Regulation of Agrobacterium tumefaciens T-cyt gene expression in leaves of transgenic potato (Solanum tuberosum L. cv. Désirée) is strongly influenced by plant culture conditions.

The promoter region of the Agrobacterium tumefaciens T-cyt gene was linked in a translational fusion to the coding DNA of the reporter gene uidA (for beta-glucuronidase or GUS protein; EC 3.2.1.31) and to nos 3' flanking DNA. The chimaeric gene was introduced by Agrobacterium transformation into potato (Solanum tuberosum L. cv. Désirée). In nine transgenic lines, the average GUS levels were highest in extracts from stems and roots of in vitro grown plants (ca. 11,000 GUS activity units per pmol MU per mg protein per min) but lower in leaves of the in vitro grown plants (ca. 7000 units). GUS activity was intermediate in stems and roots of plants grown in soil as well as in in vitro crown galls (ca. 3000 units). Activity was low in tubers, irrespective of whether these developed in vitro or in soil (both ca. 100 units), and lowest of all in leaves of soil-grown plants (ca. 10-15 units). However, in shoot cultures reestablished from soil-grown plants, GUS activity in the leaves increased to that determined in the original shoot cultures. Hence, plant culture conditions strongly influenced the expression of the T-cyt-uidA-nos gene. In particular, it was silenced in leaves of soil-grown plants. The results are compared with previous analyses of the promoter region of the wild-type T-cyt gene and with the growth properties of a large number of crown gall cell lines and crown-gall-derived plants, including over forty S. tuberosum cv. Désirée cell lines isolated in the present study that were transformed with the wild-type T-cyt gene and six promoter-mutated derivatives. A number of implications are discussed for crown gall formation and for control of expression of plant genes which contain Activator or G-box type 5' expression control sequences.

Phenotypic changes in T-cyt-transformed potato plants are consistent with enhanced sensitivity of specific cell types to normal regulation by root-derived cytokinin.

From over forty independently isolated potato lines transformed with wild-type and promoter-mutated T-cyt genes, a number of lines were selected for examination of phenotypic changes in growth and development for plants grown in soil in a controlled environment. The three lines chosen for most detailed examination showed a wide spectrum of phenotypic changes. In comparisons with control potato cv. Désirée, the plants of one line had a two- to three-fold increase in biomass production during early vegetative growth, advanced senescence and a shortened plant life-span. Another line showed abnormal cellulytic senescence. In two lines there were increases in tuber numbers and more skewed tuber size distributions which correlated with reduced shoot apical dominance and shortened dormancy of the stored tubers. None of the lines showed altered timing of onset of tuberization or flowering, although tuberization was consistently delayed when expressed as a function of increasing total plant weight. A hypothesis is proposed to explain the diverse phenotypes which postulates that (1) T-cyt transformation causes enhanced sensitivity to cytokinins in specific types of shoot cells which are already targets for regulation by normal root-derived cytokinins; (2) two distinct types of shoot target cells are present, one in shoot meristems and one in leaves; (3) the two types can acquire enhanced sensitivity, either separately or in combination depending on the particular T-cyt transformation event. The scope for using the transformed plants in subsequent physiological, biochemical and molecular studies, aimed at examining the molecular basis of the model or selected consequences of T-cyt transformation in altering regulation of potato plant growth and development, is discussed. The attention is drawn to the possible involvement at the subcellular level of sucrose phosphate synthase in mediating the phenotypic effects caused by T-cyt transformation.

Biochemical characterisation of Nicotiana plumbaginifolia auxotrophs that require branched-chain amino acids.

The biochemical lesions in six amino acid-requiring auxotrophic lines of Nicotiana plumbaginifolia have been investigated, by means of feeding experiments with [(14)C] and unlabelled substrates, and enzyme analysis. Three of the lines require isoleucine for growth, are unable to synthesise 2-oxobutyrate in vivo and have no detectable threonine dehydratase (E.C.4.2.1.16) in vitro. The other three lines require (isoleucine + valine), accumulate [(14)C] dihydroxymethylvalerate when fed [(14)C]-L-threonine, and contain no detectable dihydroxyacid dehydratase (E.C.4.2.1.9).