Agricultural and Food Science, Vol. 17 (2008): 307–324. A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 307 © Agricultural and Food Science Manuscript received September 2007 Review article Plant biotechnology for deeper understanding, wider use and further development of agricultural and horticultural crops Paula Elomaa, Jussi J. Joensuu, Helena Korpelainen, Kristiina Mäkinen1, Viola Niklander-Teeri, Minna Pirhonen, Mervi M. Seppänen, Teemu H. Teeri and Jari P.T. Valkonen* Department of Applied Biology, PO Box 27, FI-00014 University of Helsinki, Finland 1Current address: Department of Applied Chemistry and Microbiology, PO Box 27, FI-00014 University of Helsinki, Finland, *e-mail: jari.valkonen@helsinki.fi Plants bind solar energy to organic matter via photosynthesis and assimilation of carbon dioxide from the atmosphere and comprise the major source of nutrition and bioenergy. Plant biotechnology contributes to solution of important constraints in food and feed production and creates new technologies and applications for the sustainable use of plant resources. Genome-wide approaches such as massive parallel sequencing and microarrays to study gene expression, molecular markers for selection of important traits in breeding, characterization of genetic diversity with the aforementioned approaches, and somatic hybridization and genetic transformation are important tools in plant biotechnology. In this paper, studies carried out on en- hanced resistance to viruses and tolerance of cold stress in potato, genetic modification of flower pigmenta- tion and morphology in gerbera, production of edible vaccines in transgenic barley seeds, and expression of heterologous proteins for pharmaceutical purposes from vector viruses were chosen to exemplify the general utility of biotechnological approaches and also how plant biotechnology research has developed on cultivated plants at University of Helsinki. The studies reveal cellular and genetic mechanisms and provide scientific information that can be used for widening the uses of crop plants. They can also be used to detect any putative risks associated with the use of the biotechnological application in agriculture and horticulture and to develop practises which reduce any inadvertent negative consequences that plant production may have to the environment. Key-words: plant biotechnology, molecular biology, crop production, horticulture, disease resistance, stress tolerance, metabolic pathway, biopharming, edible vaccine, cryotherapy A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 308 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 309 Introduction The photosynthesizing organisms, notably plants, are responsible for binding solar energy to organic matter and hence provide the source of food and bioenergy on earth. Owing to the growing human population and the globally increasing demand for energy and food, improved technologies for enhanced utilization of nutrients and renewable energy provided by plants are needed. Develop- ment of plant tissue culture techniques, discovery of DNA-modifying enzymes, and the technologies for genetically transforming cells provided grounds for development of plant biotechnology. Although gene technology represents only one of the areas of plant biotechnology and is not yet utilized in field crop or horticultural production in Finland, to public it is the best known field of biotechnology due to the debates about benefits and putative environmental and health risks associated with gene technology (Weaver and Morris 2005, Ramessar et al. 2007). The Faculty of Agriculture and Forestry (AF) at the University of Helsinki (UH) is devoted to promote sustainable use of renewable natural re- sources, including cultivated plants and forest trees. Plant biotechnology became an integral part of teaching and research at AF-UH soon after the relevant, fundamental key discoveries in plant molecular biology had been made abroad in the early 1980’s. The role of biotechnology continues to increase at AF-UH in collaboration with other departments and the Institute of Biotechnology that have recently moved to the Viikki Campus where the agricultural departments of UH have been lo- cated since the 1960s. Today, Viikki constitutes one of the largest life science campuses in Europe. The scientists in Viikki have extensive interna- tional collaboration networks, which is necessary for cutting-edge science, but in interest of space it will not be possible to refer to all details here. Looking to the past, the current strengths of the Viikki Campus in plant biotechnology developed in various projects at different institutes. While there is also no space to exclusively review the historical aspects, some of the main steps should be mentioned. Plant tissue culture methods paved the way to other techniques of plant biotechnol- ogy and were established for many species, includ- ing agricultural and horticultural crops and forest trees (Simola & Sopanen 1971, Tapio 1972, Simola & Honkanen 1983, Huhtinen et al. 1983, Simola 1985). They are an integral part of the breeding schemes utilizing somatic embryogenesis or hy- bridization and plant transformation procedures. Stable transformation of plant genomes using the natural mechanism encompassed by the Ti-plasmid of Agrobacterium tumefaciens, a plant-pathogenic bacterium, was achieved in several laboratories in the early 1980s (Bevan et al. 1983, Zambryski et al. 1983). Subsequently, the Finnish Innovation Fund SITRA funded a project to develop gene transfer methods and suitable expression vectors for plant transformation to acquire the technology for domestic use. The first PhD thesis in Finland utilizing gene transfer methods in plants came out from these activities (Teeri 1988). Gradually, more plant-related projects began to exploit gene technology and various other plant biotechnology methods such as somatic hybridization. The longest traditions in Finland are in bar- ley and potato biotechnology due to the outmost importance of these crops for the agriculture of this country. The first procedures for cell and tis- sue culture (Foroughi-Wehr et al. 1976, Sorvari 1986, Lührs and Lörz 1987) and regeneration of protoplasts (Yan et al. 1991) of barley were de- veloped in the 1970s and 1980s. Barley, as also other monocotyledonous plant species, was ini- tially found to be recalcitrant to Agrobacterium- mediated transformation. Therefore, alternative transformation methods such as gene delivery by electrophoresis (Ahokas 1989), biolistic particle bombardment, electroporation and micro-injection were developed. Among the first reports on stable transformation of barley were those published by teams of researchers at the Institute of Biotech- nology, UH, and the VTT Technological Research Centre Finland (VTT) who used particle bombard- ment as the method for transformation (Ritala et al. 1993, 1994). Later, successful methods for genetic transformation of barley were also reported with A. tumefaciens (Tingay et al. 1997). Developments in potato biotechnology are reviewed below. Forest A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 308 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 309 biotechnology experienced a break-through when transgenic birch trees were produced at the Univer- sity of Joensuu (Keinonen-Mettälä et al. 1998). The work was continued in Viikki at AF-UH (Pappinen et al. 2002). The key methods developed on birch are now among the cornerstones of the forest bio- technology research in the Viikki Campus which, however, is not reviewed here. Research and education on breeding, produc- tion and utilization of agricultural and horticultural plants and protection of crops against pests and diseases are the task of the relatively recently es- tablished Department of Applied Biology (DAB) at the AF-UH. The methods of plant biotechnology are widely used to study these topics and produce scientific data for development of relevant applica- tions. The bio-safety and environmental impacts related to plant biotechnology applications have also been actively investigated at DAB. For ex- ample, DAB has coordinated a national research programme entitled Environmental, Societal and Health Effects of Genetically Modified Organisms (ESGEMO) funded by the Academy of Finland and relevant ministries to provide sound, science-based information for authorities working on legislation and regulatory issues. The aim of this review is to highlight the cur- rent research in plant biotechnology carried out on agricultural and horticultural crops at DAB, and provide some visions for the future. The studies on potato biotechnology, flower development in gerbera, production of edible vaccines and heter- ologous proteins in plants, and the use of molecular markers will be highlighted as examples to illustrate how plant biotechnology could contribute to the ef- ficient and sustainable use of plant resources. Potato biotechnology Cultivation of potato (Solanum tuberosum L.) is based on vegetative propagation of cultivars by planting tubers. Potato is also the first major crop species (ranking the fourth in production in the world, Vreugdenhil et al. 2007) for which vegeta- tive propagation of plants in vitro was established using meristem tip culture (Morel and Martin 1955). The driving force at that time was the need to ob- tain virus-free and phytoplasma-free plants from infected cultivars and hence increase the yields of the crop. Potato belongs to the family Solanaceae also including tobacco (Nicotiana tabacum L.) that was the main model species for development of tissue culture techniques (Murashige and Skoog 1962) and plant transformation (Zambryski et al. 1983). Potato was also found to be amenable to these methods. Anther-derived haploid produc- tion (Wenzel and Uhrig 1981), protoplast fusion (Skarzhinskaya et al. 1982), somatic hybridization (Sidorov et al. 1987), genetic transformation (An et al. 1986) and other in vitro techniques have been widely used on potato for breeding and research purposes (reviewed in Bradshaw and Mackay 1994, Vreugdenhil et al. 2007). Boreal Plant Breeding Ltd utilizes the current methods of plant biotechnology in Finland. AF-UH has been involved in building up some of the tech- nologies used. The techniques required for potato protoplast fusion and interspecific somatic hybridi- zation were introduced to the former Department of Crop Husbandry (now part of DAB) at AF-UH in 1990. The studies were initially based on somatic hybrids developed at Rothamsted Experimental Station, UK, where some of the researchers had previously worked but where these activities were not continued (Pehu et al. 1990, Valkonen et al. 1991, 1994, Xu et al. 1993). There were also other departments with interest to enhance utilization of biotechnology and, hence, a joint biotechnology laboratory of AF-UH was established in the C- building in Viikki by several research groups from different departments. Studies on potato biotech- nology at DAB were continued in a joint project with the plant breeding unit of the MTT Agrifood Research Finland (MTT) and Boreal Plant Breeding Ltd. A few years later, UniCrop Ltd was founded by some of the researchers at AF-UH and the com- mercially oriented lines of plant biotechnology re- search moved to the company. The chain of events leading to establishment of plant biotechnology at AF-UH, including the challenges and difficulties in fitting academic studies and commercially oriented A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 310 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 311 research into the same laboratory at a university department, have been reviewed in detail by Tuu- nainen (2005a, 2005b). A novel biotechnology-based breeding scheme was developed by AF-UH, MTT and Boreal Plant Breeding Ltd to enhance potato breeding. Cultivat- ed potato is tetraploid (2n = 4x = 48) and cultivars are highly heterozygous. Reduction of ploidy to the dihaploid level (2n = 2x = 24) is needed for detec- tion of phenotypes that are masked in the tetraploid cultivars and also for crosses with many diploid (2n = 2x = 24) wild potato species (Watanabe et al. 1995). Therefore, anther culture-based haploid production from commercial potato cultivars was studied and developed (Tiainen 1992, Rokka et al. 1996a). The dihaploid potato lines were elec- trofused to obtain putative new cultivars (Rokka et al. 1996b). Protoplasts of the dihaploid potato lines were also electrofused with protoplasts of the diploid, disease-resistant wild species S. brevi- dens and S. acaule to introduce novel genes to the breeding material (Rokka et al. 1994, 1998). Sub- sequently, the interspecific somatic hybrids were subjected to haploid-induction via anther culture in order to reduce their ploidy levels (Rokka et al. 1995, Gavrilenko et al. 2002). The new ‘so- matohaploid’ plants were used for production of ‘second-generation’ somatic hybrids with dihaploid potato lines (Rokka et al. 2000, Gavrilenko et al. 2002). Hence, the cultivated potato gene pool and thereby fertility and chances to make sexual crosses with potato breeding lines were increased. Besides representing a novel potato breeding scheme based on biotechnology methods, the studies produced a lot of fundamental, new information about the somatic, cytogenetic and sexual compatibility of distantly related Solanum species and utility of the disease resistance traits expressed by them. It was also found that the somatic hybrids of potato and S. brevidens synthesize a novel glycoalkaloid that was not found in the parental genotypes (Laurila et al. 1996). This finding opened an important new line of research because glycoalkaloids are consid- ered as potential biomolecules in pharmaceutical industry, which is a study area currently pursued at VTT. The new possibilities which gene technology provides for improvement of important traits in crop plants were demonstrated in Finland already in the beginning of the 1990s. Institute of Biotech- nology, UH, and the state-owned company Kemira used gene technology to construct novel forms of virus resistance in potato. The innovation was based on knowledge at the molecular level of a vi- rus defence mechanism operating in mammalians. Potato plants were transformed with the 2’-5’ oli- goadenylate synthase gene that was isolated from rat. The gene plays a key role in the interferon- induced antiviral defense pathway in mammalians, including man. Results showed that transfer of the single gene from rat was sufficient for activation of resistance to Potato virus X (PVX) in potato (Truve et al. 1993). The level of protection was at least as good as that obtained using the coat protein gene of PVX for potato transformation. This latter approach, coined as pathogen-derived resistance, had been published a few years earlier in the USA (Powel-Abel et al. 1986). Kemira also collaborated with Moscow State University to develop broad- spectrum, pathogen-derived resistance to several viruses in potato using a modified viral movement protein gene as the transgene. The resistance was thought to be protein-mediated (Seppänen et al. 1997). At the same time at the former Department of Plant Production (now part of DAB) in AF-UH, potato cv. Pito was transformed with a genomic region of Potato virus Y (PVY) that encodes the first viral protein P1. The transgenic plants were highly and specifically resistant to PVY (Pehu et al. 1995). Inserting the transgene in an antisense (non protein-encoding) orientation to the potato ge- nome also provided resistance to PVY. Therefore, the resistance was RNA-mediated (Mäki-Valkama et al. 2000). All these innovations were patented. Currently, RNA-mediated inhibition of virus rep- lication and plant gene expression (called RNA silencing or RNAi) are widely studied and utilized techniques. They induce or mimic the natural cel- lular mechanism that regulates gene expression at an RNA level and also protects cells against vi- ruses (Haasnoot et al. 2007). In fact, it could be possible to control all viruses damaging potato by transforming potato cultivars to produce double- A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 310 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 311 stranded RNA (no protein) corresponding to a small region of the viral genome (Smith et al. 2000). Gene technology enhances the use of natural disease resistance in crop plants in multiple ways. RNAi mentioned above is one of the examples. Another one is mapping of natural resistance genes and development of accurate molecular markers for their selection in potato breeding programs, which is widely used (Gebhardt and Valkonen 2001, Ge- bhardt et al. 2006). Genetic mapping can be contin- ued to gene isolation and, eventually, the resistance gene can be transferred to susceptible cultivars by means of genetic engineering. The former Depart- ment of Plant Production (now part of DAB) and The Institute of Biotechnology at UH, and Cornell University in the USA identified the chromosomal locus of Ryadg, the first gene for resistance to PVY mapped in the potato genome (Hämäläinen et al. 1997). The same region of potato chromosome XI was found to contain also a gene for resistance to Potato virus A (PVA) (Hämäläinen et al. 1998, 2000). A gene (Nxphu) for resistance to PVX was mapped in the cultivated potato species S. phureja (Tommiska et al. 1998). Reliable polymerase chain reaction (PCR) based markers were developed for Ryadg (Sorri et al., 1999, Kasai et al. 2000) and are now used by potato breeders (e.g., Gebhardt et al. 2006, Rizza et al. 2006). Another gene, Rysto, that also confers extreme resistance to all strains of PVY was studied in potato materials originat- ing in the International Potato Center (CIP), Peru, and PCR-based markers were developed for use in breeding programmes (Valkonen et al. 2008). A resistance gene homologue from the chromosomal region containing Ryadg (Vidal et al. 2002) and two new potato genes encoding proteins that interact with the HC-Pro protein of PVA (Guo et al. 2003) have been isolated and their putative use as novel virus resistance factors is being elucidated. Many additional, putative genes involved in inducible re- sistance to viruses and Rhizoctonia solani in potato have been detected at DAB using potato cDNA microarrays (Lehtonen et al. 2008 b, A. Vuorinen, et al., unpublished). One of the early begun and still ongoing top- ics of plant research at UH with specific impor- tance for Nordic countries has been investigation of cold and frost tolerance in plants (Kurkela et al. 1988), including potato. Genes from a wild, cold-tolerant potato species, S. commersonii, have been introgressed to the cultivated potato gene pool via somatic hybridization and studied at DAB for their role in frost tolerance (Seppänen et al. 1998, 2000). Studies with a potato population derived from a self-pollinated somatic hybrid revealed that antioxidative capacity plays an important role in frost tolerance. Various genes responding to low temperatures or associated with accumulation of active oxygen species at low temperature and in- tensive light were identified (Seppänen and Fager- stedt 2000, Seppänen and Coleman 2003). These studies were continued to increase understanding of the genetic and physiological basis of the non- acclimated freezing tolerance in potato. Sequences of the genes responsive to low temperature were found to be nearly identical in the freezing tolerant and freezing sensitive potatoes, whereas the con- stitution of the cis-acting factors in the promoter sequences varied. Possibilities to engineer freezing tolerance in potato by the means of gene technol- ogy are currently under study by over-expressing the low temperature regulated genes and testing activation of the promoters following various en- vironmental stimuli in plants and tubers (M. Sep- pänen, G. Coleman and O. Junttila, unpublished). Since 2000, a large program has been carried out jointly by MTT (Ruukki research station, Seed Potato Biotechnology group), DAB and private sector stakeholders to utilize biotechnological methods for diagnostics of pathogens and analysis of physiology of seed potatoes in order to enhance quality and increase the export of seed potatoes from Finland. The main seed potato production area is located in northern Ostrobothnia with good soils for potato production in an area free of quar- antine pathogens and with a low pressure from potato pests and diseases. This High Grade Seed Potato Production Zone (approved by European Union) used to have a security zone of thousands of hectares in which potatoes from outside were not allowed to be grown. The first yields of the highest pathogen-indexed potato seed classes were harvested in the protected zone in 1976 (Pietar- inen and Seppänen 1981). Furthermore, DAB has A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 312 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 313 recently applied cryotherapy as a novel means for eradication of viruses and phytoplasma from veg- etatively propagated plants, which results in virus- free plants with a much higher frequency than the previously used methods (Wang et al. 2008, Wang and Valkonen 2008). At the same time, Laukaa Re- search and Elite Plant Unit of MTT has developed cryopreservation techniques for perennial horticul- tural plants (Wang et al. 2005) and in collaboration with DAB introduced the cryotherapy technique to healthy plant production. Consequently, Finland has become a forerunner in the use of this approach. These developments have their backgound in the 1970s when in vitro techniques were introduced to production of virus-free clones of potato varieties (Tapio 1972), currants, gooseberry, raspberry and strawberry (Bremer and Ylimäki 1978, Uosukainen and Kurppa 1988). These activities were linked to AF-UH in several ways. Many key persons worked as docents or professors in plant pathology at AF- UH or got their education at AF-UH. Biotechnology in horticultural species Research for developing biotechnological applica- tions and products in floriculture in Finland was initi- ated as a joint undertaking of the private and public sectors (Kemira and The Institute of Biotechnology, UH, respectively) at the end of the 1980s (Törmälä et al. 1992, Elomaa et al. 1993). Besides many or- namental species, the efforts were strongly focused on gerbera (Gerbera hybrida), one of the most popular and economically significant cut flowers in Finland and worldwide. The value of international trade of gerberas channelled via the Dutch market alone exceeds 100 million euro annually (Teeri et al. 2006a). Efficient tissue culture, micropropaga- tion and gene transfer methods were developed for this species (Törmälä et al. 1992). Consequently, modification of flowers colours in gerbera became one of the first examples of genetically modified traits in ornamentals (Elomaa et al. 1993). Later on, the possibility of producing genetically modified gerbera plants has greatly facilitated basic scientific research and made gerbera a well-recognized model species within flower developmental biology. This topic is currently emphasized at DAB (Teeri et al. 2006a, 2006b). The first genes isolated from gerbera belonged to the anthocyanin pathway (Helariutta et al. 1993, 1995a). They could be engineered to modify flower colour (Elomaa et al. 1993). They also served as marker genes in studies of inflorescence devel- opment since pigmentation patterns in various gerbera varieties are strictly correlated with the anatomy of the complex inflorescence (Helariutta et al. 1995b). More recent studies have identified a number of regulatory genes that are required for organ and tissue specific activation of biosynthetic genes and anthocyanin pigmentation (Elomaa et al. 1998, 2003). These studies have provided intrinsic scientific information about transcriptional regula- tion of gene expression in plants. Tissues of gerbera plants are very rich in sec- ondary compounds that are attractive targets for molecular breeding (Teeri et al. 2006a). The studies on flavonoid pathway genes led to the discovery of a novel gene function responsible for synthe- sis of secondary compounds involved in patho- gen and insect resistance in gerbera (Helariutta et al. 1995a, 1996, Eckermann et al. 1998). Recent studies at DAB indicate that the presence of these compounds correlates with resistance to Botrytis cinerea in different varieties of gerbera (S. Taalas and T. Teeri, unpublished). These studies serve as a good example of how results from basic research may quickly find their ways to applications. The inflorescence of gerbera consists of mor- phologically different types of flowers with highly specialized floral organs. The complex structure distinguishes it from traditional model species used for studies on flower development. To this end, research has focused on transcription factor genes that contain a conserved ‘MADS box’ do- main and encode key regulators of flower organ identity. Many novel functions for these regula- tors have been detected using transgenic plants that show distinct phenotypes. The results emphasize the importance of using gerbera for comparative A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 312 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 313 studies with other model species such as Arabi- dopsis thaliana (Yu et al. 1999, Kotilainen et al. 2000, Uimari et al. 2004, Teeri et al. 2006c). Re- cent studies have employed expressed sequence tag (EST) sequencing and cDNA microarrays for identification of new gene family members related to both secondary metabolism and flower devel- opment (Laitinen et al. 2005). Potentially useful genes for modification of fibre qualities for chemi- cal industry have also been detected (Toikkanen et al. 2007). Large-scale gene expression profiling has been used to study regulation of flower type identity (Laitinen et al. 2006) and transcriptional changes during petal organogenesis (Laitinen et al. 2007). Comparison of the developing ray and disc flower primordia uncovered the expression of many MADS box genes that respond to the radi- ally patterned zones of the capitulum. This finding implies that flower type-specific MADS box pro- tein complexes are needed to regulate organ iden- tity and differentiation of individual flower types (Laitinen et al. 2006). In addition to the MADS box regulators, the current work at DAB concentrates on ‘TCP domain’ transcription factors that are candidate regulators specifying flower type iden- tity (Cubas 2004). Studies on flower development in gerbera, including regulation of organ growth (Kotilainen et al. 1999), have contributed to the basic understanding as to how gene functions and morphological diversification of flowering plants evolve. The rapid development of tools applica- ble to genomics research will evidently open up new possibilities to develop molecular markers for the key traits in gerbera and enhance reeding programs. Strawberry (Fragaria × ananassa) represents another important horticultural species studied at DAB. It is the most important fruit crop culti- vated in Finland. Furthermore, strawberry and the diploid, related wild species Fragaria vesca are emerging new model species the family Rosaceae that contains a plenty of important horticultural plants. The current research at DAB in collabora- tion with MTT and University of Florida concen- trates on physiology and genetic regulation of flow- ering and also yield formation (Hytönen et al. 2004, Sønsteby and Hytönen 2005). The studies on the role of gibberellic acid (GA) in axillary bud differ- entiation in strawberry have already led to practical applications in the field. Strawberry yields can be increased by exogenous application of a GA bio- synthesis inhibitor, that enhances crown branching on the cost of runner production (K. Mouhu and T. Hytönen, unpublished). The genetic pathways con- trolling flowering in the short day adapted plants, such as strawberry, are still poorly understood but studies to this direction have been initiated. Se- quencing of cDNA subtraction libraries have been used to identify genes that are induced during the floral transition of Fragaria vesca. They will be critically tested for functions in transgenic plants. Production of heterologous proteins in plants Proteins intended for industrial and medical uses are needed in increasing amounts. Microbial systems are commonly used for production of heterologous proteins but they are not always optimal, e.g., be- cause certain post-translational modifications that occur in eukaryotic cells are lacking in microbes. Plants offer a safe, easily scaleable and cost-effective eukaryotic expression system for production of heterologous proteins. “Biopharming” of high-value proteins, such as the plant-made pharmaceuticals (PMP, including subunit vaccines and antibodies) for human and veterinary use, are targets of intensive academic research as well as commercial research and development (Fischer et al. 2004, Stoger et al. 2005, Floss et al. 2007). In USA and Canada, ca. 20 PMPs for human use are in clinical trials (most of them in Phase II) and some of them should reach the market stage in the near future (Spök 2007). The first PMP that has achieved a regulatory approval was a veterinary vaccine against Newcastle disease in poultry (February 26, 2006, in the USA) (Vermij and Waltz 2006). The system is based on protein expression in plant cells rather than whole plants and production is done in a secure, bio-contained environment. A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 314 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 315 DAB has recently led or been involved in three projects devoted to development of plant-based heterologous protein production systems. Two projects will be reviewed below. The third project is done in collaboration between VTT, AF-UH and Fibrogen Europe/Fibrogen Inc. and aims to pro- duce recombinant gelatine in barley seeds. The results from transgenic barley have clearly shown that the concept of using barley grains for produc- tion of industrially important proteins is applicable (reviewed in Mäkinen and Nuutila 2004). Production of edible vaccines in trans- genic plants There is significant interest on developing safe and inexpensive PMPs for use as veterinary vaccines. The approach offers advantages in safety and cost of delivery and manufacture. PMPs can be harvested, stored and delivered to target animals as they are, i.e. by directly mixing them with the animal feed. For example, edible leaves or grains are therefore good candidates for the vehicle of veterinary vac- cines. Furthermore, the regulatory processes are greatly simplified for animal vaccines, as compared to medical use. Orally administrated plant-made vaccines may also offer a future solution to the struggle against many diseases among wild animals, such as rabies, Newcastle disease, foot-and-mouth disease and Avian flu (Streatfield 2005) DAB has recently led the development of an oral vaccine to porcine postweaning diarrhea (PWD), which was carried out in collaboration with Department of Biosciences (UH), VTT, MTT, University of Ghent and University of Brussels. PWD is a major problem in pig farming in Finland and worldwide, resulting in significant economic losses, and no vaccine is available. PWD is caused by the F4-positive enterotoxigenic Escherichia coli (ETEC) strains. F4 fimbriae are the major coloniza- tion factors of the bacteria associated with PWD. The fimbriae are assembled as long polymers of the major subunit FaeG which is also responsible for the adhesive properties of the fimbriae. Being highly stable and mucosally immunogenic F4/ FaeG offer a unique model system to study oral vaccination against PWD (Van den Broeck et al. 1999, Verdonck et al. 2004). The FaeG gene isolated from an ETEC strain was initially used to transform tobacco plants to optimize the production system. As much as 70 mg FaeG per kilogram fresh weight (1 % of the total soluble proteins, TSP) was produced in the leaves of the transgenic tobacco plants when the recombinant protein was targeted to chloroplasts. The chloroplast-derived FaeG tolerated low pH and was resistant to proteolysis under the conditions simulating gastrointestinal tract of weaned piglets (Snoeck et al. 2004, Joensuu et al. 2004). FaeG could also bind the intestinal F4 receptor (F4R) and inhibit the F4-positive ETEC binding to F4R in a dose-dependent manner (Joensuu et al. 2004). Subsequently, immunogenicity of plant-pro- duced FaeG protein was studied by transforming edible alfalfa (Medicago sativa L.) and barley plants with FaeG. The chloroplast-targeted FaeG accumulated to 1 % of TSP in alfalfa leaves (100 mg / kg dry weight) (Joensuu et al. 2006b). FaeG accumulated also to 1 % of TSP (670 mg / kg dry weight) in barley seeds when the FaeG-encoding gene was expressed under an endosperm-specific promoter and subcellularly targeted to the endo- plasmic reticulum (Joensuu et al. 2006a). Desic- cated alfalfa leaves and barley grains maintained the FaeG protein in a stable form for years. These results were promising because sufficient concen- tration and stability over a long-term storage are requirements for edible vaccines. The most important finding of the study was that the plant-expressed FaeG was immunogenic to animals. When the TSP of barley seeds was injected subcutaneously to mice, F4-specific anti- body response was observed and the sera inhibited adhesion of the F4-positive ETEC to F4R on pig- let enterocytes in vitro (Joensuu et al. 2006a). The transgenic alfalfa plants were orally administered to weaned piglets, which resulted in F4-specific systemic and mucosal immune responses (Joensuu 2006, Joensuu et al. 2006b). In the following ETEC challenge the duration and number of E. coli excre- tion were significantly reduced to a level observed A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 314 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 315 with positive control group immunized with puri- fied F4 fimbriae. In conclusion, these results suggest that trans- genic plants producing the FaeG subunit protein could be used for production and delivery of mu- cosal vaccines against F4+ ETEC infections. Fur- thermore, structural modification of FaeG may provide additional possibilities. Because of their incomplete folding, fimbrial subunits are unstable and susceptible to aggregation and/or proteolytical degradation in the absence of their chaperone. How- ever, in chloroplasts FaeG protein was expressed in a stable and soluble form. FaeG was purified from chloroplasts, studied using x-ray crystallography and found to assemble to unusual strand-swapped dimers. While providing the first crystal structure of a plant-made vaccine (Van Molle et al. 2007) the results also allowed making a high-resolution model of structure of the F4 fimbria and paved a way to design of more immunogenic and stable FaeG vaccines in the future. Expression of heterologous proteins from a vector virus Viruses can be used as gene vectors to express heter- ologous proteins in the infected plants (reviewed by Pogue et al. 2002, Gleba et al. 2004). RNA viruses are particularly suitable for this purpose, also from biosafety point-of-view, because the viral RNA genome does not integrate into genome of the plant but replicates in the cytoplasm. As compared to transgenic plants, vector viruses offer a more speedy and flexible system for use, however, including the same benefits as with transgenic plants. Most viruses complete the systemic infection of plants within two weeks and most tissues of the plant would accumulate the heterologous protein by then. The vector-virus based production system can be transferred to any new host species or genotype of the virus simply by inoculation; no plant transforma- tion, regeneration and selection are needed. The genus Potyvirus contains the largest number of virus species (>150) infecting a vast number of plant species (Rajamäki et al. 2004), which makes them attractive as vector viruses. Furthermore, they express their genome as a large polyprotein that is subsequently processed to up to ten mature proteins by the viral proteinases. Hence, a foreign gene in- serted into the viral genome will be translated as part of the polyprotein and the heterologous protein produced in equimolar amounts with viral proteins. Proteolytic processing of the heterologous protein requires that the appropriate proteolytic cleavage sites are engineered to flank the protein. Following cleavage, a few amino acid residues from the viral polyprotein will remain at the termini of the heter- ologous protein. However, in most cases this does not seem to intervene with the activity or purpose of use of the heterologous protein. PVA belongs to potyviruses and has been a model for molecular studies of potyviruses at UH. The studies were initiated at the Institute of Biotechnology and are continued at AF-UH. A full-length, infectious cDNA is now available from two PVA strains with a slightly different host range (Puurand et al. 1996, Paalme et al. 2004). The potyviral genome contains two positions (P1/ HC-Pro and NIb/CP) suitable for inserting foreign sequences without greatly affecting viral infectiv- ity (Dolja et al. 1992, Varrelman and Maiss 2000) and can be used also in PVA (Ivanov et al. 2003, Kelloniemi et al. 2006). A third, novel cloning site inside the P1 encoding region of PVA was detected by a transposone-based insertion mutagenesis ap- proach (Kekarainen et al. 2002). Catechol-O-methyltransferase (S-COMT) is a human protein associated with the metabolism of chatechol estrogens and degradation of the catecholamine neurotransmitters dopamine and epinephrine. Recombinant S-COMT is needed in pharmaceutical industry for development S-COMT inhibitors for the treatment of Parkinson’s disease (Lundström et al. 1991). S-COMT was expressed in active form from the NIb/CP site of the PVA vector in Nicotiana plants (Kelloniemi et al. 2006). Yields of S-COMT reached 0.7-0.8 % of TSP, which is slightly less than 2 % observed with the viral coat protein, possibly due to lower stability of S-COMT. The cloning site in the P1 region was, in turn, used to express the green fluorescent protein (GFP) of jellyfish, Aequorea victoria (Rajamaki et A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 316 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 317 al. 2005). In both cases, virus levels were slightly reduced but, on the other hand, also symptoms were alleviated which is beneficial for the use of the production system. These results showed that human and animal proteins can be produced from the PVA vector in plants. Recently, the three cloning sites were combined in a single, chimeric PVA genome. The vector virus is infectious and produces the three heterologous proteins (Kelloniemi et al. 2008). This is the first viral vector from which three heterologous proteins can be produced simultaneously, which provides unique possibilities not only for PMP production but also scientific research. These examples dem- onstrate that while being harmful pathogens, the viruses also possess potential for development to biotechnological tools (Valkonen 2007). Molecular markers and their multiple uses DNA-based molecular markers differentiate indi- viduals based on single-base substitutions or larger genetic differences at the genome level. Many examples of the use of molecular markers for gene mapping and marker-assisted selection (MAS) in plant breeding have already been mentioned above. One additional example at DAB is the transfer of herbicide (imidazolinone, IMI) tolerance from Brassica napus L. to B. rapa L. by conventional means using hybrid breeding (Haukkapää et al. 2005, Niemelä et al. 2006). The tolerance of IMI is based on a chemically induced mutation of the acetolactate synthase (ALS) gene in B. napus (Swanson et al. 1989). MAS is used for selection of the mutated ALS gene and the fertility-restoring (Rf) gene that is needed to overcome cytoplasmic male sterility of the hybrids. Furthermore, plants homozygous and heterozygous for the Rf locus are distinguished using allelic specific probes and quantitative polymerase chain reaction (A.-L. Haukkapää, T. Niemelä, U. Tulisalo and M. Sep- pänen, unpublished). DNA markers are mostly phenotypically and selectively neutral and thus suitable for studies on population genetics and gene flow. Molecular and population genetics studies are carried out at DAB on several plant groups, including also al- gae and non-vascular plants such as mosses which are photosynthesizing organisms important to the ecosystems affected by or interacting with the ag- ricultural and forest environments. For example, mosses are used as model organisms to study gene flow, population genetic structures and adaptation (Korpelainen et al. 2005, Pohjamo et al. 2006) and also evolution of pathogen resistance in plants (Akita and Valkonen 2002, Andersson et al. 2005, Lehtonen et al. 2006). Dispersal, colonization and gene flow are important to species in order to avoid population decline and extinction. They are particularly important to endangered species that may suffer from fragmentation of habitats and the genetic, demographic and environmental con- sequences of the decrease in population size. Many types of molecular markers are used to study gene flow, plant genetic resources and the early stages of gender determination of dioecious plant species (Korpelainen 2002, Korpelainen et al. 2007, Kor- pelainen and Kostamo 2007). Novel transposon- based markers for plants have been developed in the MTT research laboratory located in the Viikki campus (Kalendar et al. 1999). Molecular markers are also widely used for the study of plant pathogens, plant-microbe interac- tions, pathogen populations and microbial ecology. These are important study areas related to plant biotechnology carried out at DAB (Lehtonen et al. 2004, 2008a, Mattinen et al. 2004, Aittamaa et al. 2008, Hiltunen et al. 2008), other departments of AF-UH and the Viikki Campus (e.g., Pitkäjärvi et al. 2003, Jussila et al. 2006, Sjöblom et al. 2006). At DAB, these studies are carried out on many crop plant species and their pathogens and also on the model species Arabidopsis thaliana (Karim et al. 2007) and the moss, Physcomitrella patens, to un- derstand evolutionary early-developed mechanisms of pathogen defence in plants (Akita and Valkonen 2002, Andersson et al. 2005, Lehtonen et al. 2006). However, these study areas are not emphasized in this review. A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 316 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 317 Transfer of knowledge in biotechnology and biosafety issues to agricultural institutes in the developing countries (e.g., the BIO-EARN pro- gramme with East African countries and the NI- FAPRO project with Nicaragua) is considered as an important task at DAB and at AF-UH. The use and development of various kinds of molecular markers are typically included in these projects as the techniques are relatively robust and can be acquired in newly established laboratories which do not yet have a large range of equipment. Considering also the study fields of agroecolo- gy and agricultural entomology affiliated at DAB, the department has a broad and deep expertise not only for developing plant-based biotechnological applications for agricultural and horticultural use but also for studying and monitoring the envi- ronment with the help of molecular tools (e.g., Seppänen et al. 2007). This is important for risk assessment and development of practises which reduce any inadvertent negative consequences that plant production may have to the environ- ment. Structures facilitating progress in plant biotechnology research Plant biotechnology is one of the strengths at AF- UH and the Viikki campus, both from the national and international perspective. This is largely the result of close and fruitful collaboration of the research groups affiliated by different departments and faculties and the national and international collaboration. These developments need to be supported and continued. At AF-UH, the merger of several small depart- ments to form the current DAB in 2002 brought all plant science-oriented disciplines administra- tively together. Consequently, crop science, plant breeding, plant pathology and horticulture cur- rently share the same laboratory space and equip- ment at DAB. The close interaction has resulted in new joint research interests, including devel- opment of plant viruses as gene silencing tools for studies in functional genomics. Joint research activities across faculty borders have been an important foundation for the very well developed collaboration in teaching of courses in plant science. Furthermore, a national graduate school in plant sciences is coordinated from the Viikki campus. A Centre of Excellence (CoE) has been formed in Viikki and funding awarded by the Academy of Finland for periods of 2000-2005 (CoE in Plant Molecular Biology and Forest Bio- technology) and 2006-2011 (CoE in Plant Signal Research). One of its most significant achieve- ments has been the development of plant genome resources for a wide use in Finland, e.g., the large EST collection of spruce (Koutaniemi et al. 2007) and birch, and the microarray of birch. The plans include that the strong plant science community at Viikki campus will be reinforced by gathering all scientists who are involved in ex- perimental plant research to a joint “Viikki Plant Science Centre” (VPSC) which could also affiliate research groups from other organizations, as appro- priate. This is feasible due to the already existing collaboration in research and teaching which can be further synergized. VPSC will be particularly im- portant for maintenance of the up-to-date research facilities and technologies specifically required for plant biotechnology. Some of the core facilities and technology platforms needed in plant biotechnol- ogy research are maintained by the Institute of Biotechnology but used by all research groups in the Viikki Campus. These platforms included elec- tron microscopy, DNA sequencing, and microar- ray and protein analysis that are essential for plant genomics research. The research groups using the facilities have also contributed to their develop- ment in terms of funding and expertise. Indeed, concentrating the more expensive and demanding technologies to the commonly shared platforms is crucial for maintaining the cutting-edge, rapidly developing technologies and know-how of them at the reach of the plant research community in Viikki. The latest addition to the arsenal of high throughput sequencing is the “454” massive par- allel sequencing platform, with which sequencing of the EST libraries of gerbera and strawberry and A G R I C U L T U R A L A N D F O O D S C I E N C E Elomaa, P. et al. Plant biotechnology 318 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 17 (2008): 307–324. 319 the full genome of the bacterial potato pathogen, Pectobacterium carotovorum, will be achieved by the end of 2008. In conclusion, plant biotechnology research at AF-UH and the Viikki campus contributes to so- lution of the important domestic pitfalls in plant production and creates new technologies and ap- plications for the sustainable use of plant resources. Renewable biomass resources are needed to re- place the fossil fuels. Value-added crops capable to produce new types of biopolymers and structural components should be developed. 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Joensuu, Helena Korpelainen, Kristiina Mäkinen, Viola Niklander-Teeri, Minna Pirhonen, Mervi M. Seppänen, Teemu H. Teeri ja Jari P.T. Valkonen Helsingin yliopisto Yhteyttävät kasvit ovat ravinnon ja bioenergian ensisi- jainen lähde maapallolla. Viljelykasvien ominaisuuksia muokkaamalla sekä kasvien biosynteesikoneistoa eri tavoin hyödyntämällä pyritään vastaamaan haasteisiin, joita väestönkasvu ja sen myötä lisääntyvä energian sekä ravinnon tarve tuovat ihmiskunnalle. Lisäksi on pyrittävä hillitsemään ilmastonmuutosta. Tämän katsauksen tar- koituksena on osoittaa, kuinka kasvibioteknologia auttaa vastaamaan näihin haasteisiin. Esimerkkeinä käytetään mm. perunan jalostukseen, viruskestävyyteen ja kylmyy- densietoon sekä sädelatvan (gerberan) kukankehitykseen ja kukintaan kohdistuvaa bioteknologista tutkimusta. Se on tuottanut tietoa tärkeiden kasvigeenien sijainnista ja rakenteesta kasvigenomeissa, geenien säätelystä ke- hityksen aikana sekä geenien reagoinnista ympäristön muutoksiin ja taudinaiheuttajien tartuntaan. Näitä tietoja tarvitaan, jotta kasvien tuottavuutta ja kasvituotteiden laatua voidaan entisestään parantaa mm. biotekniikan keinoin. Molekyyligeneettiset tutkimukset tuottavat myös geenimerkkejä, joilla voidaan tehostaa perinteistä risteytysjalostusta. Geenitekniikan avulla on voitu ke- hittää uusia viruskestävyyden mekanismeja kasveihin. Biotekniikan menetelmiä voidaan hyödyntää myös syötävien rokotteiden tuottamiseen sekä farmasianteol- lisuuden tarvitsemien proteiinien tuotantoon kasveissa. Toisaalta biotekniikan menetelmiä tarvitaan geenivarojen kartoittamiseen sekä geneettisen monimuotoisuuden ja geenivirtojen selvittämiseen kasvipopulaatioissa. Näillä tutkimuksilla on merkitystä niin kasvien geenivarojen hyödyntämiselle kuin riskien tunnistamiselle sekä sel- laisten viljelykäytäntöjen kehittämiselle, joilla voidaan ehkäistä maa- ja puutarhatalouden haittavaikutuksia vil- jely-ympäristön ulkopuolella. Tulevaisuudessa kasvibio- tekniikalla nähdään entistä suurempi merkitys haettaessa ratkaisuja suuriin haasteisiin, jotka liittyvät ihmiskunnan selviytymiseen. Tähän tarvitaan kasvibiotekniikan osaa- misen kartuttamista myös kehitysmaissa. Plant biotechnology for deeper understanding, wider use and further development of agricultural and horticultural crops Introduction Potato biotechnology Biotechnology in horticultural species Production of heterologous proteins in plants Molecular markers and their multiple uses Structures facilitating progressin plant biotechnology research References SELOSTUS