T-DNA fragments of hairy root plasmid pRi8196 are distantly related to octopine and nopaline Ti plasmid T-DNA

Agrobacterium Ti (tumor-inducing) and Ri (root-inducing) plasmids transform dicot plant cells by insertion of a specific plasmid sector called T-DNA (transferred DNA) into host plant nuclear DNA. The mannopine-type Ri plasmid pRi8196 contains four BamHI fragments that encompass core T-DNA. We report Southern hybridization studies that show that these four fragments have no strong homology to octopine-, nopaline-, or agropine-type Ti plasmids. We detected and mapped very weak homology regions, most of which are assignable to opine synthase or opine catabolic functions on the Ti plasmid. We found no homology between Ri T-DNA and the region of Ti T-DNA that encodes tumor morphology functions.     

Segregation of T-DNA copies in the progeny of a regenerant plant from a mannopine-positive hairy root line

We have analyzed opine content, T-DNA content, and developmental features of one hairy root culture line and its progeny. Opine-positive progeny still have the hairy root phenotype and have essentially the same T-DNA structure as the parental plant. Opineless progeny do not exhibit the hairy root phenotype. Some of them do not contain any T-DNA sequences, whereas others contain only the left part of T-DNA. These results are compatible with the hypothesis that, in the hairy root line analyzed, the left part of T-DNA is integrated independently from the core T-DNA and can therefore segregate during sexual reproduction.     

Multiple transformation of plant cells by Agrobacterium may be responsible for the complex organization of T-DNA in crown gall and hairy root

Summary Inoculation of carrot discs and Lotus corniculatus plantlets with mixtures of different Agrobacterium rhizogenes or of A. rhizogenes and A. tumefaciens or with Agrobacterium strains harboring both an Ri and a modified Ti plasmid resulted in frequent multiple (pluribacterial) transformation of cells, as revealed by the mixed opine-type of hairy roots arising from them. Multiple transformation may account for the presence of dispersed T-DNA inserts in crown gall and hairy root lines. A plant genetic engineering strategy based on segregation of T-DNA inserts in the progeny of multiple transformants is proposed.     

Natural genetic engineering of plant cells: the molecular biology of crown gall and hairy root disease

During the past decade, the molecular mechanisms of crown gall and hairy root development have been elucidated in considerable detail. It now appears that the genetic colonization of plant cells by Agrobacterium evolved by continual adaptation of groups of genes that existed long before the evolution of this plant-microbe association. This is most evident for the signal transduction system leading to vir gene induction, and for the early steps of T-DNA transfer to plant cells which have probably evolved from the bacterial conjugation and protein export machinery. However, the later steps, i.e. nuclear targeting of the T-DNA-protein complex, and integration into the host genome by illegitimate recombination are reminiscent of viral infection, where the T-complex resembles a viral particle. The present article reviews the current knowledge of the molecular basis of crown gall and hairy root tumorigenesis, with some emphasis on the mechanisms of signal exchange between plants and bacteria, as well as of T-DNA excision, transfer, integration and expression.The authors are with Plant Molecular Biology, Department of Biology, Biozentrum, Marie-Curie-Str. 9, University of Frankfurt am Main, D-60439 Frankfurt, Germany     

Production and metabolic engineering of bioactive substances in plant hairy root culture

In the past three decades, hairy roots research for the production of valuable biological active substances has received a lot of attention. The addition of knowledge to enhance the yields of desired substances and the development of novel tools for biomass engineering offer new possibilities for large-scale cultivation of the plant hairy root. Hairy roots can also produce recombinant proteins through the transfer of Agrobacterium T-DNA into the plant genome, and thereby hold immense potential for the pharmaceutical industry. This review highlights some of the significant progress made in the past few years and outlines future prospects for exploiting the potential utility of hairy root cultures as “chemical factories” for producing bioactive substances.     

Evolutionary relationships can be more important than abiotic conditions in predicting the outcome of plant–plant interactions

Positive and negative plant–plant interactions are major processes shaping plant communities. They are affected by environmental conditions and evolutionary relationships among the interacting plants. However, the generality of these factors as drivers of pairwise plant interactions and their combined effects remain virtually unknown. We conducted an observational study to assess how environmental conditions (altitude, temperature, irradiance and rainfall), the dispersal mechanism of beneficiary species and evolutionary relationships affected the co‐occurrence of pairwise interactions in 11 Stipa tenacissima steppes located along an environmental gradient in Spain. We studied 197 pairwise plant–plant interactions involving the two major nurse plants (the resprouting shrub Quercus coccifera and the tussock grass S. tenacissima) found in these communities. The relative importance of the studied factors varied with the nurse species considered. None of the factors studied were good predictors of the co‐ocurrence between S. tenacissima and its neighbours. However, both the dispersal mechanism of the beneficiary species and the phylogenetic distance between interacting species were crucial factors affecting the co‐occurrence between Q. coccifera and its neighbours, while climatic conditions (irradiance) played a secondary role. Values of phylogenetic distance between 207–272.8 Myr led to competition, while values outside this range or fleshy‐fruitness in the beneficiary species led to positive interactions. The low importance of environmental conditions as a general driver of pairwise interactions was caused by the species‐specific response to changes in either rainfall or radiation. This result suggests that factors other than climatic conditions must be included in theoretical models aimed to generally predict the outcome of plant–plant interactions. Our study helps to improve current theory on plant–plant interactions and to understand how these interactions can respond to expected modifications in species composition and climate associated to ongoing global environmental change.     

T-DNA integration patterns in co-transformed plant cells suggest that T-DNA repeats originate from co-integration of separate T-DNAs

Nicotiana protoplasts and Arabidopsis leaf discs or roots were co-cultivated with two Agrobacterium strains each carrying a different T-DNA. Co-transformed plants were selected and the integration of the different T-DNAs was analysed at the genetic and genomic level. Genetic analysis showed that the T-DNAs derived from different bacteria were frequently integrated at the same locus, independent of the plant species or transformation method used. Southern analysis revealed that 12 out of 27 Arabidopsis transformants contained the co-transferred T-DNAs linked to each other in all possible configurations but with a preference for those with at least one right border involved in linkage. Overall, our data support the hypothesis that ligation of separate T-DNAs is a dominant mechanism in formation of the frequently observed repeats of identical T-DNAs. We propose a scheme which could explain the formation of T-DNA repeats and the preferential involvement of right borders in T-DNA linkages.     

Variation in plant thermal reaction norms along a latitudinal gradient – more than adaptation to season length

Little is known about the extent to which observed phenological responses to changes in climate are the result of phenotypic plasticity or genetic changes. We also know little about how plasticity, in terms of thermal reaction norms, vary spatially. We investigated if the thermal reaction norms for flower development of five crucifer species (Brassicaceae) differed among three regions along a south–north latitudinal gradient in replicated experiments. The mean response (elevation) of thermal reaction norms of flowering differed among regions in all study species, while sensitivity of flower development to temperature (slope) differed in only one of the species. Differences in mean responses corresponded to cogradient patterns in some species, but countergradient patterns in other. This suggests that differences among regions were not solely the result of adaptation to differences in the length of the growing season, but that other factors, such as herbivory, play an important role. Differences in development rate within species were mainly explained by variation in early phases of bud formation in some species but by variation in later phases of bud formation in other species. The differences in latitudinal patterns of thermal reaction norms among species observed in this study are important, both to identify agents of selection and to predict short‐ and long‐term responses to a warming climate.     

Govindjee at 80: more than 50 years of free energy for photosynthesis

We provide here a glimpse of Govindjee and his pioneering contributions on the two light reactions and the two pigment systems, particularly on the water–plastoquinone oxido-reductase, Photosystem II. His focus has been on excitation energy transfer; primary photochemistry, and the role of bicarbonate in electron and proton transfer. His major tools have been kinetics and spectroscopy (absorption and fluorescence), and he has provided an understanding of both thermoluminescence and delayed light emission in plants and algae. He pioneered the use of lifetime of fluorescence measurements to study the phenomenon of photoprotection in plants and algae. He, however, is both a generalist and a specialist all at the same time. He communicates very effectively his passion for photosynthesis to the novice as well as professionals. He has been a prolific author, outstanding lecturer and an editor par excellence. He is the founder not only of the Historical Corner of Photosynthesis Research, but of the highly valued Series Advances in Photosynthesis and Respiration Including Bioenergy and Related Processes. He reaches out to young people by distributing Z-scheme posters, presenting Awards of books, and through tri-annual articles on “Photosynthesis Web Resources”. At home, at the University of Illinois at Urbana-Champaign, he has established student Awards for Excellence in Biological Sciences. On behalf of all his former graduate students and associates, I wish him a Happy 80th birthday. I have included here several tributes to Govindjee by his well-wishers. These write-ups express the high regard the photosynthesis community holds for “Gov” and illuminate the different facets of his life and associations.     

Mechanisms of crown gall formation: T-DNA transfer fromAgrobacterium tumefaciens to plant cells

Agrobacterium tumefaciens harbouring the Ti plasmid incites crown gall tumor on dicotyledonous species. Upon infection of these plants, T-DNA in the Ti plasmid is transferred by unknown mechanisms to plant cells to be integrated into nuclear DNA. WhenAgrobacterium is incubated with protoplasts or seedlings of dicotyledonous plants, circulation of T-DNA and expression ofvir (virulence) genes on the Ti plasmid are induced. The circularization event is efficiently induced by mesophyll protoplasts of tobacco which are highly competent for transformation by the T-DNA, and is also induced by diffusible phenolic compounds excreted from the protoplasts. The circularization and formation of crown gall both require the expression of thevirD locus, one of the induciblevir genes. These results suggest that the circularization of T-DNA reflects one of steps of the T-DNA transfer during formation of crown gall. In contrast to dicotyledonous plants, monocotyledonous plants are thought to be unresponsive to infection byAgrobacterium. We showed that monocotyledonous plants do not excrete diffusible inducers for the expression ofvir genes, while they contain a novel type of a signal substance(s). This inducer is not detected in the exudates of seedlings of monocotyledonous plants, but is found in the extracts from the seedlings, and also those from the seeds, bran and germ of wheat and oats. This finding suggests that T-DNA processing, and possibly its transfer, should take place whenAgrobacterium invades seedlings and seeds of monocotyledonous plants. Recipient of the Botanical Society Award for Young Scientists, 1987.     

Ethylene's role in phosphate starvation signaling: more than just a root growth regulator

Phosphate (Pi) is a common limiter of plant growth due to its low availability in most soils. Plants have evolved elaborate mechanisms for sensing Pi deficiency and for initiating adaptive responses to low Pi conditions. Pi signaling pathways are modulated by both local and long-distance, or systemic, sensing mechanisms. Local sensing of low Pi initiates major root developmental changes aimed at enhancing Pi acquisition, whereas systemic sensing governs pathways that modulate expression of numerous genes encoding factors involved in Pi transport and distribution. The gaseous phytohormone ethylene has been shown to play an integral role in regulating local, root developmental responses to Pi deficiency. Comparatively, a role for ethylene in systemic Pi signaling has been more circumstantial. However, recent studies have revealed that ethylene acts to modulate a number of systemically controlled Pi starvation responses. Herein we highlight the findings from these studies and offer a model for how ethylene biosynthesis and responsiveness are integrated into both local and systemic Pi signaling pathways.     

Infection, propagation, distribution and stability of plant virus in hairy root cultures

Nicotiana benthamiana hairy root cultures were infected with tobacco mosaic virus (TMV) and used for in vitro plant virus propagation. The roots were infected with TMV by addition of virus to the medium at the same time as root inoculation. Viral accumulation in the biomass was 7-11-fold greater when the initial infection was carried out in B5 medium rather than sodium phosphate buffer; virus accumulation also increased with increasing viral inoculum concentration. The amount of TMV accumulated in the biomass was similar when virus was retained in the medium for the duration of the cultures and when the inoculum virus was removed 23h after addition to the roots. In roots with established infections, the concentration of virus remained relatively constant and did not increase with further root growth. The distribution of virus within individual root mats harvested from shake flasks was not uniform; there was also significant variability in viral accumulation between replicate hairy root cultures. The picture that emerges from this work is that in vitro viral accumulation in hairy root cultures depends strongly on the viral inoculum concentration applied and the initial level of primary infection achieved, even though primary infection by external virus occurs mainly within only the first few hours of exposure to the biomass and is followed by substantial secondary infection by viral progeny within the root tissue.     

Segmental distribution in potentials of lateral root budding and oxygen uptake of plant hairy roots

The positional distributions in potential of lateral root budding and oxygen uptake rate were examined using the segments of madder and horseradish hairy roots with a length of 5.0×10⁻³ m obtained at different mean distances from the root tips of l=7.5×10⁻³–47.5×10⁻³ m. The average rate of lateral root budding and oxygen uptake rate of the roots with smaller l values were higher and both the rates gradually decreased with increase in l value. Positive relations were observed between the rates of lateral root budding and oxygen uptake of both the hairy roots. The relation indicated that the potential of lateral root budding was suppressed at the oxygen uptake rates of 0.15×10⁻⁵ and 0.32×10⁻⁵ mol O₂/(h m) for madder and horseradish hairy roots, respectively.