Robbert A. Schilperoort

A rapid micro scale method for the detection of lysopine and nopaline dehydrogenase activities

A rapid and sensitive method has been developed to determine lysopine dehydrogenase (EC 1.5.1-) and nopaline dehydrogenase activities in crown gall tumour tissues. By this method, enzyme activities as low as 0.2 micrometerol octopine or nopaline per h per g fresh weight tumour tissue can still be detected. In non-infected young pea seedlings, no lysopine dehydrogenase activity was detected.

Octopine and nopaline synthesis and breakdown genetically controlled by a plasmid of Agrobacterium tumefaciens

SummarySeveral nopaline degrading strains and one octopine degrading strain are shown to loose oncogenicity as well as the ability to utilize these guanidine compounds when they are cured of their TI plasmid. To investigate whether the specific genes involved in the utilization of one or the other compound are located on the plasmid, plasmid-transfer experiments have been performed.The plasmid from a nopaline degrading strain has been transferred to a naturally non oncogenic Agrobacterium namely A. radiobacter. Furthermore, the plasmid from an octopine degrading strain has been transferred to a plasmid-cured strain which originally had the capacity to utilize nopaline. Both kinds of experiments prove that the TI plasmid determines the strain specificity with regard to the utilization of either octopine or nopaline.They also demonstrate that the synthesis of either octopine or nopaline in crown gall cells is also determined by genes located on the TI plasmid harboured by the transforming A. tumefaciens strains.

Retention of tumor markers in F1 progeny plants from in vitro induced octopine and nopaline tumor tissues

Tumorous tobacco shoots have been derived from callus tissues produced by Agrobacterium tumefaciens--induced transformation of tobacco protoplasts and by fusion of normal protoplasts with those from crown gall tumors. The continued presence of T-DNA sequences in shoots is directly demonstrated by Southern blotting and is also revealed by the presence of the tumor markers octopine and nopaline. When grafted onto normal tobacco plants, both octopine- and nopaline-type shoots (including those from somatic hybrids) produced flowers and set seed. Germination of these seeds gave F1 progeny that showed retention of morphological markers of their parental shoots, and one seedling retained the ability to synthesize nopaline. The data demonstrate that T-DNA markers can be retained during meiosis and are expressed in F1 plants.

The Molecular Genetics Of Crown Gall Tumorigenesis

Publisher Summary The most important characteristic that immediately distinguishes agrobacteria from most other bacteria is their ability to induce tumor formation in plants. Agrobacteria transform “conditioned” plant cells into tumor cells by introducing into them a piece of genetic information which in established plant tumor cells can be recovered as T-DNA integrated into the nuclear plant DNA. Tumor cells characteristically contain a set of unusual amino acid derivatives that have never been found in normal plant cells. Crown gall cells carry a piece of DNA that is homologous to a part of A. turnefuciens DNA integrated into their nuclear DNA. The T-DNA is responsible for the phytohormone-independent growth of tumor cells and encodes enzymes that synthesize opines in the tumor cells. Moreover, the finding that the T-DNA found in different tumor tissues is of a fixed size poses the question of whether T-DNA integrates into plant DNA via a mechanism similar to that by which transposable elements integrate into foreign DNA. The answer to this question is not known. However, it is known that the ends of the T-region are important for tumor induction.

Genetic map of an octopine TI-plasmid

Abstract Several deletion mutants of an octopine TI-plasmid were mapped by digestion with the restriction enzyme Sma I. The T region, as it is defined on the B6-806 plasmid, does not appear to be an essential area for tumour induction on the plasmid of Ach5. The genes for octopine breakdown, plasmid transfer, and the replicator were roughly localized. The possibility of using mutants with large deletions as a cloning vehicle in Agrobacterium tumefaciens is discussed.

The expression of tumour markers in intraspecific somatic hybrids of normal and crown gall cells from Nicotiana tabacum

SummaryFollowing fusion of protoplasts from crown gall tumour calli, characterized by hormone independent growth, and protoplasts from normal tissues of a streptomycin-resistant mutant, SR1, we selected hormone independent streptomycin-resistant calli in Nicotiana tabacum. The tumour line, B6S3, lost the ability to form shoots. Some of the selected lines, similar to SR1, however, are morphogenic. Both calli and shoots contained the tumour specific enzyme lysopinedehydrogenase. The hybrid shoots are resistant to Agrobacterium infection and do not root. These tumorous properties are dominantly expressed in the somatic hybrids.

Properties of D(+)-lysopine dehydrogenase from crown gall tumour tissue.

D(+)-Lysopine dehydrogenase of an octopine-type Crown Gall tumour has been partially purified and a number of kinetic parameters have been determined. D(+)-Lysopine dehydrogenase catalyzes the reductive condensation of pyruvate and one of at least six different L-amino acids, as well as the reverse reactions, with preferential use of NADP(H) as a cofactor. The optimal pH for both reductive and oxidative reactions has been determined. At pH 6.8, L-lysine has of all the amino acids the lowest Km value, while at the same pH the highest V was found with L-arginine and L-histidine. The isoelectric point of D(+)-lysopine dehydrogenase is about 4.5.

Structure and expression of DNA transferred to tobacco via transformation of protoplasts with Ti-plasmid DNA: co-transfer of T-DNA and non T-DNA sequences

SummaryThe T-DNA structure and organization in tissues obtained via transformation of tobacco protoplasts with Ti-plasmid DNA was found to be completely different from the T-DNA introduced via Agrobacterium tumefaciens. It is often fragmented. Overlapping copies of T-DNA, having various sizes, as well as separated fragments of T-DNA were detected. The border sequences of 23 basepairs (bp), flanking the T-region in the Ti-plasmid as direct repeats are not used as preferred sequences for integration. Similar results were obtained with a T-region clone lacking one of the TL-borders. This clone, which carried the cytokinin locus and only the right border sequence of TL and the left border sequence of TR, still had the capacity to transform protoplasts. Also the Vir-region of the Ti-plasmid is not required for integration of foreign DNA via DNA transformation. This is demonstrated by the results with the T-region clone mentioned and by the transforming capacity of a Ti-plasmid carrying a mutated Vir-region. Nevertheless, in a number of Ti-plasmid DNA transformants Vir-region fragments were found to be stably integrated. Furthermore, it has been established that co-transformation can occur with plant cells. Besides the detection of Ti-plasmid fragments from outside the T-region also DNA sequences originating from two DNA sources, which were both independently present in transformation experiments, have been found in some DNA transformants, e.g. calf thymus DNA, which was used as carrier DNA. No expression of the co-transferred DNA was observed. In total three phenotypical classes of DNA transformants were isolated. Although the T-DNA was often scrambled, polyA+ mRNA studies indicated that the different phenotypes studied can be explained by the presence of active T-DNA genes with known functions.

The role of bacterial attachment in the transformation of cell-wall-regenerating tobacco protoplasts by Agrobacterium tumefaciens.

The presence of a newly formed primary cell wall was shown to be required for attachment and subsequent transformation of tobacco leaf protoplasts by Agrobacterium tumefaciens in cocultivation experiments. In these experiments both protoplasts at different stages after their isolation and cell-wall inhibitors were used. The specificity of Agrobacterium attachment was shown by using other kinds of bacteria that did not attach. By diminishing the concentration of divalent cations using ethylenediaminetetraacetic acid, neither attachment nor transformation was found; however, when more specifically the Ca2+concentration was lowered by ethylene glycol-bis (β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid, both phenomena occurred. Commercial lectins had no effect on binding, but this observation does not exclude the involvement of other lectins. Protoplasts isolated from various crown-gall callus tissues also developed binding sites, but when they were at the stage of dividing cells, attachment of agrobacteria was no longer observed. In this respect, cells from protoplasts of normal tobacco leaves behaved differently. Even 16 d after protoplast isolation, the dividing cells were still able to bind A. tumefaciens, while transformation was not detected. For transformation of 3-d-old tobacco protoplasts, a minimal co-cultivation period of 24 h was required, while optimal attachment took place within 5 h. It is concluded that the primary cell wall was sufficiently well formed that certain functional receptor molecules were available for attachment of Agrobacterium as the first step of a multistep process leading to the transformation of cells. The expression of bacterial functions required for attachment, moreover, was independent of the presence of Ti-plasmid.

Double infection of tobacco plants by two complementing octopine T-region mutants of Agrobacterium tumefaciens.

The molecular basis of complementation by a mixture of two different types of octopine T-region mutants (LBA4060 and LBA4210) was studied. Six randomly chosen cellular clones derived from a tumor obtained after mixed infection were analyzed for their T-DNA content via Southern blot hybridization. The clones appeared to contain T-DNA that originated from each of both mutants, indicating that they developed from doubly infected single cells. Genetic complementation, therefore, might explain at least in part the observed complementation phenomenon. However, complementation as a result of cross-feeding between separately transformed cells could not be excluded. Following protoplast isolation, small aggregates might have formed that developed into the clones analyzed.