has not been previously described for this organism, and we identified two genes (YKL186C/MTR2 and YML034W) which encode alternatively spliced mRNAs; YKL186C/MTR2 produces at least five different spliced mRNAs. One gene (YGR225W/SPO70) has an intron whose removal is activated during meiosis under control of the MER1 gene. We found eight new introns, suggesting that numerous introns still remain to be discovered. The results show that correct prediction of introns remains a significant barrier to understanding the structure, function and coding capacity of eukaryotic genomes, even in a supposedly simple system like yeast.     

CLAVATA3-like genes are differentially expressed in grape vine (Vitis vinifera) tissues

The CLAVATA3 (CLV3)/endosperm surrounding region [(ESR) CLE] peptides function as intercellular signaling molecules that regulate various physiological and developmental processes in diverse plant species. We identified five CLV3-like genes from grape vine (Vitis vinifera var. Pinot Noir): VvCLE 6, VvCLE 25-1, VvCLE 25-2, VvCLE 43 and VvCLE TDIF. These CLV3-like genes encode short proteins containing 43–128 amino acids. Except VvCLE TDIF, grape vine CLV3-like proteins possess a consensus amino acid sequence known as the CLE domain. Phylogenic analysis suggests that the VvCLE 6, VvCLE25-1, VvCLE25-2 and VvCLE43 genes have evolved from a single common ancestor to the Arabidopsis CLV3 gene. Expression analyses showed that the five grape CLV3-like genes are expressed in leaves, stems, roots and axillary buds with significant differences in their levels of expression. For example, while all of them were strongly expressed in axillary buds, VvCLE6 and VvCLE43 expression prevailed in roots, and VvCLE25-1, VvCLE25-2 and VvCLE TDIF expression in stems. The differential expression of the five grape CLV3-like peptides suggests that they play different roles in different organs and developmental stages.     

Functional Evolution of Phosphatidylethanolamine Binding Proteins in Soybean and Arabidopsis

Gene duplication provides resources for novel gene functions. Identification of the amino acids responsible for functional conservation and divergence of duplicated genes will strengthen our understanding of their evolutionary course. Here, we conducted a systemic functional investigation of phosphatidylethanolamine binding proteins (PEBPs) in soybean (Glycine max) and Arabidopsis thaliana. Our results demonstrated that after the ancestral duplication, the lineage of the common ancestor of the FLOWERING LOCUS T (FT) and TERMINAL FLOWER1 (TFL1) subfamilies functionally diverged from the MOTHER OF FT AND TFL1 (MFT) subfamily to activate flowering and repress flowering, respectively. They also underwent further specialization after subsequent duplications. Although the functional divergence increased with duplication age, we observed rapid functional divergence for a few pairs of young duplicates in soybean. Association analysis between amino acids and functional variations identified critical amino acid residues that led to functional differences in PEBP members. Using transgenic analysis, we validated a subset of these differences. We report clear experimental evidence for the functional evolution of the PEBPs in the MFT, FT, and TFL1 subfamilies, which predate the origin of angiosperms. Our results highlight the role of amino acid divergence in driving evolutionary novelty after duplication.     

Development of a candidate gene marker for Rf 1 based on a PPR gene in cytoplasmic male sterile CMS-D2 Upland cotton

The cytoplasmic male sterility (CMS) system is convenient and efficient for hybrid seed production in Upland cotton (Gossypium hirsutum L.). However, it has not been widely used because of limited restorer lines carrying the restorer gene Rf ₁ in the CMS-D2 system. In this study, the fertility segregation in a backcross (BC8F1) population of 409 individuals and an F2 population of 695 plants confirmed that the fertility restoration was determined by one dominant restorer gene (Rf ₁ ). A sequence alignment showed that 13 Rf ₁ -linked simple sequence repeat marker sequences were distributed on nine scaffolds of chromosome 9 in the sequenced D5 genome of G. raimondii Ulbrich. Ten pentotricopeptide repeat (PPR)-like genes were identified on two scaffolds, including Scaffold 333 where nine PPR-like genes were clustered in a region of about 160 kb. Among them, PPR-like gene Cotton_D_gene_10013437 was identified as the candidate for the Rf ₁ gene through a comparative sequence analysis of the homologous gene among sterile (A), maintainer (B) and restorer (R) lines, and co-segregation analysis. Compared with the non-restoring lines, the restorer had a 9-nucleotide (nt) insertion and a single nucleotide polymorphism (SNP) 8 nt upstream of the insertion at the 3′ untranslated regions (3′ UTRs) in this gene. A cleaved amplified polymorphic sequence (CAPS) marker named CAPS-R was developed from the SNP site using the restriction enzyme DraI, and was further used to track the restorer gene and its homozygous or heterozygous status in molecular breeding for restorer lines. A marker-assisted selection system using the Rf ₁ -specific CAPS-R marker and a CMS-D2 cytoplasm-specific SCAR marker was established to distinguish the three-line hybrids from other genotypes.     

LEA Gene Introns: is the Intron of Dehydrin Genes a Characteristic of the Serine-Segment?

Dehydrins, which belong to group 2 LEA proteins, are a family of intrinsically unstructured plant proteins that accumulate during the late stages of embryogenesis and in response to abiotic stresses. We have previously reported that the OpsDHN1 gene, encoding an SK₃-type acidic dehydrin protein from Opuntia streptacantha, contains an intron inserted within the sequence encoding the S-motif. Herein, we present an in silico analysis of intron sequences in dehydrin genes from mono- and dicotyledonous plants that reveals a preference for insertion within the nucleotide sequence encoding the S-motif. Sequence comparison of ten Dhn genes from Arabidopsis thaliana and the orthologous genes in Arabidopsis lyrata revealed that introns maintain considerable sequence identity and conserve the insertion pattern. Furthermore, syntenic regions were identified among eight orthologous genes of A. thaliana and A. lyrata, showing that correlated gene arrangements are conserved between these Arabidopsis species. Our study shows that most SKn-type dehydrins contain one intron that is conserved in phase and location; this intron is linked to the nucleotide sequence that encodes the S-motif.