Putative polyadenylation signals in nuclear genes of higher plants: a compilation and analysis

GCTTCA as a novel motif for regulating mesocarp-specific expression of the oil palm (Elaeis guineensis Jacq.) stearoyl-ACP desaturase gene

TAAAAT and a novel motif, GCTTCA found in the oil palm stearoyl-ACP desaturase (SAD1) promoter are involved in regulating mesocarp-specific expression. Two key fatty acid biosynthetic genes, stearoyl-ACP desaturase (SAD1), and acyl-carrier protein (ACP3) in Elaeis guineensis (oil palm) showed high level of expression during the period of oil synthesis in the mesocarp [12-19 weeks after anthesis (w.a.a.)] and kernel (12-15 w.a.a.). Both genes are expressed in spear leaves at much lower levels and the expression increased by 1.5-fold to 2.5-fold following treatments with ethylene and abscisic acid (ABA). Both SAD1 and ACP3 promoters contain phytohormone-responsive, light-responsive, abiotic factors/wounding-responsive, endosperm specificity and fruit maturation/ripening regulatory motifs. The activities of the full length and six 5' deletion fragments of the SAD1 promoter were analyzed in transiently transformed oil palm tissues by quantitative β-glucuronidase (GUS) fluorometric assay. The highest SAD1 promoter activity was observed in the mesocarp followed by kernel and the least in the leaves. GUS activity in the D3 deletion construct (- 486 to + 108) was the highest, while the D2 (- 535 to + 108) gave the lowest suggesting the presence of negative cis-acting regulatory element(s) in the deleted - 535 to - 486 (49 bp). It was found that the 49-bp region binds to the nuclear protein extract from mesocarp but not from leaves in electrophoretic mobility shift assay (EMSA). Further fine-tuned analysis of this 49-bp region using truncated DNA led to the identification of GCTTCA as a novel motif in the SAD1 promoter. Interestingly, another known fruit ripening-related motif, LECPLEACS2 (TAAAAT) was found to be required for effective binding of the novel motif to the mesocarp nuclear protein extract.

Quantitative distribution of Citrus yellow mosaic badnavirus in sweet orange (Citrus sinensis) and its implication in developing disease diagnostics

Citrus yellow mosaic badnavirus (CMBV) is the etiologic agent of citrus yellow mosaic disease, which has caused serious economic losses to Indian citrus industry. CMBV is a quarantined pathogen that is geographically restricted to India. To prevent unintentional movement of the virus to other major citrus-growing countries in fruits, root stocks or grafted citrus plants and facilitate trade, a sensitive, validated diagnostic tool is needed. In the present study, we developed a SYBR Green real-time PCR-based method to detect and quantify CMBV in different tissues of infected Mosambi sweet orange (Citrus sinensis) and compared its sensitivity to conventional PCR protocols. Primers were designed to recognize a portion of the CMBV capsid protein gene. Conventional and real-time PCR were performed on several different tissues: shoot tips, leaves displaying typical CMBV symptoms, asymptomatic leaves, senescent leaves, thorns, green stems and feeder roots. The detection limit of CMBV by conventional PCR was 2.5 × 10⁴ copies per 5 ng of total genomic DNA, while the detection limit of real-time PCR was found to be 4.6 × 10² virus copies per 5 ng of viral DNA. The viral load varied between different tissues. The highest concentration occurred in feeder roots (3.5 × 10⁸ copies per 5 ng of total genomic DNA) and the lowest in thorns (1 × 10⁶ copies per 5 ng of total genomic DNA). The variation in viral load within different tissues suggests movement of the virus within an infected plant that follows the path of photo-assimilates via the phloem. In symptomatic leaves, the CMBV concentration was highest in the lamella followed by midrib and petiole, suggesting that virus resides inside these sections of a leaf and side by side symptoms develop. On the other hand, in asymptomatic leaves, the petiole contained higher virus load than the lamella and midrib suggesting that the pathogen gets established from the stem through the phloem into petiole then infects the lamella and midrib. In addition to information on virus movement, the distribution of CMBV in different tissues helps with the selection of tissues with relatively higher viral load to sample for early and sensitive diagnosis of the disease, which will be useful for better management of the disease in endemic areas.

Structural and functional characterisation of a class I endochitinase of the carnivorous sundew (Drosera rotundifolia L.)

Chitinase gene from the carnivorous plant, Drosera rotundifolia , was cloned and functionally characterised. Plant chitinases are believed to play an important role in the developmental and physiological processes and in responses to biotic and abiotic stress. In addition, there is growing evidence that carnivorous plants can use them to digest insect prey. In this study, a full-length genomic clone consisting of the 1665-bp chitinase gene (gDrChit) and adjacent promoter region of the 698 bp in length were isolated from Drosera rotundifolia L. using degenerate PCR and a genome-walking approach. The corresponding coding sequence of chitinase gene (DrChit) was obtained following RNA isolation from the leaves of aseptically grown in vitro plants, cDNA synthesis with a gene-specific primer and PCR amplification. The open reading frame of cDNA clone consisted of 978 nucleotides and encoded 325 amino acid residues. Sequence analysis indicated that DrChit belongs to the class I group of plant chitinases. Phylogenetic analysis within the Caryophyllales class I chitinases demonstrated a significant evolutionary relatedness of DrChit with clade Ib, which contains the extracellular orthologues that play a role in carnivory. Comparative expression analysis revealed that the DrChit is expressed predominantly in tentacles and is up-regulated by treatment with inducers that mimick insect prey. Enzymatic activity of rDrChit protein expressed in Escherichia coli was confirmed and purified protein exhibited a long oligomer-specific endochitinase activity on glycol-chitin and FITC-chitin. The isolation and expression profile of a chitinase gene from D. rotundifolia has not been reported so far. The obtained results support the role of specific chitinases in digestive processes in carnivorous plant species.

Investigating Triticeae anther gene promoter activity in transgenic Brachypodium distachyon

In this report, we demonstrate that Brachypodium distachyon could serve as a relatively high throughput in planta functional assay system for Triticeae anther-specific gene promoters. There remains a vast gap in our knowledge of the promoter cis-acting elements responsible for the transcriptional regulation of Triticeae anther-specific genes. In an attempt to identify conserved cis-elements, 14 pollen-specific and 8 tapetum-specific Triticeae putative promoter sequences were analyzed using different promoter sequence analysis tools. Several cis-elements were found to be enriched in these sequences and their possible role in gene expression regulation in the anther is discussed. Despite the fact that potential cis-acting elements can be identified within putative promoter sequence datasets, determining whether particular promoter sequences can in fact direct proper tissue-specific and developmental gene expression still needs to be confirmed via functional assays preferably performed in closely related plants. Transgenic functional assays with Triticeae species remain challenging and Brachypodium distachyon may represent a suitable alternative. The promoters of the triticale pollen-specific genes group 3 pollen allergen (PAL3) and group 4 pollen allergen (PAL4), as well as the tapetum-specific genes chalcone synthase-like 1 (CHSL1), from wheat and cysteine-rich protein 1 (CRP1) from triticale were fused to the green fluorescent protein gene (GFP) and analyzed in transgenic Brachypodium. This report demonstrates that this model species could serve to accelerate the functional analysis of Triticeae anther-specific gene promoters.

Computational analysis of atpB gene promoter from different Pakistani apple varieties

Apple is the fourth most important fruit crop grown in temperate areas of the world belongs to the family Rosaceae. In the present study, the promoter (∼1000bp) region of atpB gene was used to evaluate the genetic diversity and phylogeny of six local apple varieties. atpB gene is one of the large chloroplastic region which encodes β-subunit of ATP synthase and previously it had been used largely in phylogenetic studies. During the present study, atpB promoter was amplified, sequenced and analyzed using various bioinformatics tools including Place Signal Scan, MEGA6 and BLASTn. During the phylogenetic analysis, obtained phylogram divided the studied varieties into two clusters revealing the monophyletic origin of studied apple varieties. Pairwise distance revealed moderate genetic diversity that ranges from 0.047-0.170 with an average of 0.101. While identifying different cis-acting elements present in the atpB promoter region, results exhibited the occurrence of 56 common and 20 unique cis-regulatory elements among studied varieties. The identified cis-acting regulatory elements were mapped as well. It was observed that Kala Kulu has the highest unique features with reference to the availability of cis-acting elements. Moreover, the possible functions of all regulatory elements present on the promoter sequence of atpB gene were predicted based on already reported information regarding their in vivo role.

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.

Molecular and biochemical characterization of dehydroascorbate reductase from a stress adapted C4 plant, pearl millet [Pennisetum glaucum (L.) R. Br]

KEY MESSAGE

PgDHAR was isolated from Pennisetum glaucum. PgDHAR responded to abiotic stress and exhibited enzyme activity at broad ranges of temperature, pH and substrate concentrations suggesting its role in stress tolerance.

ABSTRACT

Dehydroascorbate reductase (EC 1.8.5.1) is a crucial enzyme actively involved in the recycling of ascorbate redox pool in the cellular environment. In this study, the full-length cDNA coding for DHAR polypeptide and its corresponding gene was isolated from Pennisetum glaucum (PgDHAR). PgDHAR encodes a polypeptide of 213 amino acids with a predicted molecular mass of 23.4 kDa and shares 80-75 % sequence homology with DHAR from other plants. The heterologously expressed recombinant PgDHAR protein exhibited activity in a wide range of substrate concentrations. The recombinant PgDHAR is thermostable and retains its activity over a broad pH range. Furthermore, transcript level of PgDHAR is quantitatively up-regulated in response to temperature. On the whole, PgDHAR alone or in combination with other genes of ascorbate-glutathione cycle can be used for the development of stress tolerant as well as nutritionally improved food crop with enhanced ascorbic acid content.

Functional characterization of a bidirectional plant promoter from cotton leaf curl Burewala virus using an Agrobacterium-mediated transient assay

The C1 promoter expressing the AC1 gene, and V1 promoter expressing the AV1 gene are located in opposite orientations in the large intergenic region of the Cotton leaf curl Burewala virus (CLCuBuV) genome. Agro-infiltration was used to transiently express putative promoter constructs in Nicotiana tabacum and Gossypium hirsutum leaves, which was monitored by a GUS reporter gene, and revealed that the bidirectional promoter of CLCuBuV transcriptionally regulates both the AC1 and AV1 genes. The CLCuBuV C1 gene promoter showed a strong, consistent transient expression of the reporter gene (GUS) in N. tabacum and G. hirsutum leaves and exhibited GUS activity two- to three-fold higher than the CaMV 35S promoter. The CLCuBuV bidirectional gene promoter is a nearly constitutive promoter that contains basic conserved elements. Many cis-regulatory elements (CREs) were also analyzed within the bidirectional plant promoters of CLCuBuV and closely related geminiviruses, which may be helpful in understanding the transcriptional regulation of both the virus and host plant.

Identification and characterization of granule bound starch synthase I (GBSSI) gene of tartary buckwheat (Fagopyrum tataricum Gaertn.)

Tartary buckwheat (Fagopyrum tataricum Gaertn.) is increasingly considered as an important functional food material because of its rich nutraceutical compounds. Reserve starch is the major component of tartary buckwheat seed. However, the gene sequences and the molecular mechanism of tartary buckwheat starch synthesis are unknown so far. In this study, the complete genomic sequence and full-size cDNA coding tartary buckwheat granule-bound starch synthase I (FtGBSSI), which is responsible for amylose synthesis, were isolated and analyzed. The genomic sequence of the FtGBSSI contained 3947 nucleotides and was composed of 14 exons and 13 introns. The cDNA coding sequence of FtGBSSI shared 63.3%-75.1% identities with those of dicots and 56.6%-57.5% identities with monocots (Poaceae). In deduced amino acid sequence of FtGBSSI, eight motifs conserved among plant starch synthases were identified. A cleavage at the site IVC↓G of FtGBSSI protein produces the chloroplast transit sequence of 78 amino acids and the mature protein of 527 amino acids. The FtGBSSI mature protein showed an identity of 73.4%-77.8% with dicot plants, and 67.6%-70.4% with monocot plants (Poaceae). The mature protein was composed of 20 α-helixes and 16 β-strands, and folds into two main domains, N- and C-terminal domains. The critical residues which are involved in ADP and sugar binding were predicted. These results will be useful to modulate starch composition of buckwheat kernels with the aim to produce novel improved varieties in future breeding programs.

Looking for Arabidopsis thaliana peroxidases involved in lignin biosynthesis

Monolignol polymerization into lignin is catalyzed by peroxidases or laccases. Recently, a Zinnia elegans peroxidase (ZePrx) that is considered responsible for monolignol polymerization in this plant has been molecularly and functionally characterized. Nevertheless, Arabidopsis thaliana has become an alternative model plant for studies of lignification, filling the gaps that may occur with Z. elegans. The arabidopsis genome offers the possibility of performing bioinformatic analyses and data mining that are not yet feasible with other plant species, in order to obtain preliminary evidence on the role of genes and proteins. In our search for arabidopsis homologs to the ZePrx, we performed an exhaustive in silico characterization of everything from the protein to the transcript of Arabidopsis thaliana peroxidases (AtPrxs) homologous to ZePrx, with the aim of identifying one or more peroxidases that may be involved in monolignol polymerization. Nine peroxidases (AtPrx 4, 5, 52, 68, 67, 36, 14, 49 and 72) with an E-value greater than 1e-80 with ZePrx were selected for this study. The results demonstrate that a high level of 1D, 2D and 3D homology between these AtPrxs and ZePrx are not always accompanied by the presence of the same electrostatic and mRNA properties that indicate a peroxidase is involved in lignin biosynthesis. In summary, we can confirm that the peroxidases involved in lignification are among AtPrx 4, 52, 49 and 72. Their structural and mRNA features indicate that exert their action in the cell wall similar to ZePrx.

Characterization of a set of novel meiotically-active promoters in Arabidopsis

BACKGROUND

Homologous recombination, together with selection, laid the foundation for traditional plant breeding. The recombination process that takes place during meiotic cell division is crucial for the creation of novel variations of highly desired traits by breeders. Gaining control over this process is important for molecular breeding to achieve more precise, large-scale and quicker plant improvement. As conventional ubiquitous promoters are neither tissue-specific nor efficient in driving gene expression in meiocytes, promoters with high meiotic activities are potential candidates for manipulating the recombination process. So far, only a few meiotically-active promoters have been reported. Recently developed techniques to profile the transcriptome landscape of isolated meiocytes provided the means to discover promoters from genes that are actively expressed in meiosis.

RESULTS

In a screen for meiotically-active promoters, we examined ten promoter sequences that are associated with novel meiotic candidate genes. Each promoter was tested by expressing a GFP reporter gene in Arabidopsis. Characterization of regulatory regions revealed that these meiotically-active promoters possessed conserved motifs and motif arrangement. Some of the promoters unite optimal properties which are invaluable for meiosis-directed studies such as delivering specific gene expression in early meiosis I and/or meiosis II. Furthermore, the examination of homologs of the corresponding genes within green plants points to a great potential of applying the information from Arabidopsis to other species, especially crop plants.

CONCLUSIONS

We identified ten novel meiotically-active promoters; which, along with their homologs, are prime candidates to specifically drive gene expression during meiosis in plants and can thus provide important tools for meiosis study and crop breeding.

Cloning and molecular characterization of a gene encoding late embryogenesis abundant protein from Pennisetum glaucum: protection against abiotic stresses

Late embryogenesis abundant (LEA) protein family is a large protein family that protects other proteins from aggregation due to desiccation or osmotic stresses. A cDNA clone encoding a group 7 late embryogenesis abundant protein, termed PgLEA, was isolated from Pennisetum glaucum by screening a heat stress cDNA library. PgLEA cDNA encodes a 176 amino acid polypeptide with a predicted molecular mass of 19.21 kDa and an estimated isoelectric point of 7.77. PgLEA shares 70-74% sequence identity with other plant homologs. Phylogenetic analysis revealed that PgLEA is evolutionarily close to the LEA 7 group. Recombinant PgLEA protein expressed in Escherichia coli possessed in vitro chaperone activity and protected PgLEA-producing bacteria from damage caused by heat and salinity. Positive correlation existed between differentially up-regulated PgLEA transcript levels and the duration and intensity of different environmental stresses. In silico analysis of the promoter sequence of PgLEA revealed the presence of a distinct set of cis-elements and transcription factor binding sites. Transcript induction data, the presence of several putative stress-responsive transcription factor binding sites in the promoter region of PgLEA, the in vitro chaperone activity of this protein and its protective effect against heat and salt damage in E. coli suggest a role in conferring abiotic stress tolerance in plants.

Signals for pre-mRNA cleavage and polyadenylation

Pre-mRNA cleavage and polyadenylation is an essential step for 3' end formation of almost all protein-coding transcripts in eukaryotes. The reaction, involving cleavage of nascent mRNA followed by addition of a polyadenylate or poly(A) tail, is controlled by cis-acting elements in the pre-mRNA surrounding the cleavage site. Experimental and bioinformatic studies in the past three decades have elucidated conserved and divergent elements across eukaryotes, from yeast to human. Here we review histories and current models of these elements in a broad range of species.

Molecular characterization and expression of a gene encoding cytosolic Hsp90 from Pennisetum glaucum and its role in abiotic stress adaptation

Heat shock protein 90 (Hsp90) is an abundant and highly conserved molecular chaperone that is essential for viability in eukaryotes. They have a crucial role in the folding of a set of proteins involved in the regulation of many essential cellular pathways and also re-folding of stress-denatured polypeptides. However, their exact function is still not clearly elucidated. In this study the full-length cDNA encoding for Hsp90 polypeptide and its corresponding gene was isolated from Pennisetum glaucum (designated PgHsp90). PgHsp90 cDNA encoded for a polypeptide of 698 amino acids with a predicted molecular mass of 80.3kDa and shared a high sequence homology (97-81%) to other plant cytosolic Hsp90s and shared less sequence homology (40-45%) to organelle and endoplasmic reticulum specific Hsp90 isoforms. A deduced amino acid sequence possessed three structural domains: N-terminus (1-211) ATP binding domain, middle (281-540) client protein interacting domain and C-terminus (541-698) dimerization domain; the N-terminus and middle domain is linked by a charged linker domain (212-280). It possesses the five-conserved amino acid signature sequence motifs characteristic of the Hsp90 family and a C-terminus MEEVD penta-peptide characteristic of the cytosolic Hsp90 isoform. The predicted quaternary architecture generated for PgHsp90 through molecular modeling was globally akin to that of yeast Hsp90. The PgHsp90 gene consists of 3 exons and 2 introns. The position and phasing of these introns were conserved in other plant cytosolic Hsp90 genes. Recombinant PgHsp90 protein was expressed in E. coli and purified to homogeneity, which possessed in vitro chaperone activity. E. coli expressing PgHsp90 protein showed enhanced tolerance to heat, salt and dehydration stresses. The quantitative up-regulation of PgHsp90 gene expression positively correlates in response to different stresses to meet the additional demand for protein folding support. Cumulatively, the in vivo and in vitro experiments indicated that PgHsp90 plays an adaptive or protective role to counter the stress induced protein damage.

Production of the 42-kDa fragment of Plasmodium falciparum merozoite surface protein 1, a leading malaria vaccine antigen, in Arabidopsis thaliana seeds

Malaria is widely associated with poverty, and a low-cost vaccine against malaria is highly desirable for implementing comprehensive vaccination programmes in developing countries. Production of malaria antigens in plants is a promising approach, but its development has been hindered by poor expression of the antigens in plant cells. In the present study, we targeted plant seeds as a low-cost vaccine production platform and successfully expressed the Plasmodium falciparum 42-kDa fragment of merozoite surface protein 1 (MSP1₄₂), a leading malaria vaccine candidate, at a high level in transgenic Arabidopsis seeds. We overcame hurdles of transcript and protein instabilities of MSP1₄₂ in plants by synthesizing a plant-optimized MSP1₄₂ cDNA and either targeting the recombinant protein to protein storage vacuoles or fusing it with a stable plant storage protein. An exceptional improvement in MSP1₄₂ expression, from an undetectable level to 5% of total extractable protein, was achieved with these combined strategies. Importantly, the plant-derived MSP1₄₂ maintains its natural antigenicity and can be recognized by immune sera from malaria-infected patients. Our results provide a strong basis for the development of a plant-based, low-cost malaria vaccine.

Molecular cloning and characterization of gene encoding for cytoplasmic Hsc70 from Pennisetum glaucum may play a protective role against abiotic stresses

Molecular chaperones (Hsps) have been shown to facilitate protein folding or assembly under various developmental and adverse environmental conditions. The aim of this study was to unravel a possible role of heat-shock proteins in conferring abiotic stress tolerance to plants. We isolated a cDNA encoding a cytoplasmic Hsp70 (PgHsc70) from Pennisetum glaucum by screening heat-stress cDNA library. PgHsc70 cDNA encoding 649 amino acids represents all conserved signature motifs characteristic of Hsp70s. The predicted molecular model of PgHsc70 protein suggests that the N-terminus ATP-binding region is evolutionarily conserved, in comparison to C-terminus peptide-binding domains. A single intron in ATPase domain coding region of PgHsc70 exhibited a high degree of conservation with respect to its position and phasing among other plant Hsp70 genes. Recombinant PgHsc70 protein purified from E. coli possessed in vitro chaperone activity and protected PgHsc70 expressing bacteria from damage caused by heat and salinity stress. Nucleotide sequence analysis of 5' flanking promoter region of PgHsc70 gene revealed a potential heat-shock element (HSE) and other putative stress-responsive transcription factor binding sites. Positive correlation existed between differentially up-regulated PgHsc70 transcript levels and the duration and intensity of different environmental stresses. Molecular and biochemical analyses revealed that PgHsc70 gene was a member of the Hsp70 family and suggested that its origin was from duplication of a common ancestral gene. Transcript induction data, presence of several putative stress-responsive transcription factor-binding sites in the promoter region of PgHsc70 and the presence of a protective in vitro chaperone activity of this protein against damage caused by heat and salinity, when expressed in E. coli, suggest its probable role in conferring abiotic stress tolerance to this plant.

Cloning and characterization of a cDNA encoding 14-3-3 protein with leaf and stem-specific expression from wheat

The 14-3-3 proteins, originally described as the mammalian brain proteins, are ubiquitous eukaryotic proteins and have been shown to exert an array of function. A great number of 14-3-3 sequences have been reported in Eudicotyledon. The data of 14-3-3 from the monocotyledon plants, however, are limited. In this report, a 14-3-3 cDNA (designated as Ta14A) was isolated from wheat. An extensive search in GenBank database revealed another 14 14-3-3 isoforms from monocotyledonous plants. These proteins plus 14-3-3 isoforms from Arabidopsis were used for phylogenetic reconstruction, which revealed two groups of 14-3-3 proteins in monocotyledonous plants, namely epsilon and non-epsilon, respectively. The epsilon isoforms were present in monocotyledonous plants. Therefore, the gene duplication to result in an epsilon and non-epsilon isoforms was likely to take place before the speciation of monocotyledon and Eudicotyledon plants. Structural analysis indicated that the different conserved domains and structural characters existed in the monocotyledon 14-3-3 isoforms, which will affect their interaction with other effector proteins. Ta14A was strongly expressed in leaf and stem, undetected in root, suggesting it may have the unique functions within these tissues. These data suggest that structure difference and spatial expression of 14-3-3 will be the important factors to confine its functional specificity.

Plant seeds as bioreactors for recombinant protein production

Plants are attractive expression systems for the economic production of recombinant proteins. Among the different plant-based systems, plant seed is the leading platform and holds several advantages such as high protein yields and stable storage of target proteins. Significant advances in using seeds as bioreactors have occurred in the past decade, which include the first commercialized plant-derived recombinant protein. Here we review the current progress on seeds as bioreactors, with focus on the different food crops as production platforms and comprehensive strategies in optimizing recombinant protein production in seeds.

Design of gene constructs for transgenic maize

The first step of any maize transformation project is to select gene expression elements that will make up an effective construct. When designing a gene construct, one must have a full understanding of the different expression elements that are currently available and of the strategies that have been successfully used to overcome obstacles in past. In this chapter, we discuss several major classes of expression elements that have been used for maize transformation, including promoters, introns, and untranslated regions. We also discuss several strategies for further improving transgene expression levels, such as optimization of codon usage, removal of deleterious sequences, addition of signal sequences for subcellular protein targeting, and use of elements to reduce position effects. We hope that this chapter can serve as a general guideline to help researchers, especially beginners in the field, to design a gene construct that will have the maximum potential for gene expression.

Functional analysis of the Arabidopsis thaliana poly(A) binding protein PAB5 gene promoter in Nicotiana tabacum

Poly(A) binding (PAB) proteins play an important role in posttranscriptional regulation by stabilizing mRNA and initiating translation in eukaryotes. Previous studies have shown that the expression of PAB5 gene encoding one of the poly(A) binding proteins (PABPs) in Arabidopsis thaliana is restricted to pollen, ovule and early embryogenesis. To investigate the tissue-specific expression of the PAB5 promoter, a series of promoter deletions (from -1,804, -1,653, -1,334, -1,014, -715, -424 and -175 to +185) were fused to the uidA reporter gene (GUS) and transformed into tobacco plants (Nicotiana tabacum L.). The results showed that GUS expression driven by the full-length PAB5 promoter was detected in floral organs (pollen, ovule, anther, stigma) and immature seeds, but not in vegetative tissues (root, stem, leaf) and mature seeds. Deletion analysis of the PAB5 promoter region revealed that promoters longer than -1,334 had the similar GUS expression level in pollen, ovule and immature seeds, whereas further 5' deletions resulted in a considerable reduction in GUS activity. These results indicated that the region between -1,653 and -1,014 was necessary to direct the tissue-specific expression of PAB5 promoter during development.

MOLECULAR CHARACTERIZATION OF THE LECTIN, BRYOHEALIN, INVOLVED IN PROTOPLAST REGENERATION OF THE MARINE ALGA BRYOPSIS PLUMOSA (CHLOROPHYTA)(1)

When a coenocytic cell of the green alga Bryopsis plumosa (Hudson) C. Agardh was cut open and the cell contents expelled, the cell organelles agglutinated rapidly in seawater to form protoplasts. This process was mediated by a lectin, Bryohealin. The full sequence of the cDNA encoding Bryohealin was obtained, which consisted of 1,101 base pairs (bp), with 24 bp of 5' untranslated region (UTR) and 201 bp of 3' UTR. It had an open reading frame (ORF) of 771 bp encoding 257 amino acid residues. A signal peptide consisted of 22 amino acids presented before the start codon of Bryohealin, indicating that this lectin was a vacuolar (storage) protein. The C-terminal sequence of Bryohealin was composed of antibiotic domains, suggesting that this lectin could perform two functions: (i) aggregation of cell organelles in seawater and (ii) protection from bacterial contamination for successful protoplast regeneration. The BLAST search result showed that Bryohealin had little sequence homology with any known plant lectins, but rather resembled animal lectins with fucolectin domains. The expression of recombinant Bryohealin (rBryohealin) was obtained in the Escherichia coli system.

Reme1, a Copia retrotransposon in melon, is transcriptionally induced by UV light

For the first time, numerous sequences of Copia and Gypsy retrotransposons from the Cucumis melo genome have been obtained and analyzed. Phylogenetic analyses of sequences of both types of long terminal repeat (LTR) retrotransposons were carried out. The melon genome contains approximately 20,000 Gypsy and 6,800 Copia elements, comprising about 26% of its total size. Starting from a retrotransposon fragment, we have cloned and characterized an entire melon retrotransposon, named Reme1, which is 5,149 bp long. Reme1 belongs to the Superfamily Copia retrotransposons by its protein domain order and sequence similarity to other Copia elements of dicotyledons. The haploid genome of melon (var. "Piel de Sapo") contains about 120 copies of Reme1. Several copies of Reme1 are transcriptionally active, although at low levels, in melon leaves as analyzed by reverse-transcription PCR (RT-PCR) and sequencing. However, the transcript pool is considerably increased when melon leaves are treated with UV light, as has been seen for various retroelements in many organisms. The cDNAs of Reme1 transcripts showed less diversity than do Reme1 genomic sequences, suggesting that a subfamily of these elements is differentially responsive to UV.

Molecular cloning, characterization and expression analysis of three aldehyde oxidase genes from Pisum sativum L

Aldehyde oxidase (AO, EC 1.2.3.1) is a molybdenohydroxylase that is considered to catalyze the last step of abscisic acid (ABA) and indole-3-acetic acid (IAA) synthesis. Three cDNAs encoding aldehyde oxidase proteins in Pisum sativum (cv. Little Marvel) were obtained based on RT-PCR (reverse transcriptase-polymerase chain reaction) strategy. The cloned genes, designated as PsAO1, PsAO2 and PsAO3, are 4630, 4347, 4600 bp in length, respectively, and show high sequence identity to each other and to aldehyde oxidases from other plant species. The deduced PsAO1, PsAO2, and PsAO3 proteins are 1373, 1367, 1367 amino acids in length, respectively, and contain consensus sequences for two iron-sulfur centers, a FAD binding domain, and a molybdenum cofactor (Moco) binding domain. PsAO1 and PsAO2 were mainly expressed in leaves of seedlings and young leaves of adult plants, while the highest PsAO3 transcript level was observed in aging leaves and matured seeds. PsAO2 mRNA was not affected by salinity or ammonium treatment, whereas the transcript level of PsAO3 increased significantly under both stress conditions, with the most pronounced changes in aging leaves, fully expanded leaves and roots. The PsAO1 transcript level was enhanced only in the presence of ammonium in the nutrient medium, but not under salinity. Based on the molecular mass of the deduced proteins and on organ-specific gene expression, studied both under control and stress conditions, the contribution of each PsAO cDNA in the formation of the previously described three dimeric pea AO isoforms and the possible involvement of the PsAO3 in abscisic acid (ABA) synthesis is discussed.

Complete genomic sequence of Dracaena mottle virus, a distinct badnavirus

The genome of Dracaena mottle virus (DrMV) was cloned from infected Dracaena sanderiana plants, and its complete nucleotide sequence was determined and analyzed. The circular DNA genome consists of 7531 base pairs (bp) and possesses seven putative open reading frames (ORFs) on the plus-strand that potentially encode proteins of 17.6, 14.9, 215.0, 11.9, 11.3, 16.1, and 11.0 kDa, respectively. ORF 3, the largest ORF, encodes a putative polyprotein that contains sequences for viral aspartyl proteinase, reverse transcriptase (RT) and ribonuclease H (RNase H), characteristic of pararetroviruses. Phylogenetic analysis based on the amino acid sequence of ORF 3 showed that DrMV is related to other badnaviruses. However, the nucleotide sequence coding for the RT and RNase H domain of DrMV shares less than 68% homology with that of any known badnaviruses. The seventh ORF of DrMV is not found in other badnaviruses described before. Our results strongly support that DrMV is a distinct species of the genus Badnavirus, family Caulimoviridae. Evidence that the DrMV sequence is integrated in the D. sanderiana genome is presented and discussed.

Cotton GhDREB1 increases plant tolerance to low temperature and is negatively regulated by gibberellic acid

The transcription factors C-repeat binding factors/dehydration-responsive element binding proteins (CBFs/DREBs) control the expression of many stress-inducible genes in Arabidopsis. A cDNA clone, designated GhDREB1, was isolated from cotton (Gossypium hirsutum) by cDNA library screening. Northern blot analysis indicated that mRNA accumulation of GhDREB1 was induced by low temperatures and salt stress, but was not induced by abscisic acid (ABA) or drought stress in cotton seedlings. Transgenic tobacco (Nicotiana tabacum) plants overexpressing GhDREB1 displayed stronger chilling tolerance than wild-type plants. Their leaf chlorophyll fluorescence, net photosynthetic rate and proline concentrations were higher than those of control plants during low-temperature treatment. However, under normal growth conditions, the transgenic tobacco plants exhibited retarded growth and delayed flowering. Interestingly, GhDREB1 transcripts in cotton seedlings were negatively regulated by gibberellic acid (GA(3)) treatment. Analysis of the promoter of the GhDREB1 gene revealed the presence of one low-temperature and four gibberellin-responsive elements. Green fluorescent protein (GFP) signal intensity or beta-glucuronidase (GUS) activity driven by the GhDREB1 promoter was clearly enhanced by low temperature but repressed by GA(3). These results suggest that GhDREB1 functions as a transcription factor and plays an important role in improving cold tolerance, and also affects plant growth and development via GA(3).

Cloning and characterization of a cDNA encoding Ran binding protein from wheat

Ran, which functions in nucleocytoplasmic transport and mitosis, binds to and is regulated in part by Ran binding protein (RanBP). A RanBP cDNA (TaRanBP1) was isolated from a wheat cDNA library using RT-PCR product as a probe. The predicted amino acid sequence of TaRanBP1 is over 60% identity to AtRanBP1 from Arabidopsis and also with considerable similarity to human and fungi RanBPs. TaRanBP1 gene was expressed ubiquitously in roots, leaves and stems, with a similar abundance in these tissues. Phylogenetic reconstruction of TaRanBP1 with 32 other RanBPs from 26 species of organisms revealed that RanBPs from plants, animals and fungi clustered as the distinct groups, intraspecies isoforms were not developed for RanBPs, contrast with most other ancestral genes. Structural analysis revealed that all RanBPs were highly conserved in the middle region of their amino acid sequence, which included Ran binding domain and the three conserved motifs that have the essential roles in binding with Ran protein and promotion of GTP hydrolysis by the Ran/RanGAP/RanBP complex. However, N-terminus and C-terminus exhibited very low similarity between the different RanBPs. The different structures in N-terminus and C-terminus of RanBPs are likely to direct the Ran into the specific physiological processes and subsequently exhibit the different roles in different organisms.

Xylem-specific and tension stress-responsive coexpression of KORRIGAN endoglucanase and three secondary wall-associated cellulose synthase genes in aspen trees

In nature, angiosperm trees develop tension wood on the upper side of their leaning trunks and drooping branches. Development of tension wood is one of the straightening mechanisms by which trees counteract leaning or bending of stem and resume upward growth. Tension wood is characterized by the development of a highly crystalline cellulose-enriched gelatinous layer next to the lumen of the tension wood fibers. Thus experimental induction of tension wood provides a system to understand the process of cellulose biosynthesis in trees. Since KORRIGAN endoglucanases (KOR) appear to play an important role in cellulose biosynthesis in Arabidopsis, we cloned PtrKOR, a full-length KOR cDNA from aspen xylem. Using RT-PCR, in situ hybridization, and tissue-print assays, we show that PtrKOR gene expression is significantly elevated on the upper side of the bent aspen stem in response to tension stress while KOR expression is significantly suppressed on the opposite side experiencing compression stress. Moreover, three previously reported aspen cellulose synthase genes, namely, PtrCesA1, PtrCesA2, and PtrCesA3 that are closely associated with secondary cell wall development in the xylem cells exhibited similar tension stress-responsive behavior. Our results suggest that coexpression of these four proteins is important for the biosynthesis of highly crystalline cellulose typically present in tension wood fibers. Their simultaneous genetic manipulation may lead to industrially relevant improvement of cellulose in transgenic crops and trees.

Lily pollen alkaline phytase is a histidine phosphatase similar to mammalian multiple inositol polyphosphate phosphatase (MINPP)

Phytic acid is the most abundant inositol phosphate in cells; it constitutes 1-5% of the dry weight of cereal grains and legumes. Phytases are the primary enzymes responsible for the hydrolysis of phytic acid and thus play important roles in inositol phosphate metabolism. A novel alkaline phytase in lily pollen (LlALP) was recently purified in our laboratory. In this paper, we describe the cloning and characterization of LlALP cDNA from lily pollen. Two isoforms of alkaline phytase cDNAs, LlAlp1 and LlAlp2, which are 1467 and 1533 bp long and encode proteins of 487 and 511 amino acids, respectively, were identified. The deduced amino acid sequences contains the signature heptapeptide of histidine phosphatases, -RHGXRXP-, but shares < 25% identity to fungal histidine acid phytases. Phylogenetic analysis reveals that LlALP is most closely related to multiple inositol polyphosphate phosphatase (MINPP) from humans (25%) and rats (23%). mRNA corresponding to LlAlp1 and LlAlp2 were expressed in leaves, stem, petals and pollen grains. The expression profiles of LlAlp isoforms in anthers indicated that mRNA corresponding to both isoforms were present at all stages of flower development. The expression of LlAlp2 cDNA in Escherichia coli revealed the accumulation of the active enzyme in inclusion bodies and confirmed that the cDNA encodes an alkaline phytase. In summary, plant alkaline phytase is a member of the histidine phosphatase family that includes MINPP and exhibits properties distinct from bacterial and fungal phytases.

Xylem-specific and tension stress-responsive coexpression of KORRIGAN endoglucanase and three secondary wall-associated cellulose synthase genes in aspen trees

In nature, angiosperm trees develop tension wood on the upper side of their leaning trunks and drooping branches. Development of tension wood is one of the straightening mechanisms by which trees counteract leaning or bending of stem and resume upward growth. Tension wood is characterized by the development of a highly crystalline cellulose-enriched gelatinous layer next to the lumen of the tension wood fibers. Thus experimental induction of tension wood provides a system to understand the process of cellulose biosynthesis in trees. Since KORRIGAN endoglucanases (KOR) appear to play an important role in cellulose biosynthesis in Arabidopsis, we cloned PtrKOR, a full-length KOR cDNA from aspen xylem. Using RT-PCR, in situ hybridization, and tissue-print assays, we show that PtrKOR gene expression is significantly elevated on the upper side of the bent aspen stem in response to tension stress while KOR expression is significantly suppressed on the opposite side experiencing compression stress. Moreover, three previously reported aspen cellulose synthase genes, namely, PtrCesA1, PtrCesA2, and PtrCesA3 that are closely associated with secondary cell wall development in the xylem cells exhibited similar tension stress-responsive behavior. Our results suggest that coexpression of these four proteins is important for the biosynthesis of highly crystalline cellulose typically present in tension wood fibers. Their simultaneous genetic manipulation may lead to industrially relevant improvement of cellulose in transgenic crops and trees.

Biochemical characterization of a cinnamoyl-CoA reductase from wheat

Cinnamoyl-CoA reductase (CCR) is responsible for the CoA ester-->aldehyde conversion in monolignol biosynthesis, which can divert phenylpropanoid-derived metabolites into the biosynthesis of lignin. To gain a better understanding of lignin biosynthesis in wheat (Triticum aestivum L.), a cDNA encoding CCR was isolated and named Ta-CCR2. DNA hybridization analyses demonstrated that the Ta-CCR2 gene exists in three copies in the wheat genome. RNA blot hybridization indicated that Ta-CCR2 was expressed most abundantly in root and stem tissues that were in the process of lignification. The secondary and three-dimensional structures of Ta-CCR2 were analyzed by molecular modeling. Recombinant Ta-CCR2 protein purified from E. coli converted feruloyl CoA, 5-OH-feruloyl CoA, sinapoyl CoA and caffeoyl CoA with almost similar efficiency, suggesting that it is involved in both G and S lignin synthesis. Ta-CCR2 had a very low V max value for 4-coumaroyl CoA, which may serve as a mechanism to control metabolic flux to H lignin in vivo . Furthermore, the reaction mechanism of Ta-CCR2 was analyzed in relation to its possible three-dimensional structure. The activity of Ta-CCR2 in relation to lignin biosynthesis is discussed.

Characterization of a jasmonate-regulated wheat protein related to a beta-glucosidase-aggregating factor

Jasmonates are distributed throughout higher plants, where they play an important role in the activation of signal transduction pathways in response to wounding and pathogen attack. Jasmonates are known to induce the transcriptional activation of plant defense genes, produce jasmonate-regulated proteins (JRP). One class of 32 kDa JRP (designated as JRP-32 in this paper) is present in the Gramineae family, although the function of these proteins is still unclear. A cDNA was cloned from wheat (Triticum aestivum L.) and designated as Ta-JA1. Sequence comparison indicated that Ta-JA1 encodes a JRP-32 protein. Ta-JA1 exists as a single-copy gene, but other genes with low sequence similarity to Ta-JA1 may be present in the wheat genome. The expression of Ta-JA1 was confined to stem tissues and barely detected in leaf and root tissues. Western blot analyses demonstrated that the recombinant Ta-JA1 protein cross-reacts with maize beta-glucosidase-aggregating factor (BGAF) antibody. Molecular modeling showed that Ta-JA1 and BGAF have a very similar three-dimensional structure. Protein structure analysis indicated that Ta-JA1 together with some related proteins (maize BGAF, wheat Ver2, WCI-1 and Hfr-1) contain two functional domains: a disease response domain and jacalin-related lectin (JRL) domain. A mannose-binding site was also well conserved in these proteins. The data support the hypothesis that JRP-32 and related proteins from Gramineae form a small protein family related to JRLs. This small protein family may have evolved from mannose-specific jacalin-related lectins (mJRLs) by developing a disease response domain in their N-terminus, which may have broadened the functional role of these proteins to include the plant defense response.

The complex developmental expression of a novel stress-responsive barley Ltp gene is determined by a shortened promoter sequence

The search for a cereal promoter capable of driving preferential transgene expression in the pericarp epidermis (epicarp) of developing barley (Hordeum vulgare L.) resulted in the cloning of a novel gene. This encoded a polypeptide of 124 amino acids showing 87 identity with WBP1A, a wheat lipid transfer protein (LTP), but much lower homology to other barley LTPs. In addition to the epicarp, this Ltp-like gene, Ltp6, is highly expressed in coleoptiles and embryos under normal growth conditions. Messenger RNA levels increased in seedling tissues during salt and cold treatments and under applied abscisic acid (ABA) and salicylic acid (SA). Taken together, Ltp6 tissue-specific and response patterns are distinct from other known barley Ltp genes. Inverse PCR was used to derive 2345 bp of upstream Ltp6 sequence. The level of transcription conferred by different promoter deletion constructs was assessed by quantitative real time RT-PCR using gfp as a reporter in transient expression assays. All constructs containing at least 192 bp of upstream sequence and the 5'UTR conferred tissue-specific expression and retained most of the promoter strength. Deletion of 64 bp (-192/-128) from this upstream sequence reduced expression levels by 80. Moreover, a minimal 247 bp Ltp6 promoter continuously drove gfp expression during spike development, from early ovary differentiation through its final expression in the epicarp and during embryogenesis and germination in transgenic barley, reproducing the expression pattern of the native gene. The potential use of this promoter sequence for targeting transgene-mediated disease resistance in barley and wheat is discussed.

A single complementary-sense transcript of a geminiviral DNA beta satellite is determinant of pathogenicity

Small circular single-stranded DNA satellites, termed DNAbeta, have recently been found associated with some geminivirus infections. The DNA beta associated with Cotton leaf curl virus is responsible for symptom expression of a devastating disease in Pakistan. Mutagenesis of DNA beta revealed that the complementary-sense open reading frame (ORF) betaC1 is required for inducing disease symptoms in Nicotiana tabacum. An ORF present on the virion-sense strand betaV1 appeared to have no role in pathogenesis. Tobacco plants transformed with a betaC1 ORF under the control of the Cauliflower mosaic virus 35S promoter or with a dimeric DNA beta exhibited severe disease-like phenotypes, while plants transformed with a mutated version of betaC1 appeared normal. Northern blot analysis of RNA from the transgenic plants, using strand-specific probes, identified a single complementary-sense transcript. The transcript carries the full betaC1 ORF encoding a 118-amino acid product. It maps to the DNA beta at nucleotide position 186 to 563 and contains a polyadenylation signal 18 nt upstream of the stop codon. A TATA box is located 43 nt upstream of the start codon. Our results indicate that betaC1 protein is responsible for DNA beta-induced disease symptoms.

The Nicotiana sylvestris extensin gene, Ext 1.2A, is expressed in the root transition zone and upon wounding

The Ext 1.2A gene of Nicotiana sylvestris L. encoding an extensin, a cell wall structural protein, was characterized. Ext 1.2A encodes a polypeptide of 311 amino acids having a highly repetitive structure and showing extensin features such as Ser-(Pro)(4) repeats and a high content of Tyr and Lys. The expression profile of the gene was demonstrated using the reporter GUS (beta-glucuronidase) fused to its promoter region (-630/+124, relative to the transcription start site) and by RNA gel blots. The results show that the (-630/+124) Ext 1.2A/GUS gene fusion is expressed in the root transition zone, where cells undergo an isodiametric growth but have not yet reached the rapid elongation phase, in stem inner and outer phloems and in cortical cells at the stem/petiole junction. The Ext 1.2A gene is also induced after wounding of stems, ribs, leaves or roots. The gene fusion is expressed in stem cortical cells, in ribs and at leaf edges upon wounding. These data suggest that the (-630/+124) promoter region contains regulatory elements responsible for expression in roots and stems, as well as for response to wounding in stems and leaves.

Isolation and characterization of a single-copy actin gene from a sterile mutant of Ulva pertusa (Ulvales, Chlorophyta)

We constructed a cDNA library from sterile Ulva pertusa (Ulvales, Chlorophyta), and isolated and characterized a full-length cDNA clone encoding actin. The actin (ACT) cDNA consisted of 1487 nucleotides (nt) and had an open reading frame (ORF) encoding a polypeptide of 377 amino acid (AA) residues. The ACT gene had one intron in the 5'-untranslated region and three introns in the coding region. Transcription started 26 nt downstream of the putative TATA box. A potential polyadenylation signal, TGTAG, was located 100 nt downstream of the terminator codon, TAG. Amino acid alignment with actins from various algae and land plants showed that sterile U. pertusa actin was more similar to actins from Chlorophyta, Phaeophyta, Euglenophyta, and higher plants (over 76.9%) than to actins from Rhodophyta. Southern blot analysis indicated that the sterile U. pertusa genome has only a single actin-encoding gene. Thalli grown on a 12D/12L photoperiod increased in surface area some two-fold over 24 h regardless of the nutritional conditions. The growth rate of thalli during the light period was significantly higher than that during the dark period. Northern hybridization indicated that the expression of actin mRNA was induced and repressed by the light and dark treatments, respectively. These results suggest that the U. pertusa cell division cycle has a periodicity of 24 h and that the ACT gene is highly transcribed during cell growth and development in the light period.

The pea END1 promoter drives anther-specific gene expression in different plant species

END1 was isolated by an immunosubtractive approach intended to identify specific proteins present in the different pea (Pisum sativum L.) floral organs and the genes encoding them. Following this strategy we obtained a monoclonal antibody (mAbA1) that specifically recognized a 26-kDa protein (END1) only detected in anther tissues. Northern blot assays showed that END1 is expressed specifically in the anther. In situ hybridization and immunolocalization assays corroborated the specific expression of END1 in the epidermis, connective, endothecium and middle layer cells during the different stages of anther development. END1 is the first anther-specific gene isolated from pea. The absence of a practicable pea transformation method together with the fact that no END1 homologue gene exists in Arabidopsis prevented us from carrying out END1 functional studies. However, we designed functional studies with the END1 promoter in different dicot species, as the specific spatial and temporal expression pattern of END1 suggested, among other things, the possibility of using its promoter region for biotechnological applications. Using different constructs to drive the uidA (beta-glucuronidase) gene controlled by the 2.7-kb isolated promoter sequence we have proven that the END1 promoter is fully functional in the anthers of transgenic Arabidopsis thaliana (L.) Heynh., Nicotiana tabacum L. (tobacco) and Lycopersicon esculentum Mill. (tomato) plants. The presence in the -330-bp region of the promoter sequence of three putative CArG boxes also suggests that END1 could be a target gene of MADS-box proteins and that, subsequently, it would be activated by genes controlling floral organ identity.

Characterization of a cytosolic malate dehydrogenase cDNA which encodes an isozyme toward oxaloacetate reduction in wheat

Malate dehydrogenase (MDH), which is ubiquitous in nature, catalyzes the interconversion of oxaloacetate and malate. Higher plants contain multiple forms of MDH that differ in co-enzyme specificity, subcellular localization and physiological function. Cytosolic NAD-dependent MDH (cyMDH) is one class of MDH that has not been extensively characterized in plants. Here we report the cloning of a cDNA from wheat by RT-PCR and cDNA library screening, which is designated as TaMDH. Sequence analysis indicated that TaMDH exhibits a highly similarity to other plant cyMDHs. Immunological analysis confirmed that TaMDH encoded a cytosolic NAD-dependent MDH. The secondary and three-dimensional structures of TaMDH were analyzed by molecular modeling. DNA gel-blot analyses demonstrated that TaMDH gene exists as two copies in the wheat genome. RNA and protein gel-blot hybridization indicated that both TaMDH mRNA and protein were constitutively expressed in vegetative tissues of wheat, with slightly lower levels in roots than in leaves and stems. In silico analysis indicated that TaMDH was also expressed in various reproductive tissues and tissues under many different stress conditions. Kinetic analysis of bacterially expressed and purified protein confirmed that TaMDH catalyzed a reaction driven towards malate synthesis, which is consistent with other cyMDHs. Evolutionary analysis showed that this class of genes evolved from a very ancestral gene. The cyMDH represents an ancestral form of MDH, which is highly conserved in plants, animals and bacteria. This implies that cyMDHs are housekeeping genes and may have very essential functions in plant metabolism.

The salt-stress signal transduction pathway that activates the gpx1 promoter is mediated by intracellular H2O2, different from the pathway induced by extracellular H2O2

Several genes encoding putative glutathione peroxidase have been isolated from a variety of plants, all of which show the highest homology to the phospholipid hydroperoxide isoform. Several observations suggest that the proteins are involved in biotic and abiotic stress responses. Previous studies on the regulation of gpx1, the Citrus sinensis gene encoding phospholipid hydroperoxide isoform, led to the conclusion that salt-induced expression of gpx1 transcript and its encoded protein is mediated by oxidative stress. In this paper, we describe the induction of gpx1 promoter:uidA fusions in stable transformants of tobacco (Nicotiana tabacum) cultured cells and plants. We show that the induction of gpx1 by salt and oxidative stress occurs at the transcriptional level. gpx1 promoter analysis confirmed our previous assumption that the salt signal is transduced via oxidative stress. We used induction of the fusion construct to achieve better insight into, and to monitor salt-induced oxidative stress. The gpx1 promoter responded preferentially to oxidative stress in the form of hydrogen peroxide, rather than to superoxide-generating agents. Antioxidants abolished the salt-induced expression of gpx1 promoter, but were unable to eliminate the induction by H2O2. The commonly employed NADPH-oxidase inhibitor diphenyleneiodonium chloride and catalase inhibited the H2O2-induced expression of gpx1 promoter, but did not affect its induction by salt. Our results led us to conclude that salt induces oxidative stress in the form of H2O2, its production occurs in the intracellular space, and its signal transduction pathway activating the gpx1 promoter is different from the pathway induced by extracellular H2O2.

The cotton GhNHX1 gene encoding a novel putative tonoplast Na(+)/H(+) antiporter plays an important role in salt stress

A cDNA clone was isolated from cotton (Gossypium hirsutum) cDNA library and characterized with regard to its sequence, regulation in response to salt stress and functions in yeast mutants and transgenic tobacco plants. The clone, designated as GhNHX1, contains 2485 nucleotides with an open reading frame of 1629 nucleotides, and the deduced amino acid sequence showed high identities with other plant vacuolar-type Na(+)/H(+) antiporters. Northern blot analysis indicated that the mRNA accumulation of GhNHX1 was strongly induced by salt stress and abscisic acid in cotton seedlings. The expression of GhNHX1 in yeast Na(+)/H(+) antiporter mutant showed function complementation. The transgenic tobacco plants overexpressing GhNHX1 also had higher salt tolerance than the wild-type plants. The salt-induced mRNA level of GhNHX1 was 3 and 7 times higher in the salt-tolerant cotton cultivar ZM3 than those in the salt-sensitive cotton cultivars ZMS17 and ZMS12, respectively. Together, these results suggest that the products of the novel gene, GhNHX1, function as a tonoplast Na(+)/H(+) antiporter and play an important role in salt tolerance of cotton.

Differential expression of six novel peroxidase cDNAs from cell cultures of sweetpotato in response to stress

Six peroxidase (POD) cDNAs were isolated from suspension cultures of sweetpotato (Ipomoea batatas) by cDNA library screening, and their expression was investigated with a view to understanding the physiological functions of each POD in relation to environmental stress. The gene products encoded by these cDNAs could be divided into two groups, anionic PODs (SWPA4, SWPA5, SWPA6) and basic PODs (SWPB1, SWPB2, SWPB3), on the basis of the predicted pI values of the mature proteins. RT-PCR analysis revealed that the six POD genes showed diverse expression patterns in various tissues of intact plants, a various stages of growth in suspension cultures, and in leaf tissues exposed to different stresses. The six genes from which they were derived are predominantly expressed in cultured cells of sweetpotato. Thus, transcripts of swpa4 were not detected in any tissues of the intact plant. The genes swpa6 and swpb1 were highly expressed in root tissues, whereas swpa6 and swpb3 were highly expressed in stem tissues. During suspension culture, the expression patterns of the six genes differed from each other. The level of swpa4, swpa5, swpb2 and swpb3 transcripts progressively increased during culture, whereas swpa6 and swpb1 showed high expression levels regardless of the age of the culture. In leaf tissues the six POD genes responded differently to various abiotic stresses. In particular, swpa4 was highly induced by several abiotic stresses, including exposure to hydrogen peroxide (440 mM) or NaCl (100 mM), and wounding of leaf tissues, suggesting that this POD gene is inducible by many stresses. Based on the different expression patterns of these POD genes, we propose that each POD may have different enzymatic properties and physiological functions during cell growth and development.

Identification and expression of a soybean nodule-enhanced PEP-carboxylase kinase gene (NE-PpcK) that shows striking up-/down-regulation in vivo

Various isoforms of plant phosphoenolpyruvate carboxylase (PEPC (Ppc)) are controlled post-translationally by an intricate interaction between allosteric regulation and reversible protein phosphorylation. In leaves and root nodules of legumes, these changes in PEPC phosphorylation state are governed primarily by PEPC-kinase (PpcK), a novel, 'minimal but functional' Ser/Thr kinase. To date, this plant-specific kinase has been investigated in molecular terms exclusively in non-leguminous plants, such as Crassulacean-acid-metabolism (CAM) species and Arabidopsis. As an important extension of our earlier biochemical studies on this dedicated kinase and PEPC phosphorylation in soybean (Glycine max) nodules, we now report the molecular cloning of the first legume PpcK from a soybean nodule cDNA library, which encodes a functional, 31.0 kDa PpcK polypeptide. Besides displaying organ, developmental, and spatial expression properties that are strikingly up-regulated in mature nodules, the expression pattern of this transcript is distinct from that of a second soybean PpcK isogene (GmPpcK). The steady-state abundance of this former, nodule-enhanced transcript (NE-PpcK) is markedly influenced by photosynthate supply from the shoots. This latter up-/down-regulation of NE-PpcK transcript level occurs in vivo in concert with the corresponding changes in the nodule PpcK activity, the phosphorylation-state of PEPC, and the abundance of a previously identified, nodule-enhanced transcript (GmPEPC7) that encodes the target enzyme (NE-Ppc). Furthermore, genomic Southern analysis and inspection of the public database indicate that there are at least three distinct PpcK and Ppc isogenes in soybean. Collectively, these and recent findings with Arabidopsis implicate the existence of multiple PpcK-Ppc'expression-partners' in plants, exemplified by NE-PpcK and NE-Ppc in the soybean nodule.

VH1, a provascular cell-specific receptor kinase that influences leaf cell patterns in Arabidopsis

The formation of the venation pattern in leaves is ideal for examining signaling pathways that recognize and respond to spatial and temporal information, because the pattern is two-dimensional and heritable and the resulting veins influence the three-dimensional spatial organization of the surrounding differentiating leaf cell types. We identified a provascular/procambial cell-specific gene that encodes a Leu-rich repeat receptor kinase, which we named VASCULAR HIGHWAY1 (VH1). A change in the expression domain and level of VH1 marks the transition from an uncommitted provascular state to a committed procambial state in early vascular development. The coding sequence, expression pattern, and transgenic phenotypes together suggest that VH1 transduces extracellular spatial and temporal signals into downstream cell differentiation responses in provascular/procambial cells.

Isolation and characterization of a novel ribosome-inactivating protein from root cultures of pokeweed and its mechanism of secretion from roots

Ribosome-inactivating proteins are N-glycosidases that remove a specific adenine from the sarcin/ricin loop of the large rRNA, thus arresting protein synthesis at the translocation step. In the present study, a novel type I ribosome-inactivating protein, termed PAP-H, was purified from Agrobacterium rhizogenes-transformed hairy roots of pokeweed (Phytolacca americana). The protein was purified by anion- and cation-exchange chromatography. PAP-H has a molecular mass of 29.5 kD as detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and its isoelectric point was determined to be 7.8. Yeast (Saccharomyces cerevisiae) ribosomes incubated with PAP-H released the 360-nucleotide diagnostic fragment from the 26S rRNA upon aniline treatment, an indication of its ribosome-inactivating activity. Using immunofluorescence microscopy, PAP-H was found to be located in the cell walls of hairy roots and root border cells. PAP-H was determined to be constitutively secreted as part of the root exudates, with its secretion enhanced by a mechanism mediated by ethylene induction. Purified PAP-H did not show in vitro antifungal activity against soil-borne fungi. In contrast, root exudates containing PAP-H as well as additional chitinase, beta-1,3-glucanase, and protease activities did inhibit the growth of soil-borne fungi. We found that PAP-H depurinates fungal ribosomes in vitro and in vivo, suggesting an additive mechanism that enables PAP-H to penetrate fungal cells.

Isolation and characterization of a novel ribosome-inactivating protein from root cultures of pokeweed and its mechanism of secretion from roots

Ribosome-inactivating proteins are N-glycosidases that remove a specific adenine from the sarcin/ricin loop of the large rRNA, thus arresting protein synthesis at the translocation step. In the present study, a novel type I ribosome-inactivating protein, termed PAP-H, was purified from Agrobacterium rhizogenes-transformed hairy roots of pokeweed (Phytolacca americana). The protein was purified by anion- and cation-exchange chromatography. PAP-H has a molecular mass of 29.5 kD as detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and its isoelectric point was determined to be 7.8. Yeast (Saccharomyces cerevisiae) ribosomes incubated with PAP-H released the 360-nucleotide diagnostic fragment from the 26S rRNA upon aniline treatment, an indication of its ribosome-inactivating activity. Using immunofluorescence microscopy, PAP-H was found to be located in the cell walls of hairy roots and root border cells. PAP-H was determined to be constitutively secreted as part of the root exudates, with its secretion enhanced by a mechanism mediated by ethylene induction. Purified PAP-H did not show in vitro antifungal activity against soil-borne fungi. In contrast, root exudates containing PAP-H as well as additional chitinase, beta-1,3-glucanase, and protease activities did inhibit the growth of soil-borne fungi. We found that PAP-H depurinates fungal ribosomes in vitro and in vivo, suggesting an additive mechanism that enables PAP-H to penetrate fungal cells.

A new cellulose synthase gene (PtrCesA2) from aspen xylem is orthologous to Arabidopsis AtCesA7 (irx3) gene associated with secondary cell wall synthesis

We report here the molecular cloning and characterization of a new full-length cellulose synthase (CesA) cDNA, PtrCesA2 from aspen (Populus tremuloides) trees. The predicted PtrCesA2 protein shows a high degree of identity/similarity (87%/91%) to the predicted gene product of Arabidopsis AtCesA7 gene that has been associated with secondary cell wall development. Previously, a mutation in AtCesA7 gene (irx3) was correlated with a significant decrease in the amount of cellulose synthesized (about 70%) and genetic complementation of irx3 mutant with a wild-type AtCesA7 gene restored the normal phenotype. This is the first report of a full-length AtCesA7 ortholog from any non-Arabidopsis species. Interestingly, PtrCesA2 shares only 64% identity with our earlier reported PtrCesA1 from aspen suggesting its structural distinctness from the only other known CesA member from the aspen genome. PtrCesA1 is a xylem-specific and tension stress responsive gene that is highly similar to another Arabidopsis gene, AtCesA8 which also has been associated with secondary wall development. Moreover, AtCesA7 and AtCesA8 are suggested to be part of the same cellulose synthase complex. Isolation of PtrCesA2 from a xylem library enriched in cells with active secondary wall synthesis, PtrCesA2 expression levels similar to PtrCesA1 and high similarity of PtrCesA1 and PtrCesA2 to AtCesA8 and AtCesA7, respectively, suggest that both these aspen genes might be involved in the secondary wall development in aspen woody tissues. Availability of two aspen CesA orthologs will now enable us to examine if PtrCesA1 and PtrCesA2 functionally interact during aspen wood development that has long-term implications on genetic improvement of forest trees.