Water Transport Properties of the Grape Pedicel during Fruit Development: Insights into Xylem Anatomy and Function Using Microtomography.

Xylem flow of water into fruits declines during fruit development, and the literature indicates a corresponding increase in hydraulic resistance in the pedicel. However, it is unknown how pedicel hydraulics change developmentally in relation to xylem anatomy and function. In this study on grape (Vitis vinifera), we determined pedicel hydraulic conductivity (kh) from pressure-flow relationships using hydrostatic and osmotic forces and investigated xylem anatomy and function using fluorescent light microscopy and x-ray computed microtomography. Hydrostatic kh (xylem pathway) was consistently 4 orders of magnitude greater than osmotic kh (intracellular pathway), but both declined before veraison by approximately 40% and substantially over fruit development. Hydrostatic kh declined most gradually for low (less than 0.08 MPa) pressures and for water inflow and outflow conditions. Specific kh (per xylem area) decreased in a similar fashion to kh despite substantial increases in xylem area. X-ray computed microtomography images provided direct evidence that losses in pedicel kh were associated with blockages in vessel elements, whereas air embolisms were negligible. However, vessel elements were interconnected and some remained continuous postveraison, suggesting that across the grape pedicel, a xylem pathway of reduced kh remains functional late into berry ripening.

Polarity of water transport across epidermal cell membranes in Tradescantia virginiana.

Using the automated cell pressure probe, small and highly reproducible hydrostatic pressure clamp (PC) and pressure relaxation (PR) tests (typically, applied step change in pressure = 0.02 MPa and overall change in volume = 30 pL, respectively) were applied to individual Tradescantia virginiana epidermal cells to determine both exosmotic and endosmotic hydraulic conductivity (L(p)(OUT) and L(p)(IN), respectively). Within-cell reproducibility of measured hydraulic parameters depended on the method used, with the PR method giving a lower average coefficient of variation (15.2%, 5.8%, and 19.0% for half-time, cell volume [V(o)], and hydraulic conductivity [L(p)], respectively) than the PC method (25.4%, 22.0%, and 24.2%, respectively). V(o) as determined from PC and PR tests was 1.1 to 2.7 nL and in the range of optically estimated V(o) values of 1.5 to 4.9 nL. For the same cell, V(o) and L(p) estimates were significantly lower (about 15% and 30%, respectively) when determined by PC compared with PR. Both methods, however, showed significantly higher L(p)(OUT) than L(p)(IN) (L(p)(OUT)/L(p)(IN) ≅ 1.20). Because these results were obtained using small and reversible hydrostatically driven flows in the same cell, the 20% outward biased polarity of water transport is most likely not due to artifacts associated with unstirred layers or to direct effects of externally applied osmotica on the membrane, as has been suggested in previous studies. The rapid reversibility of applied flow direction, particularly for the PR method, and the lack of a clear increase in L(p)(OUT)/L(p)(IN) over a wide range of L(p) values suggest that the observed polarity is an intrinsic biophysical property of the intact membrane/protein complex.

Water uptake along the length of grapevine fine roots: developmental anatomy, tissue-specific aquaporin expression, and pathways of water transport.

To better understand water uptake patterns in root systems of woody perennial crops, we detailed the developmental anatomy and hydraulic physiology along the length of grapevine (Vitis berlandieri × Vitis rupestris) fine roots from the tip to secondary growth zones. Our characterization included the localization of suberized structures and aquaporin gene expression and the determination of hydraulic conductivity (Lpr) and aquaporin protein activity (via chemical inhibition) in different root zones under both osmotic and hydrostatic pressure gradients. Tissue-specific messenger RNA levels of the plasma membrane aquaporin isogenes (VvPIPs) were quantified using laser-capture microdissection and quantitative polymerase chain reaction. Our results highlight dramatic changes in structure and function along the length of grapevine fine roots. Although the root tip lacked suberization altogether, a suberized exodermis and endodermis developed in the maturation zone, which gave way to the secondary growth zone containing a multilayer suberized periderm. Longitudinally, VvPIP isogenes exhibited strong peaks of expression in the root tip that decreased precipitously along the root length in a pattern similar to Arabidopsis (Arabidopsis thaliana) roots. In the radial orientation, expression was always greatest in interior tissues (i.e. stele, endodermis, and/or vascular tissues) for all root zones. High Lpr and aquaporin protein activity were associated with peak VvPIP expression levels in the root tip. This suggests that aquaporins play a limited role in controlling water uptake in secondary growth zones, which contradicts existing theoretical predictions. Despite having significantly lower Lpr, woody roots can constitute the vast majority of the root system surface area in mature vines and thus provide for significant water uptake potential.

Comprehensive developmental profiles of gene activity in regions and subregions of the Arabidopsis seed.

Seeds are complex structures that consist of the embryo, endosperm, and seed-coat regions that are of different ontogenetic origins, and each region can be further divided into morphologically distinct subregions. Despite the importance of seeds for food, fiber, and fuel globally, little is known of the cellular processes that characterize each subregion or how these processes are integrated to permit the coordinated development of the seed. We profiled gene activity genome-wide in every organ, tissue, and cell type of Arabidopsis seeds from fertilization through maturity. The resulting mRNA datasets offer the most comprehensive description of gene activity in seeds with high spatial and temporal resolution,providing unique insights into the function of understudied seed regions. Global comparisons of mRNA populations reveal unexpected overlaps in the functional identities of seed subregions. Analyses of coexpressed gene sets suggest that processes that regulate seed size and filling are coordinated across several subregions. Predictions of gene regulatory networks based on the association of transcription factors with enriched DNA sequence motifs upstream of coexpressed genes identify regulators of seed development. These studies emphasize the utility of these data sets as an essential resource for the study of seed biology.

Genomic cloning and characterization of a PPA gene encoding a mannose-binding lectin from Pinellia pedatisecta.

A gene encoding a mannose-binding lectin, Pinellia pedatisecta agglutinin (PPA), was isolated from leaves of Pinellia pedatisecta using genomic walker technology. The ppa contained an 1140-bp 5'-upstream region, a 771-bp open reading frame (ORF) and an 829-bp 3'-downstream region. The ORF encoded a precursor polypeptide of 256 amino acid residues with a 24-amino acid signal peptide. There were one putative TATA box and six possible CAAT boxes lying in the 5'-upstream region of ppa. The ppa showed significant similarity at the nucleic acid level with genes encoding mannose-binding lectins from other Araceae species such as Pinellia ternata, Arisaema hererophyllum, Colocasia esculenta and Arum maculatum. At the amino acid level, PPA also shared varying homology (ranging from 40% to 85%) with mannose-binding lectins from other plant species, such as those from Araceae, Alliaceae, Iridaceae, Lillaceae, Amaryllidaceae and Bromeliaceae. The cloning of the ppa gene not only provides a basis for further investigation of PPA's structure, expression and regulation mechanism, but also enables us to test its potential role in controlling pests and fungal diseases by transferring the gene into tobacco and rice in the future.

Genomic cloning and characterization of a PPA gene encoding a mannose-binding lectin from Pinellia pedatisecta

A gene encoding a mannose-binding lectin, Pinellia pedatisecta agglutinin (PPA), was isolated from leaves of Pinellia pedatisecta using genomic walker technology. The ppa contained an 1140-bp 5'-upstream region, a 771-bp open reading frame (ORF) and an 829-bp 3'-downstream region. The ORF encoded a precursor polypeptide of 256 amino acid residues with a 24-amino acid signal peptide. There were one putative TATA box and six possible CAAT boxes lying in the 5'-upstream region of ppa. The ppa showed significant similarity at the nucleic acid level with genes encoding mannose-binding lectins from other Araceae species such as Pinellia ternata, Arisaema heterophyllum, Colocasia esculenta and Arum maculatum. At the amino acid level, PPA also shared varying homology (ranging from 40% to 85%) with mannose-binding lectins from other plant species, such as those from Araceae, Alliaceae, Iridaceae, Lillaceae, Amaryllidaceae and Bromeliaceae. The cloning of the ppa gene not only provides a basis for further investigation of PPA's structure, expression and regulation mechanism, but also enables us to test its potential role in controlling pests and fungal diseases by transferring the gene into tobacco and rice in the future

A novel pathogenesis-related protein (SsPR10) from Solanum surattense with ribonucleolytic and antimicrobial activity is stress- and pathogen-inducible.

A cDNA clone (designated as SsPR10, GenBank Accession Number AY660753 ) encoding a PR10 protein from yellow-fruit nightshade (Solanum surattense) was isolated and characterized. SsPR10 encoded a 160-amino-acid polypeptide with a predicted molecular mass of 17.58 kDa and pI of 5.29. Sequence alignments showed that SsPR10 had high identity (68.1%) with CaPR10, but had only about 31.7% identity with JIOsPR10 at the amino acid level. Genomic DNA gel blot analysis indicated that SsPR10 belonged to a multigene family. The constitutively expressed SsPR10 was detected to be the highest in roots of the sterile seedlings cultured in jars, while SsPR10 expression was the highest in old yellow leaves from the seedlings incubated with sap containing TMV. SsPR10 always expressed at slightly higher level in senescent leaves than in tender ones under both conditions. Further expression analysis revealed that the signaling components of defense/stress pathways (MeJA, SA, ABA, GA3, H2O2 and Cu2+) up-regulated significantly the SsPR10 mRNA levels over the control. However, darkness failed to induce SsPR10 expression and its expression was also inhibited by cold treatment. The SsPR10 was successfully expressed in Eschericha coli and the expressed protein was purified to near homogeneity. The dialytically renatured SsPR10 protein without phosphorylation exhibited ribonucleolytic activity against S. surattense leaf total RNA preparations and could inhibit hyphal growth of Pyricularia oryzae. Our findings suggest that the novel stress- and pathogen-inducible SsPR10 with ribonucleolytic and antimicrobial activity participates not only in the defense/stress response pathways but also in plants' growth, development and senescence.

Cloning and characterization of an agglutinin gene from Arisaema lobatum.

A novel agglutinin gene was cloned from Arisaema lobatum using SMART RACE-PCR technology. The full-length cDNA of Arisaema lobatum agglutinin (ala) was 1078 bp and contained a 774 bp open reading frame encoding a lectin precursor (proproprotein) of 258 amino acid residues with a 23 aa signal peptide. ALA contained three mannose-binding sites (QXDXNXVXY) with two-conserved domains of 45% identity, ALA-DOM1 and ALA-DOM2. The three-dimensional structure of ALA was very similar to that of GNA (Galanthus nivalis agglutinin). ALA shared varying identities, ranging from 40% to 85%, with mannose-binding lectins from other species of plant families, such as Araceae, Alliaceae, Iridaceae, Lillaceae, Amaryllidaceae and Bromeliaceae. Genomic sequence of ala was also cloned using genomic walker technology, and it was found to contain three putative TATA boxes and eight possible CAAT boxes in the 5'-flanking region. No intron was found within the region of genomic sequence. Southern blot analysis indicated that the ala belonged to a multi-copy gene family. Expression pattern analysis revealed that the ala preferentially expressed in the tissues with the higher expression being found in spadix, bud, leaf, spathe and tuber. The cloning of the ala gene not only provides a basis for further investigation of its structure, expression and regulation mechanism, but also enables us to test its potential role in controlling pests and fungal diseases by transferring the gene into plants in the future.

Genomic cloning and characterization of a Pto-like gene SsPto-2 from Solanum surattense.

A Pto-like gene (designated as SsPto-2) was isolated from Solanum surattense by using genomic walker technology which encoded a cytoplasmically localized serine-threonine protein kinase. Analysis of the 2365 bp segment revealed a gene including a 905 bp 5' flanking region, a 924 bp open reading frame (ORF) and a 536 bp 3' flanking region. The deduced amino acid sequence of the SsPto-2 gene shared high homology with other known Ptos. The deduced SsPto-2 protein contained no signal peptide with a calculated molecular weight of 34.61 kDa. The analysis of SsPto-2 promoter region and terminator region was also presented. Semi-quantitative reverse transcription-polymerase chain reaction (RT-PCR) analysis revealed that SsPto-2 transcripts were up-regulated by defense-related factors such as gibberellic acid (GA(3)), salicylic acid (SA) and down-regulated by darkness. The cloning of the SsPto-2 gene will allow us to further study its potential role in disease resistance.

An efficient method for rapid amplification of Arisaema heterophyllum agglutinin gene using a genomic walking technique.

The genomic sequence of Arisaema heterophyllum agglutinin (AHA), a mannose-binding lectin (MBL), was cloned through a novel genomic walking technique. Adaptor ligation reactions and subsequent amplifications with adaptor primer and multiple specific primers were used to generate specificity in this method. The method allowed for the amplification of over 1 kb of genomic DNA sequence immediately upstream and downstream from the 5' and 3' ends of full-length cDNAs. For aha gene, the upstream regions contained a putative transcription initiation start site and other sequences commonly found in eukaryotic promoters. The downstream regions of aha contained two polyadenylation signals. Our study demonstrated that aha had no intron like mannose-binding lectin genes cloned from other plant species so far. This efficient method, based on a genomic walking technique, was useful for the cloning of promoters, insertion sites, and other sequences of interest without constructing and screening genomic libraries.

Isolation and characterization of an IAA-responsive gene from Gossypium barbadense L.

The full-length cDNA of an IAA-responsive gene was cloned from Gossypium barbadense L. (designated as Gbiaa-Re) by rapid amplification of cDNA ends (RACE). Gbiaa-Re gene was 1043-bp long and contained a 573-bp open reading frame encoding a polypeptide of 190 amino acid residues. Homology analysis revealed that Gbiaa-Re strongly resembled known plant IAA-responsive genes. The conserved integrated domain "AUX_IAA, AUX/IAA family" resided within the region from L11, to V190 of GbIAA-RE, and the 4 typically conserved domains of IAA-responsive gene family were all found in GbIAA-RE. The secondary structure of GbIAA-RE consisted of 20.53% alpha helix, 13.68% extended strand and 65.79% random coil. In total, 12 phosphorylation sites, 1 N-glycosylation site and 4 O-beta-GlcNAc attachment sites were predicted. Southern blot analysis indicated that Gbiaa-Re belonged to a low-copy gene family. Semi-quantitative PCR analysis indicated that the expression of Gbiaa-Re gene was inducible by IAA. Our studies suggested that Gbiaa-Re was a new member of plant AUX/IAA gene family.

CDNA cloning and characterization of the Ve homologue gene StVe from Solanum torvum Swartz.

Verticillium wilt is a disastrous disease causing significant yield losses of many crops. Isolation of verticillium wilt resistance gene is a fundamental work for controlling this disease through genetic engineering. In this report, we describe the cloning and characterization of a Ve like gene (StVe) from Solanum torvum Swartz. The nucleotide sequence of StVe is 3640 bp long with an open reading frame of 3414 bp encoding a protein precursor of 1138 aa. Sharing high homologies to tomato verticillium wilt disease resistance genes Ve1 and Ve2, the leucine rich (15.89%) protein StVe has a calculated molecular weight of 126.48kDa with an isoelectric point of 5.62. It possesses a hydrophobic N-terminal signal peptide of 20 aa and 38 predicted leucine-rich repeats containing 32 potential N-glycosylation sites (28 being significant). Fifty-seven predicted phosphorylation sites (36 for S, 8 for T and 13 for Y) distribute in StVe protein. A PEST-like sequence and a mammalian endocytosis signals YCVF are found within the C-terminal region. The C terminus of StVe concludes with the residues KKF similar to the KKX motif that confers endoplasmic reticulum localization in plants as well as mammals and yeast. The sequence analysis of the StVe gene implies that the StVe is a potential verticillium wilt disease resistance gene encoding a cell surface-like receptor protein.

Isolation and characterization of a serine/threonine protein kinase SOS2 gene from Brassica napus.

A full-length cDNA of a new serine/threonine (Ser/Thr) protein kinase gene, designated as BnSOS2 (GenBank Acc. No.AY310413), was cloned from Brassica napus by rapid amplification of cDNA ends (RACE). The full-length cDNA of BnSOS2 was 1779 bp and contained a 1539-bp open reading frame encoding a protein of 512 amino acids. Homology analysis shows that BnSOS2 strongly resembles other Ser/Thr protein kinase genes, and that its putative protein belongs to a typical Ser/Thr kinase family. Northern blot analysis reveals that BnSOS2 is salt-inducible. Our results indicate that BnSOS2 is a new member of the plant SOS2 gene family, which may play an important role in salt tolerance of plants.

Molecular cloning and characterization of a novel mannose-binding lectin gene from Amorphophallus konjac.

A new lectin gene was cloned from Amorphophallus konjac. The full-length cDNA of Amorphophallus konjac agglutinin (aka) was 736 bp and contained a 474 bp open reading frame encoding a 158 amino acid protein. Homology analysis revealed that the lectin from this Araceae species belonged to the superfamily of monocot mannose-binding proteins. Molecular modeling of AKA indicated that the three-dimensional structure of AKA strongly resembles that of the snowdrop lectin. Southern blot analysis of the genomic DNA revealed that aka belonged to a low-copy gene family. Northern blot analysis demonstrated that aka expression was tissue-specific with the strongest expression being found in root.

Molecular cloning and characterization of a novel lectin gene from Zephyranthes candida.

A new lectin gene was cloned from Zephyranthes candida by using RACE-PCR. The full-length cDNA of Zephyranthes candida agglutinin (ZCA) was 647 bp and contained a 477 bp open reading frame encoding a 159 amino acid protein. Zephyranthes candida lectin gene was found to encode a precursor lectin with signal peptide and had extensive homology with those of other plant lectins. Molecular modeling of ZCA indicated that the three-dimensional structure of ZCA strongly resembles that of the snowdrop lectin, implying ZCA may have the similar insecticidal functions with GNA.