Roberto Ruiz-Medrano

The phloem as a conduit for inter-organ communication

The plant vascular system plays a pivotal role in the delivery of nutrients to distantly located organs. Recent discoveries have provided new insight into a novel role for plasmodesmata and the phloem in terms of the transport and delivery of information macromolecules (i.e. proteins and ribonucleoprotein complexes). Non-cell/organ-autonomous control over gene expression may function both in defense signaling and developmental programming in plants.

Phylogenetic and Structural Analysis of Translationally Controlled Tumor Proteins

The translationally controlled tumor protein (TCTP) is conserved in all eukaryotes studied thus far. Recent evidence points to an important role for TCTP in the induction of cell proliferation in animals through an interaction with G proteins. TCTP may also constitute an intercellular secreted signal that modulates the immune response in the vertebrates. Because of its sequence conservation and ubiquity, the analysis of its amino acid sequence divergence between different taxa may provide insight into the structural constraints on the evolution of this protein. In the present study, we analyzed the phylogeny of TCTP sequences from a wide range of organisms and found that, with some exceptions, the groupings formed were consistent with the evolutionary history. Indeed, at the level of lower-order taxa, the groupings are in agreement with their established phylogeny, thus indicating that the substitution rates of the TCTP residues varied evenly between members of the same clade. Predicted three-dimensional structures of representative TCTPs, based on the reported 3D structure of Schizosaccharomyces pombe, indicated that these proteins are highly conserved among diverse taxonomic groups. However, analysis of the primary structure indicated subtle differences in the domain-forming pocket that potentially interacts with G proteins, particularly among Diplomonadidae, Apicomplexa, and other parasites of vertebrates. These differences support the notion that these specific TCTPs could block the normal immune response by acting as dominant negative mutants. Structural differences were also observed in a reported sequence of TCTP from Plasmodium knowlesi, in which the presence of an extra α-helix could also interfere in the interaction with G proteins.

Nucleotide sequence of an osmotin-like cDNA induced in tomato during viroid infection.

A cDNA library from tomato planta macho viroid (TPMV)-infected tomato was constructed. The library was screened at low stringency with a tobacco PR-R cDNA probe. An 832 bp cDNA from a mRNA present only in infected tissue was isolated. Nucleotide sequence showed high homology with the osmotin from both tobacco and tomato (NP24). This cDNA probably corresponds to the AP24 and P23 proteins previously described in tomato and induced upon fungal and viroid infection.

Influence of cucumber mosaic virus infection on the mRNA population present in the phloem translocation stream of pumpkin plants

The effect of cucumber mosaic virus (CMV) infection on the phloem sap mRNA population was investigated in pumpkin Cucurbita maxima Duch. cv. Big Max, through analysis of a suppressive subtractive hybridisation (SSH) library. Analysis of the infected phloem library identified 91 highly diverse mRNA species, including enzymes involved in general metabolism, transcription factors and signalling agents. Our analysis indicated that, quantitatively, the effect of CMV infection on the composition of the phloem sap transcriptome was minor in nature. Virtual northern analysis was used to confirm the specific upregulation of these transcripts in the phloem of CMV-infected plants. In silico northern analysis also confirmed that none of the transcripts identified in the SSH library was contained in the population of mRNA species present in the phloem sap of healthy plants. Induction levels ranged from low to high and in situ hybridisation studies showed that transcripts displayed a range of accumulation patterns. Collectively, our findings suggest that plants have evolved a highly robust mechanism for the exchange of information macromolecules between the companion cell (CC) and the sieve tube system. Production of viral movement protein (MP) in the CC is not sufficient for the indiscriminate transport of mRNA into the sieve element. Our findings are discussed in the context of symptom development and likely strong selection pressure, on the viral genome, to encode for a MP that does not adversely interfere with the phloem long-distance trafficking system.

Selective inhibition of cytosine‐DNA methylases by polyamines

We have advanced the hypothesis that polyamines affect DNA methylation and thus promote the expression of developmentally controlled genes. We demonstrate that the activity of cytosine‐DNA methyltransferases HpaII, HhaI, HaeIII and SssI is inhibited by physiological concentrations of polyamines. On the other hand, activity of the adenine‐DNA methyltransferase EcoRI, and restriction enzymes HpaII, HhaI, HaeIII and EcoRI, is insensitive to polyamine concentrations up to 40 mM. Our results indicate that the effect of polyamines on cytosine‐DNA methyltranferases is rather selective and suggest a possible mode of action in vivo.

Vascular expression in Arabidopsis is predicted by the frequency of CT/GA‐rich repeats in gene promoters

Phloem-transported signals play an important role in regulating plant development and in orchestrating responses to environmental stimuli. Among such signals, phloem-mobile RNAs have been shown to play an important role as long-distance signaling agents. At maturity, angiosperm sieve elements are enucleate, and thus transcripts in the phloem translocation stream probably originate from the nucleate companion cells. In the present study, a pumpkin (Cucurbita maxima) phloem transcriptome was used to test for the presence of common motifs within the promoters of this unique set of genes, which may function to coordinate expression in cells of the vascular system. A bioinformatics analysis of the upstream sequences from 150 Arabidopsis genes homologous to members of the pumpkin phloem transcriptome identified degenerate sequences containing CT/GA- and GT/CA-rich motifs that were common to many of these promoters. Parallel studies performed on genes shown previously to be expressed in phloem tissues identified similar motifs. An expanded analysis, based on homologs of the pumpkin phloem transcriptome from cucumber (Cucumis sativus), identified similar sets of common motifs within the promoters of these genes. Promoter analysis offered support for the hypothesis that these motifs regulate expression within the vascular system. Our findings are discussed in terms of a role for these motifs in coordinating gene expression within the companion cell/sieve element system. These motifs could provide a useful bioinformatics tool for genome-wide screens on plants for which phloem tissues cannot readily be obtained.

Cloning and expression of a novel, moderately thermostable xylanase-encoding gene (Cfl xyn11A) from Cellulomonas flavigena

The Cfl xyn11A gene, encoding the endo-1,4-beta-xylanase Cfl Xyn11A from Cellulomonas flavigena, was isolated from a genomic DNA library. The open reading frame of the Cfl xyn11A gene was 999 base pairs long and encoded a polypeptide (Cfl Xyn11A) of 332 amino acids with a calculated molecular mass of 35,110Da. The Cfl xyn11A gene was expressed in Escherichia coli and the recombinant enzyme, with an estimated molecular weight of 31kDa was purified and xylanase activity was measured. Cfl Xyn11A showed optimal activity at pH 6.5 and 55 degrees C. The enzyme demonstrated moderate thermal stability as Cfl Xyn11A maintained 50% of its activity when incubated at 55 degrees C for 1h or at 45 degrees C for 6h. This is the first report describing the cloning, expression and functional characterization of an endo-1,4-beta-xylanase-encoding gene from C. flavigena. Cfl Xyn11A may be suitable for industrial applications in the food and feed industries, or in the pre-treatment of lignocellulosic biomass required to improve the yields of fermentable sugars for bioethanol production.

Isolation of dehydration-responsive genes in a drought tolerant common bean cultivar and expression of a group 3 late embryogenesis abundant mRNA in tolerant and susceptible bean cultivars

Drought is one of the main constraints for common bean (Phaseolus vulgaris L.) production in Latin America. The aim of this work was to identify upregulated genes in the drought-tolerant common bean cv. Pinto Villa, grown under water-deficit conditions. Twenty-eight cDNAs representing differentially-expressed mRNAs in roots and/or leaves were isolated via suppression subtractive hybridisation. Their expression profiles in plants under intermediate and severe dehydration stress were tested. Three cDNAs corresponded to genes already described as associated to drought stress in P. vulgaris, 12 were known P. vulgaris sequences without previous association with drought response, and 13 were new P. vulgaris sequences. Analysis of the deduced proteins encoded by the cDNAs revealed putative functions in cellular protection, sugar metabolism, and protein synthesis, folding and turnover. Additionally, a new member of group 3 late embryogenesis abundant (LEA) genes (PvLEA3) was cloned and its complete sequence was obtained. Given the lack of reports comparing expression of dehydration-responsive genes in bean cultivars with different response to drought, the expression of PvLEA3 transcript in five bean cultivars from different origin was analysed. The induction of PvLEA3 was directly associated with the level of drought tolerance in the cultivars studied.

Characterization of a Proposed Dichorhavirus Associated with the Citrus Leprosis Disease and Analysis of the Host Response

The causal agents of Citrus leprosis are viruses; however, extant diagnostic methods to identify them have failed to detect known viruses in orange, mandarin, lime and bitter orange trees with severe leprosis symptoms in Mexico, an important citrus producer. Using high throughput sequencing, a virus associated with citrus leprosis was identified, belonging to the proposed Dichorhavirus genus. The virus was termed Citrus Necrotic Spot Virus (CNSV) and contains two negative-strand RNA components; virions accumulate in the cytoplasm and are associated with plasmodesmata—channels interconnecting neighboring cells—suggesting a mode of spread within the plant. The present study provides insights into the nature of this pathogen and the corresponding plant response, which is likely similar to other pathogens that do not spread systemically in plants.

A novel intracellular nitrogen‐fixing symbiosis made by Ustilago maydis and Bacillus spp.

We observed that the maize pathogenic fungus Ustilago maydis grew in nitrogen (N)-free media at a rate similar to that observed in media containing ammonium nitrate, suggesting that it was able to fix atmospheric N2 . Because only prokaryotic organisms have the capacity to reduce N2 , we entertained the possibility that U. maydis was associated with an intracellular bacterium. The presence of nitrogenase in the fungus was analyzed by acetylene reduction, and capacity to fix N2 by use of (15) N2 . Presence of an intracellular N2 -fixing bacterium was analyzed by PCR amplification of bacterial 16S rRNA and nifH genes, and by microscopic observations. Nitrogenase activity and (15) N incorporation into the cells proved that U. maydis fixed N2 . Light and electron microscopy, and fluorescence in situ hybridization (FISH) experiments revealed the presence of intracellular bacteria related to Bacillus pumilus, as evidenced by sequencing of the PCR-amplified fragments. These observations reveal for the first time the existence of an endosymbiotic N2 -fixing association involving a fungus and a bacterium.