Cloning and sequence of a cDNA encoding a novel hybrid proline-rich protein associated with cytokinin-induced haustoria formation in Cuscuta reflexa

Genome-Wide Identification of PRP Genes in Apple Genome and the Role of MdPRP6 in Response to Heat Stress

Plant proline-rich proteins (PRPs) are cell wall proteins that occur in the plant kingdom and are involved in plant development and stress response. In this study, 9 PRP genes were identified from the apple genome and a comprehensive analysis of the PRP family was conducted, including gene structures, phylogenetic analysis, chromosome mapping, and so on. The expression of MdPRPs varied among tissues and in response to different types of stresses. MdPRP4 and MdPRP7 were induced by five detected stress treatments, including heat, drought, abscisic acid, cold, and salt; the expression patterns of the others varied under different types of stress. Subcellular localization showed that MdPRPs mainly functioned in the cytoplasm, except for MdPRP1 and MdPRP5, which also functioned in the nucleus. When MdPRP6 was overexpressed in tobacco, the transgenic plants showed higher tolerance to high temperature (48 °C) compared with wild-type (WT) plants. The transgenic plants showed milder wilting, a lower accumulation of electrolyte leakage, MDA and ROS, and a higher level of chlorophyll and SOD and POD activity, indicating that MdPRP6 may be an important gene in apples for heat stress tolerance. Overall, this study suggested that MdPRPs are critically important for the ability of apple responses to stresses.

Nitric oxide mediates cold- and dehydration-induced expression of a novel MfHyPRP that confers tolerance to abiotic stress

Hybrid proline-rich proteins (HyPRPs) are cell wall-localized proteins, and are frequently responsive to environmental stresses. The coding sequence of a HyPRP cDNA was isolated from Medicago falcata, a forage crop that shows cold and drought tolerance. The predicted MfHyPRP contains a proline-rich domain at N-terminus after the signal peptide and a conserved eight-cysteine motif at the C-terminus. Higher level of MfHyPRP transcript was observed in leaves than in stems and roots under control conditions, while more MfHyPRP transcript was induced in leaves and stems than in roots after cold treatment. Levels of MfHyPRP transcript and MfHyPRP protein in leaves were induced by cold, dehydration, abscisic acid (ABA), hydrogen peroxide (H2 O2) and nitric oxide (NO), but not responsive to salt stress. The cold- or dehydration-induced expression of MfHyPRP was blocked by scavenger of NO, but not affected by inhibitor of ABA biosynthesis or scavenger of H2 O2. The results indicated that NO, but not ABA and H2 O2, was essential in the cold- and dehydration-induced expression of MfHyPRP. Overexpression of MfHyPRP in tobacco led to increased tolerance to freezing, chilling and osmotic stress as well as methyl viologen-induced oxidative stress. The increased cold and osmotic stress tolerance was proposed to be associated with improved protection against oxidative damages. It is suggested that NO mediates cold- and dehydration-induced expression of MfHyPRP that confers tolerance to abiotic stress.

Expression of pigeonpea hybrid-proline-rich protein encoding gene (CcHyPRP) in yeast and Arabidopsis affords multiple abiotic stress tolerance

A hybrid-proline-rich protein encoding gene (CcHyPRP) has been isolated and characterized, for the first time, from the subtracted cDNA library of pigeonpea (Cajanus cajan L.) plants subjected to drought stress. Functionality of CcHyPRP has been validated for abiotic stress tolerance using the heterologous yeast and Arabidopsis systems. The CcHyPRP contained a repetitive proline-rich (PR) N-terminal domain and a conserved eight cysteine motif (8CM) at the C-terminus. Southern analysis disclosed single-copy nature of CcHyPRP gene in the pigeonpea genome. Northern analysis revealed higher levels of CcHyPRP transcripts in PEG, NaCl, heat (42 degrees C), cold and ABA-treated plants compared with the weak signals observed in the untreated plants, suggesting stress-responsive nature of the CcHyPRP gene. In yeast, expression of CcHyPRP imparted marked tolerance against abiotic stresses exerted by PEG, high temperature, NaCl and LiCl. Transgenic Arabidopsis lines, expressing CcHyPRP under the control of CaMV35S and rd29A promoters, when subjected to PEG, mannitol, NaCl, LiCl and heat (42 degrees C) stress, developed into healthy plants with profuse root system and increased biomass in contrast to the weak-stunted wild-type plants. The CcHyPRP-transgenics driven by stress-inducible rd29A exhibited similar stress-tolerance as that of CaMV35S-lines without any negative effects on plant morphology, implying that stress-inducible promoters are preferable for production of stress tolerant transgenics. The overall results amply demonstrate the profound effect of CcHyPRP in bestowing multiple abiotic stress tolerance at cellular and whole plant levels. Accordingly, the multipotent CcHyPRP seems promising as a prime candidate gene to fortify crop plants with abiotic stress tolerance.

Isolation and characterization of a new defense gene from soybean

A cDNA clone of a single-copy gene designated SbPRP was isolated and characterized from 2-week-old soybean seedlings. It putatively encodes a bimodular protein similar to developmentally regulated proteins in other plant species. The deduced amino acid sequence consists of 126 amino acids with a distinct proline-rich domain (17 amino acids) and a long hydrophobically cysteine-rich domain (84 amino acids), plus a signal peptide of 25 amino acids in N terminal. SbPRP mRNA transcripts accumulated in an organ specific manner. It can be detected in leaves and epicotyls of soybean seedlings, whereas virtually expression signal of SbPRP was not detected in cotyledons, hypocotyls and roots. Further Northern hybridization suggested that SbPRP steady-state mRNA level accumulated differentially not only in response to salicylic acid, but to the inoculation of soybean mosaic virus Sa strain. Also it was responsive to drought treatment and salt (NaCl) stress. Therefore it is likely that SbPRP functions as a defense gene in soybean.

Analysis of the hybrid proline-rich protein families from seven plant species suggests rapid diversification of their sequences and expression patterns

Background

Plant hybrid proline-rich proteins (HyPRPs) are putative cell wall proteins consisting, usually, of a repetitive proline-rich (PR) N-terminal domain and a conserved eight-cysteine motif (8 CM) C-terminal domain. Understanding the evolutionary dynamics of HyPRPs might provide not only insight into their so far elusive function, but also a model for other large protein families in plants.

Results

We have performed a phylogenetic analysis of HyPRPs from seven plant species, including representatives of gymnosperms and both monocot and dicot angiosperms. Every species studied possesses a large family of 14–52 HyPRPs. Angiosperm HyPRPs exhibit signs of recent major diversification involving, at least in Arabidopsis and rice, several independent tandem gene multiplications. A distinct subfamily of relatively well-conserved C-type HyPRPs, often with long hydrophobic PR domains, has been identified. In most of gymnosperm (pine) HyPRPs, diversity appears within the C-type group while angiosperms have only a few of well-conserved C-type representatives. Atypical (glycine-rich or extremely short) N-terminal domains apparently evolved independently in multiple lineages of the HyPRP family, possibly via inversion or loss of sequences encoding proline-rich domains. Expression profiles of potato and Arabidopsis HyPRP genes exhibit instances of both overlapping and complementary organ distribution. The diversified non-C-type HyPRP genes from recently amplified chromosomal clusters in Arabidopsis often share their specialized expression profiles. C-type genes have broader expression patterns in both species (potato and Arabidopsis), although orthologous genes exhibit some differences.

Conclusion

HyPRPs represent a dynamically evolving protein family apparently unique to seed plants. We suggest that ancestral HyPRPs with long proline-rich domains produced the current diversity through ongoing gene duplications accompanied by shortening, modification or loss of the proline-rich domains. Most of the diversity in gymnosperms and angiosperms originates from different branches of the HyPRP family. Rapid sequence diversification is consistent with only limited requirements for structure conservation and, together with high variability of gene expression patterns, limits the interpretation of any functional study focused on a single HyPRP gene or a couple of HYPRP genes in single plant species.

Proline-rich cell wall proteins accumulate in growing regions and phloem tissue in response to water deficit in common bean seedlings

Plant cell walls undergo dynamic changes in response to different environmental stress conditions. In response to water deficit, two related proline-rich glycoproteins, called p33 and p36, accumulate in the soluble fraction of the cell walls in Phaseolus vulgaris (Covarrubias et al. in Plant Physiol 107:1119-1128, 1995). In this work, we show that p33 and p36 are able to form a 240 kDa oligomer, which is found in the cell wall soluble fraction. We present evidence indicating that the highest accumulation of these proteins in response to water deficit occurs in the growing regions of common bean seedlings, particularly in the phloem tissues. These proteins were detected in P. vulgaris cell suspension cultures, where the p33/p36 ratio was higher under hyperosmotic conditions than in bean seedlings subjected to the same treatment. The results support a role for these proteins during the plant cell response to changes in its water status, and suggest that cell wall modifications are induced in active growing cells of common bean in response to water limitation.

Plant molecular biology and biotechnology research in the post-recombinant DNA era

After the beginning of the recombinant DNA era in the mid-1970s, researchers in India started to make use of the new technology to understand the structure of plant genes and regulation of their expression. The outcome started to appear in print in early the 1980s and genes for histones, tubulin, photosynthetic membrane proteins, phototransduction components, organelles and those regulated differentially by developmental and extrinsic signals were sequenced and characterized. Some genes of biotechnological importance like those encoding an interesting seed protein and the enzyme glyoxalase were also isolated. While work on the characterization of genome structure and organization was started quite early, it remained largely focused on the identification of DNA markers and genetic variability. In this context, the work on mustard, rice and wheat is worth mentioning. In the year 2000, India became a member of the international consortium to sequence entire rice genome. Several laboratories have also given attention to regulated expression of plastid and nuclear genes as well as to isolate target-specific promoters or design promoters with improved potential. Simultaneously, transgenic systems for crops like mustard, rice, wheat, cotton, legumes and several vegetables have been established. More recently, genes of agronomic importance like those for insect resistance, abiotic stress tolerance, nutritional improvement and male sterility, isolated in India or abroad, have been utilized for raising transgenics for crop improvement. Some of these transgenics have already shown their potential in containment facility or limited field trials conducted under the stipulated guidelines. Plant molecular biology and biotechnology are thus clearly poised to make an impact on research in basic biology and agriculture in the near future.

Lambda exonuclease-based subtractive hybridization approach to isolate differentially expressed genes from leaf cultures of Paulownia kawakamii

Genes that are preferentially expressed in a particular developmental pathway can be isolated by subtractive hybridization (SH). We developed a PCR-based approach coupled with lambda exonuclease digestion that allows for generating single-stranded tester and driver nucleic acids suitable for SH starting from cDNA libraries. An efficient subtraction strategy was developed to overcome some of the problems in the previously described SH protocols, such as the need for large amounts of experimental tissue, RNase contamination during solution hybridization, and postsubtraction recovery of nucleic acids. We used this method to obtain cDNA corresponding to genes expressed during adventitious shoot regeneration from excised leaf cultures of the fast-growing tree Paulownia kawakamii. Over 36 cDNA clones were isolated and 1 of the differentially expressed clones codes for a leucine zipper transcription factor. This clone showed about sixfold higher level of expression in the shoot-forming tissues (tester) compared to that in the callus-forming tissues (driver) of Paulownia, suggesting that differentially expressed genes can be efficiently isolated using this simple lambda exonuclease-based subtractive hybridization method.

In vivo evaluation of the context sequence of the translation initiation codon in plants

Statistical analysis of the AUG initiation codon context in several plant organisms identified a nucleotide preference in some positions around the AUG. Sixteen AUG contexts were studied using transient expression in tobacco, maize and Norway spruce. Besides the importance of A or G at position -3, we revealed the role of positions -2, -1 for which AA or CC were found to be the best for tobacco and maize, respectively. GC (positions +4, +5) were also found to be important in both tobacco and maize. Finally, we identified a variation in context efficiency according to cell type, since A was better than G at position -3 in tobacco leaf protoplasts, while both nucleotides were equally efficient in tobacco suspension cells.

Host-root exudates increase gene expression of asparagine synthetase in the roots of a hemiparasitic plant Triphysaria versicolor (Scrophulariaceae)

Triphysaria is a facultative root parasite in the Scrophulariaceae family. Similar to other related parasites, the development of the parasitic life cycle is initiated by molecular signals released from appropriate host roots. Using a differential display, we isolated cDNAs preferentially abundant in T. versicolor roots exposed to Trifolium repens (white clover) root exudates in vitro. Sequence analysis indicated that one of the differentially expressed cDNAs had significant homology to the nitrogen-assimilating enzyme, asparagine synthetase (AS). T. versicolor AS cDNA clones were isolated and placed into three distinct classes on the basis of nucleotide sequence variations. All three classes encoded identical AS proteins. AS was expressed in both roots and shoots of in-vitro-cultured T. versicolor. Steady-state levels of AS mRNA increased in T. versicolor roots several-fold when seedlings were exposed to exudate obtained from hydroponically grown Arabidopsis thaliana roots. Therefore, AS transcript levels increased in response to exudates from two different hosts (Trifolium and Arabidopsis). The T. versicolor AS message levels increased to a similar magnitude when seedlings were incubated in the dark. Interestingly, AS levels were unaffected by treatment with the Striga haustoria inducer 2,6-dimethoxybenzoquinone. The potential role of AS in root parasitism is discussed.

Post-transcriptional regulation of a salt-inducible alfalfa gene encoding a putative chimeric proline-rich cell wall protein

A cDNA previously shown to identify a salt-inducible root-specific transcript in Medicago sativa was used to screen an alfalfa library for the corresponding genomic sequence. One positive clone was recovered. The nucleotide sequence of a subclone contained a 329 bp 5' region upstream of the first ATG codon, a 1143 bp coding segment, and a 447 bp 3'-untranslated region interrupted by a single 475 bp intron. Translation of the coding segment, which was designated MsPRP2, suggested it encodes a chimeric 40,569 Da cell wall protein with an amino-terminal signal sequence, a repetitive proline-rich sequence, and a cysteine-rich carboxyl-terminal sequence homologous to nonspecific lipid transfer proteins. The 3'-untranslated region of MsPRP2 contained a sequence similar to one found to destabilize mRNAs transcribed from the elicitor-regulated proline-rich protein gene PvPRP1. Transcription run-on experiments using nuclei from salt-sensitive and salt-tolerant alfalfa callus suggested that the accumulation of MsPRP2 transcripts in salt-tolerant alfalfa cells grown in the presence of salt is due primarily to increased mRNA stability. The MsPRP2 gene thus may be a useful model for studying post-transcriptional salt-regulated expression of cell wall proteins.

The cDNA sequence of cytochrome b5 associated with cytokinin-induced haustoria formation in Cuscuta reflexa

A cDNA clone isolated by differentially screening a cytokinin-induced haustorial cDNA library of Cuscuta reflexa was sequenced and identified as the gene coding for cytochrome b5, based on the similarity of the deduced amino-acid sequence with that of the cauliflower (60% identity) and tobacco (78% identity) proteins. The 5'-UTR is unusually long (720 bp) and contains 14 potential start codons (ATG) and 10 short ORFs.