Analysis of unique variable region of a plant root inducing plasmid, pRi1724, by the construction of its physical map and library.
(73/1949)
Ri plasmids in Agrobacterium rhizogenes specifically induce the hairy root syndrome on various dicotyledonous plants. Its T-DNA transfer system as well as those of Ti plasmids have successfully provided the fundamental technique to introduce exogenous genes into plants. To study the Ri genome structure, we constructed a complete BamHI physical map and a lambda library of pRi1724 of A. rhizogenes strain 1724. By using these, we carried out the complete sequence of the 74-kb region between the right border of T-DNA and tra operon, which is the highly variable region (VAR) among Ri and Ti plasmids. As a result, we found three kinds of putative ABC-type transport operons, histidine utilization operon, glycerol utilization operon and two chemoreceptor genes. In addition, a virulence-related gene, tzs was located independently of the vir region. (+info)
Agrobacterium yellow group: bacteremia and possible septic arthritis following peripheral blood stem cell transplantation.
(74/1949)
A 47-year-old male patient developed sepsis and monoarticular arthritis following autologous stem cell transplantation for recurrent Hodgkin's disease. Blood cultures were positive for Agrobacterium yellow group. The knee pain and swelling responded promptly to the institution of empirical broad-spectrum antibiotics. Recurrent bacteremia developed necessitating Hickman line removal for eventual resolution of the infection. Transplant physicians should be aware of this unusual pathogen and the potential for both persistent line-related sepsis and possible septic arthritis. (+info)
Rhizosphere soil aggregation and plant growth promotion of sunflowers by an exopolysaccharide-producing Rhizobium sp. strain isolated from sunflower roots.
(75/1949)
Root-adhering soil (RAS) forms the immediate environment where plants take up water and nutrients for their growth. We report the effect of an exopolysaccharide (EPS)-producing rhizobacterium (strain YAS34) on the physical properties of sunflower (Helianthus annuus L.) RAS, associated with plant growth promotion, under both water stress and normal water supply conditions. Strain YAS34 was isolated as a major EPS-producing bacterium from the rhizoplane of sunflowers grown in a French dystric cambisol. Strain YAS34 was assigned to the Rhizobium genus by 16S ribosomal DNA gene sequencing. Inoculation of sunflower seeds and soil with strain YAS34 caused a significant increase in RAS per root dry mass (dm) (up to 100%) and a significant increase in soil macropore volume (12 to 60 microm in diameter). The effect of inoculation on sunflower shoot dm (up to +50%) and root dm (up to +70%) was significant under both normal and water stress conditions. Inoculation with strain YAS34 modified soil structure around the root system, counteracting the negative effect of water deficit on growth. Using [(15)N]nitrate, we showed that inoculation made the use of fertilizer more effective by increasing nitrogen uptake by sunflower plantlets. (+info)
Lipopolysaccharides of Rhizobium etli strain G12 act in potato roots as an inducing agent of systemic resistance to infection by the cyst nematode Globodera pallida.
(76/1949)
Recent studies have shown that living and heat-killed cells of the rhizobacterium Rhizobium etli strain G12 induce in potato roots systemic resistance to infection by the potato cyst nematode Globodera pallida. To better understand the mechanisms of induced resistance, we focused on identifying the inducing agent. Since heat-stable bacterial surface carbohydrates such as exopolysaccharides (EPS) and lipopolysaccharides (LPS) are essential for recognition in the symbiotic interaction between Rhizobium and legumes, their role in the R. etli-potato interaction was studied. EPS and LPS were extracted from bacterial cultures, applied to potato roots, and tested for activity as an inducer of plant resistance to the plant-parasitic nematode. Whereas EPS did not affect G. pallida infection, LPS reduced nematode infection significantly in concentrations as low as 1 and 0.1 mg ml(-1). Split-root experiments, guaranteeing a spatial separation of inducing agent and challenging pathogen, showed that soil treatments of one half of the root system with LPS resulted in a highly significant (up to 37%) systemic induced reduction of G. pallida infection of potato roots in the other half. The results clearly showed that LPS of R. etli G12 act as the inducing agent of systemic resistance in potato roots. (+info)
Prediction, identification, and artificial selection of DNA rearrangements in Rhizobium: toward a natural genomic design.
(77/1949)
Based on the DNA sequence of the symbiotic plasmid of Rhizobium strain NGR234, we predicted potential rearrangements generated by homologous recombination. All predicted rearrangements were identified experimentally by using a PCR-based methodology. Thus, the predicted and the actual dynamic maps of the replicon coincide. By using an approach that does not involve the introduction of exogenous genetic elements, derivative populations that are pure for specific rearrangements were obtained. We propose that knowledge of the DNA sequence of a genome offers the possibility of designing pathways of sequential rearrangements leading to alternative genomic structures. An experimental strategy to isolate bacterial populations containing the desired structures is discussed. (+info)
The maternal chromosome set is the target of the T-DNA in the in planta transformation of Arabidopsis thaliana.
(78/1949)
In planta transformation methods are now commonly used to transform Arabidopsis thaliana by Agrobacterium tumefaciens. The origin of transformants obtained by these methods has been studied by inoculating different floral stages and examining gametophytic expression of an introduced beta-glucuronidase marker gene encoding GUS. We observed that transformation can still occur after treating flowers where embryo sacs have reached the stage of the third division. No GUS expression was observed in embryo sacs or pollen of plants infiltrated with an Agrobacterium strain bearing a GUS gene under the control of a gametophyte-specific promoter. To identify the genetic target we used an insertion mutant in which a gene essential for male gametophytic development has been disrupted by a T-DNA bearing a Basta resistance gene (B(R)). In this mutant the B(R) marker is transferred to the progeny only by the female gametes. This mutant was retransformed with a hygromycin resistance marker and doubly resistant plants were selected. The study of 193 progeny of these transformants revealed 25 plants in which the two resistance markers were linked in coupling and only one plant where they were linked in repulsion. These results point to the chromosome set of the female gametophyte as the main target for the T-DNA. (+info)
Ethylene is involved in the nodulation phenotype of Pisum sativum R50 (sym 16), a pleiotropic mutant that nodulates poorly and has pale green leaves.
(79/1949)
R50 is characterized as a pleiotropic pea mutant; it forms few nodules and has short lateral roots, short stature and pale leaves. Using grafting techniques, R50 paleness was found to be controlled by the shoot of the mutant whereas the nodulation phenotype was regulated by its root. The paleness of R50 is due to a lower than normal total chlorophyll content in its young leaves. The defect appears to be overcome with age because, as the plant matures, the chlorophyll levels increase in the older leaves. The reduction in stature is attributed to shorter internodes, and the oldest internodes are thicker than those of the parent Sparkle. Upon rhizobial inoculation, R50 forms as many infection threads as Sparkle. However, most of these are arrested in the inner cortex. The threads appear to have lost their directional growth towards the stele, and they coil around within enlarged cortical cells. In addition, very few infection threads are associated with divisions of the inner cortical cells. These aborted nodule primordia are abnormal, flat and mainly composed of cells which have divided anticlinally only. Nodulation of R50 was restored by treating the roots with ethylene inhibitors. The R50 mutant further supports the postulated role of ethylene in regulating rhizobial infection with a probable role in the control of the primordium development. (+info)
Agrobacterium rhizogenes-mediated transformation of opium poppy, Papaver somniferum l., and California poppy, Eschscholzia californica cham., root cultures.
(80/1949)
An efficient protocol for the establishment of transgenic opium poppy (Papaver somniferum L.) and California poppy (Eschscholzia californica Cham.) root cultures using A. grobacterium rhizogenes is reported. Five strains of A. rhizogenes were tested for their ability to produce hairy roots on wounded opium poppy seedlings and California poppy embryogenic calli. Three of the strains induced hairy root formation on both species, whereas two others either caused the growth of tumorigenic calli or produced no response. To characterize the putative transgenic roots further, explant tissues were co-cultivated with the most effective A: rhizogenes strain (R1000) carrying the pBI121 binary vector. Except for the co-cultivation medium, all formulations included 50 mg l(-1) paromomycin to select for transformants and 200 mg l(-1) timentin to eliminate the Agrobacterium. Four weeks after infection, paromomycin-resistant roots appeared on 92-98% of explants maintained on hormone-free medium. Isolated hairy roots were propagated in liquid medium containing 1.0 mg l(-1) indole-3-acetic acid to promote rapid growth. Detection of the neomycin phosphotransferase gene, high levels of beta-glucuronidase (GUS) transcripts and enzyme activity, and GUS histochemical localization confirmed the integrative transformation of root cultures. Transgenic roots grew faster than wild-type roots, and California poppy roots grew more rapidly than those of opium poppy. With the exception of a less compact arrangement of epidermal cells and more root hairs, transformed roots of both species displayed anatomical features and benzylisoquinoline alkaloid profiles that were virtually identical to those of wild-type roots. Transgenic root cultures of opium poppy and California poppy are a simple, reliable and well-defined model system to investigate the molecular and metabolic regulation of benzylisoquinoline alkaloid biosynthesis, and to evaluate the genetic engineering potential of these important medicinal plants. (+info)