A novel cell surface polysaccharide in Pseudomonas putida WCS358, which shares characteristics with Escherichia coli K antigens, is not involved in root colonization.

Previously we have shown that flagella and the O-specific polysaccharide of lipopolysaccharide play a role in colonization of the potato root by plant growth-promoting Pseudomonas strains WCS374 and WCS358. In this paper, we describe a novel cell surface-exposed structure in Pseudomonas putida WCS358 examined with a specific monoclonal antibody. This cell surface structure appeared to be a polysaccharide, which was accessible to the monoclonal antibody at the outer cell surface. Further study revealed that it does not contain 2-keto-3-deoxyoctonate, heptose, or lipid A, indicating that it is not a second type of lipopolysaccharide. Instead, the polysaccharide shared some characteristics with K antigen described for Escherichia coli. From a series of 49 different soil bacteria tested, only one other potato plant growth-promoting Pseudomonas strain reacted positively with the monoclonal antibody. Mutant cells lacking the novel antigen were efficiently isolated by an enrichment method involving magnetic antibodies. Mutant strains defective in the novel antigen contained normal lipopolysaccharide. One of these mutants was affected in neither its ability to adhere to sterile potato root pieces nor its ability to colonize potato roots. We conclude that the bacterial cell surface of P. putida WCS358 contains at least two different polysaccharide structures. These are the O-specific polysaccharide of lipopolysaccharide, which is relevant for potato root colonization, and the novel polysaccharide, which is not involved in adhesion to or colonization of the potato root.     

Plant protein improvement by genetic engineering: use of synthetic genes

Methods now exist to construct genes coding for synthetic proteins enriched in essential amino acid content. The production of these synthetic proteins in potato tubers can improve the nutritive value of the potato and increase its importance as a basic food crop.     

Engineering Antibodies as Drugs: Principles and Practice

Over the last forty years, recombinant antibodies have been transformed from an unproven experimental approach to a therapeutic modality with multiple success stories in the treatment of cancer, inflammation, infections and cardiometabolic diseases. Owing to their high affinity and selectivity for the target antigen, their multimodal tunable mode of action, their modular nature and long half-life, antibodies now hold prominent positions in the pipelines of major biopharmaceutical companies. In this brief report, I aim to highlight the themes that have shaped the therapeutic antibody engineering as it exists today and to offer a personal perspective on its future developments. Distinct antibody engineering history, developments and trends in Russian Federation will not be discussed since they are detailed elsewhere in this journal issue.     

Improving starch for food and industrial applications

Progress in understanding starch biosynthesis, and the isolation of many of the genes involved in this process, has enabled the genetic modification of crops in a rational manner to produce novel starches with improved functionality. For example, potato starches have been created that contain unprecedented levels of amylose and phosphate. Amylose-free short-chain amylopectin starches have also been developed; these starches have excellent freeze-thaw stability without the need for chemical modification. These developments highlight the potential to create even more modified starches in the future.     

Lignin degrading system of white-rot fungi and its exploitation for dye decolorization

With global attention and research now focused on looking for the abatement of pollution, white-rot fungi is one of the hopes of the future. The lignin-degrading ability of these fungi have been the focus of attention for many years and have been exploited for a wide array of human benefits. This review highlights the various enzymes produced by white-rot fungi for lignin degradation, namely laccases, peroxidases, aryl alcohol oxidase, glyoxal oxidase, and pyranose oxidase. Also discussed are the various radicals and low molecular weight compounds that are being produced by white-rot fungi and its role in lignin degradation. A brief summary on the developments in research of decolorization of dyes using white-rot fungi has been made.     

Expression of a cassava granule-bound starch synthase gene in the amylose-free potato only partially restores amylose content

Granule-bound starch synthase I (GBSS I) is responsible for the synthesis of amylose in starch granules. A heterologous cassava GBSS I gene was tested for its ability to restore amylose synthesis in amylose-free (amf) potato mutants. For this purpose, the cassava GBSS I was equipped with different transit peptides. In addition, a hybrid containing the potato transit peptide, the N-terminal 89 amino acids of the mature potato GBSS I, and the C-terminal part of cassava GBSS I was prepared. The transgenic starches were first analysed by iodine staining. Only with the hybrid could full phenotypic complementation of the amf mutation be achieved in 13% of the plants. Most transformants showed partial complementation, but interestingly the size of the blue core was similar in all granules derived from one tuber of a given plant. The amylose content was only partially restored, up to 60% of wild-type values or potato GBSS I-complemented plants; however, the GBSS activity in these granules was similar to that found in wild-type ones. From this, and the observation that the hybrid protein (a partial potato GBSS I look-alike) performs best, it was concluded that potato and cassava GBSS I have different intrinsic properties and that the cassava enzyme is not fully adapted to the potato situation.     

Pathogen virulence of Phytophthora infestans: from gene to functional genomics

The oomycete, Phytophthora infestans, is one of the most important plant pathogens worldwide. Much of the pathogenic success of P. infestans, the potato late blight agent, relies on its ability to generate large amounts of sporangia from mycelia, which release zoospores that encyst and form infection structures. Until recently, little was known about the molecular basis of oomycete pathogenicity by the avirulence molecules that are perceived by host defenses. To understand the molecular mechanisms interplay in the pathogen and host interactions, knowledge of the genome structure was most important, which is available now after genome sequencing. The mechanism of biotrophic interaction between potato and P. infestans could be determined by understanding the effector biology of the pathogen, which is until now poorly understood. The recent availability of oomycete genome will help in understanding of the signal transduction pathways followed by apoplastic and cytoplasmic effectors for translocation into host cell. Finally based on genomics, novel strategies could be developed for effective management of the crop losses due to the late blight disease.     

Ultraviolet light-emitting diode (UV LED) trap the West Indian sweet potato weevil, <Emphasis Type="Italic">Euscepes postfasciatus</Emphasis> (Coleoptera: Curculionidae)

The West Indian sweet potato weevil Euscepes postfasciatus (Fairmaire) is a troublesome pest insect of sweet potato that originally came from the Caribbean, but is now expanding its distribution into the Pacific Islands. Although sterile insect techniques have been used against this pest in a demonstration experiment on Kume Island [Ohno et al. (2006) Kontyu to Shizen 41:25–30], effective methods of monitoring E. postfasciatus are scarce. It is necessary to detect the weevils at an early stage of invasion in uninvaded areas, and an attractant trap can be used to achieve this. Thus, we developed an ultraviolet (UV) light-emitting diode trap, invented a method for diffusing the light to attract more insects, and investigated the attractiveness of the light trap to E. postfasciatus under laboratory conditions. Our results indicate that diffused UV light has a higher potential to attract E. postfasciatus than direct UV light. Furthermore, sweet potato is an effective bait to use to capture the weevils attracted by UV light. Thus, E. postfasciatus can be trapped using diffused UV light and sweet potato bait.     

Flexible automation of cell culture and tissue engineering tasks

Until now, the predominant use cases of industrial robots have been routine handling tasks in the automotive industry. In biotechnology and tissue engineering, in contrast, only very few tasks have been automated with robots. New developments in robot platform and robot sensor technology, however, make it possible to automate plants that largely depend on human interaction with the production process, e.g., for material and cell culture fluid handling, transportation, operation of equipment, and maintenance. In this paper we present a robot system that lends itself to automating routine tasks in biotechnology but also has the potential to automate other production facilities that are similar in process structure. After motivating the design goals, we describe the system and its operation, illustrate sample runs, and give an assessment of the advantages. We conclude this paper by giving an outlook on possible further developments.     

Plant transformation technology

Plant transformation has its roots in the research on Agrobacterium that was being undertaken in the early 1980s. The last two decades have seen significant developments in plant transformation technology, such that a large number of transgenic crop plants have now been released for commercial production. Advances in the technology have been due to development of a range of Agrobacterium-mediated and direct DNA delivery techniques, along with appropriate tissue culture techniques for regenerating whole plants from plant cells or tissues in a large number of species. In addition, parallel developments in molecular biology have greatly extended the range of investigations to which plant transformation technology can be applied. Research in plant transformation is concentrating now not so much on the introduction of DNA into plant cells, but rather more on the problems associated with stable integration and reliable expression of the DNA once it has been integrated.     

Role of 2,4-Diacetylphloroglucinol in the Interactions of the Biocontrol Pseudomonad Strain F113 with the Potato Cyst Nematode Globodera rostochiensis

The potato cyst nematode Globodera rostochiensis is an important pest of potato (Solanum tuberosum). Pseudomonas fluorescens F113, which produces 2,4-diacetylphloroglucinol (DAPG), was investigated as a potential biocontrol agent against G. rostochiensis. Exposure of nematode cysts to the pseudomonad, under in vitro conditions or in soil microcosms, almost doubled the ability of the eggs to hatch. The percentage of mobile juveniles was reduced threefold following their incubation in the presence of the pseudomonad, both in vitro and in soil. Results obtained with a transposon-induced DAPG-negative biosynthetic mutant of F113 and its complemented derivative with restored DAPG synthesis showed that the ability of strain F113 to produce DAPG was responsible for the increase in hatch ability and the reduction in juvenile mobility. Similar effects on egg hatch ability and juvenile mobility of G. rostochiensis were obtained in vitro by incubating nematode cysts and juveniles, respectively, in the presence of synthetic DAPG. DAPG-producing P. fluorescens F113 is proposed as a potential biocontrol inoculant for the protection of potato crops against the potato cyst nematode.     

Human embryonic stem cells: emerging technologies and practical applications

Human embryonic stem cells possess the unique ability to differentiate into any adult cell type. Recent advances in the understanding of stem cell biology make new applications possible for stem cell based technology. Of note, it is now possible to reprogram terminally differentiated human somatic cells into pluripotent cells that are functionally equivalent to embryonic stem cells. These induced pluripotent cells may become the substrate for future disease models and cell-based therapies. In addition, novel techniques for genetic manipulation have increased the ease with which genes can be modified into stem cells. In this review, we describe these novel technologies as well as developments in the understanding of basic biology of stem cell pluripotency and differentiation.     

Guest Lecture 9.00–9.45 Wednesday 17 September 2003

The past decades have seen an explosion in our knowledge of the molecular events underpinning the pathogenesis of many disease processes. Furthermore, there have been enormous technical advances with the ability to identify, clone and sequence genes and to characterize their protein products now being common place in research settings. However, despite many claims as to the utility of molecular and biochemical methods in pathology only very few laboratories employ such methods in a clinical setting. Indeed the impact of molecular medicine has been more talked about than real. Why is this? The goal of this presentation is to address this question and present some perspectives on the future of Molecular Pathology. I shall overview, for the BSCC, the current state of the technology available for gene analysis and to explore the developments needed before the mirage of molecular pathology becomes a clinical reality.     

Multiple Copies of Genes Encoding XEGIPs are Harbored in an 85-kB Region of the Potato Genome

Proteinaceous inhibitors of plant cell wall degrading enzymes can provide a first level of defense from invasive phytopathogens. One recently discovered inhibitor is the xyloglucans-specific endoglucanase inhibitor protein (XEGIP) originally found in tomato. This inhibitor protein has since been found in many solanaceous plants as well as other dicots. As xyloglucans play a major role in maintaining cell wall structure in dicots, protection of xyloglucan is critical. Thus far, only a single potato XEGIP had been identified (AY321357), even though a major pathogen of potato, Phytophthora infestans, has multiple copies of xyloglucan-specific endoglucanase. We now report that potato has nine additional copies of XEGIP, clustered together on a small region of chromosome one. They are located adjacent to the previously described potato XEGIP and represent one of the highest degrees of gene duplication relative to any other potato inhibitor. Synteny with tomato indicates this duplication may have occurred before speciation of Solanum.     

Application of high-resolution DNA melting for genotyping and variant scanning of diploid and autotetraploid potato

The ideal marker system for tetraploid potato would be dosage-sensitive and have the ability to distinguish heterozygous genotypes with multiple haplotypes within the genomic region targeted by the marker. The objective of this study was to evaluate the utility of high-resolution DNA melting (HRM) for genotyping and polymorphism detection in diploid and tetraploid potato. Amplicon scanning, unlabelled probe, and short amplicon assays were developed for four candidate genes affecting tuber skin and flesh colour, and starch, and a marker linked to nematode resistance. Genotyping a set of 95 potato clones revealed several examples of clones with three distinct haplotypes. Combined probe and amplicon analysis identified between 29 and 44 unique genotypes for the same assays. Assays developed for four of the five target genes are suitable for marker-assisted selection in potato breeding programs. This study illustrates the use of HRM in potato genetics. Further advances in the technology and associated data analysis should make HRM a useful tool for basic and applied studies of potato.     

Inhibitory ability of sap from different tobacco varieties on potato virus Y

In these experiments the inhibitory ability of 12 varieties ofNicotiana tabacum L. to potato virus Y was studied by means of drop serological precipitation method. In 11 varieties under study a correlation was found between field resistance and the inhibitory ability of sap. Varieties S 390/1, line 40, fixed A 1 exhibited low inhibitory ability of sap, lines Bel 61-10, R 3, Criolo and Burley N-15 were of medium inhibitory ability and high inhibitory ability was found in varieities Vir?inský zlatý, line 37, A 5205 and R 1. The variety Vir?inský zlatý, which is believed to be susceptible to potato virus Y was found to have high inhibitory ability. This was confirmed by inoculation of leavesChenopodium giganteum Don., determination of the number of lesions by the half leaf test, and determination of relative concentration of potato virus Y by means of serological drop method. None of the varieties under study showed extremely high inhibitory ability against potato virus Y. We believe that laboratory methods of determining the inhibitory ability of sap of tobacco leaves can be used to produce hybrids with high inhibitory ability on potato virus Y. The field resistance of those hybrids should, however, be checked by provocative field experiments.     

Fructan as a New Carbohydrate Sink in Transgenic Potato Plants

Fructans are polyfructose molecules that function as nonstructural storage carbohydrates in several plant species that are important crops. We have been studying plants for their ability to synthesize and degrade fructans to determine if this ability is advantageous. We have also been analyzing the ability to synthesize fructan in relation to other nonstructural carbohydrate storage forms like starch. To study this, we induced fructan accumulation in normally non-fructan-storing plants and analyzed the metabolic and physiological properties of such plants. The normally non-fructan-storing potato plant was modified by introducing the microbial fructosyltransferase genes so that it could accumulate fructans. Constructs were created so that the fructosyltransferase genes of either Bacillus subtilis (sacB) or Streptococcus mutans (ftf) were fused to the vacuolar targeting sequence of the yeast carboxypeptidase Y (cpy) gene. These constructs were placed under the control of the constitutive cauliflower mosaic virus 35S promoter and introduced into potato tissue. The regenerated potato plants accumulated high molecular mass (>5 [times] 106 D) fructan molecules in which the degree of polymerization of fructose units exceeded 25,000. Fructan accumulation was detected in every plant tissue tested. The fructan content in the transgenic potato plants tested varied between 1 and 30% of dry weight in leaves and 1 and 7% of dry weight in microtubers. Total nonstructural neutral carbohydrate content in leaves of soil-grown plants increased dramatically from 7% in the wild type to 35% in transgenic plants. Our results demonstrated that potato plants can be manipulated to store a foreign carbohydrate by introducing bacterial fructosyltransferase genes. This modification affected photosynthate partitioning in microtubers and leaves and increased nonstructural carbohydrate content in leaves.     

Biology,Epidemiology and Management of Rhizoctonia solani on Potato

Black scurf and stem canker on potato is an economically important disease complex, causing both quantitative and qualitative damage to potato crops which occurs in potato production areas throughout the world. The ribosomal DNA internal transcribed spacer sequence analysis is currently accepted and a commonly used method for classifying Rhizoctonia species and anastomosis groups (AGs). To date, 13 AGs have been recognized. The updated AG distribution in potato worldwide production areas confirm the status of AG‐3 as the most prevalent AG in potato and reflects the population dynamics of the pathogen probably due to global trading of tubers. As R. solani is a tuber‐ and soilborne pathogen, the ability to detect its levels in the seed tubers and in the soil and predict the potential damage is an important factor in controlling the disease. Effective disease management of Rhizoctonia disease requires implementation of an integrated disease management approach and knowledge of each of its stages. Although the most important control measures are cultural, chemical control (either by seed tuber‐ or in‐furrow treatments) is still an important tool in reducing the damages caused by R. solani.     

Applications of biotechnology and genomics in potato improvement

Potato is the third most important global food crop and the most widely grown noncereal crop. As a species highly amenable to cell culture, it has a long history of biotechnology applications for crop improvement. This review begins with a historical perspective on potato improvement using biotechnology encompassing pathogen elimination, wide hybridization, ploidy manipulation and applications of cell culture. We describe the past developments and new approaches for gene transfer to potato. Transformation is highly effective for adding single genes to existing elite potato clones with no, or minimal, disturbances to their genetic background and represents the only effective way to produce isogenic lines of specific genotypes/cultivars. This is virtually impossible via traditional breeding as, due to the high heterozygosity in the tetraploid potato genome, the genetic integrity of potato clones is lost upon sexual reproduction as a result of allele segregation. These genetic attributes have also provided challenges for the development of genetic maps and applications of molecular markers and genomics in potato breeding. Various molecular approaches used to characterize loci, (candidate) genes and alleles in potato, and associating phenotype with genotype are also described. The recent determination of the potato genome sequence has presented new opportunities for genomewide assays to provide tools for gene discovery and enabling the development of robustly unique marker haplotypes spanning QTL regions. The latter will be useful in introgression breeding and whole‐genome approaches such as genomic selection to improve the efficiency of selecting elite clones and enhancing genetic gain over time.