Abstract
Management of soft rot Pectobacteriaceae (SRP) is a challenge as there are no control agents available and no effective resistance present in commercial cultivars. In addition, many species of SRP have a broad host range and spread via rotten plant material takes place readily. In this chapter, the possibilities for disease management are outlined. Management is mainly based on seed certification to limit the risks of using infected planting material, and on hygiene and cultivation practices that reduce cross-contamination within and between seed lots. Balanced nutrition also supports the suppressiveness of crops against SRP. Experimental data show that inoculum in seed tubers can be reduced by thermotherapy and the use of biocides. Under controlled conditions, application of seed potatoes with biocontrol agents has showed promising results but few data are present on the efficacy of biocontrol in the field. Resistance in wild Solanum species against SRP has been found but to date no genes have been transferred to cultivars. However, new breeding technologies, such as CRISPR/CAS 9 and the use of true potato seed (TPS), will give us new perspectives on the generation of resistant cultivars.
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6.1 Introduction
The control of plant diseases caused by soft rot Pectobacteriaceae (SRP) is highly challenging. Until now, no commercially available control agents have been developed to effectively control SRP infections in agriculturally important crops. In addition, no host crops immune to SRP have been developed, while the use of SRP-resistant crops generated using biotechnology, although promising, is not widely accepted. In potato, the use of SRP-free certified planting material, in combination with the application of adequate cultural and hygienic measures, is still the most effective strategy to reduce contamination and disease prevalence. Within the certification scheme, the use of minitubers grown from pathogen-free in vitro plants significantly contributes to the management of the disease. Nevertheless, infections in the first generations frequently occur, whereas the main source of initial infection is still unknown despite the identification of several potential infection sources (see Chap. 3). In this chapter, testing and certification of planting material, the use of cultivation measures and hygiene, options to treat plant material, and the perspectives for resistance breeding will be discussed for potato (Sects. 6.2–6.6) and to a lesser extent, due to lack of available information, other hosts including chicory, Chinese cabbage and ornamental crops (Sect. 6.7).
6.2 Seed Testing and Certification in Potato
The health, vigour and yield of a potato crop are strongly influenced by the quality of the seed tubers (Haverkort and Struik 2015). Seed potatoes are generally the most expensive input for a seed crop (www.fao.org/potato-2008/en/potato/cultivation.html) but a high marketable yield can offset these costs, and planting healthy seed potatoes is therefore a key factor in maximising the marketable yield of a crop.
Potato is a vegetatively propagated crop and, unlike true seed propagation, such plants are prone to disease and deterioration in quality with each propagation cycle. Many potato-producing countries mitigate this risk using a certification program, which provides assurance to customers that seed potatoes meet specified minimum health standards.
Certification is the process of assuring the quality of seed potatoes that are being marketed. Seed potato certification programs ensure the production and supply of seed potatoes in which disease, predominantly seed-borne, has been monitored, controlled and maintained below a threshold that could cause significant losses to customers (www.unece.org/trade/agr/standard/potatoes). The United Nations Economic Commission for Europe (UNECE) acknowledges that strict tolerances at the growing crop and tuber inspections are an important tool in controlling blackleg in certified seed.
6.2.1 Certification and Testing in Europe
Certification is under official control of the government designated authority in the producing country and many countries have their own national standards that may be stricter than regulated standards. In the EU, certification is regulated by Directives 2014/20/EU and 2014/21/21/EU. Seed certification programs normally start with the production and multiplication of in vitro pathogen-free microplants (nuclear stock). Nuclear stock microplants undergo an extensive testing program to ensure freedom from disease. These microplants are multiplied in a protected facility to produce Pre-basic Tissue Culture (PBTC) minitubers, to comply with International Standards for Phytosanitary Measures (ISPM) guidelines. These PBTC minitubers are the input seed for the first field grown generation of seed potatoes. In the EU, seed potato crops are categorised depending on the health and the field generation. These categories are Pre-basic (PB), Basic and Certified as recommended in the UNECE standard for seed potatoes (UNECE 2018; www.unece.org/trade/agr/standard/potatoes). Seed certification programs typically restrict the maximum number of generations permitted for seed crops. As the number of field generations increases, the disease tolerance applicable to each grade relaxes slightly to account for each additional propagation cycle (Table 6.1).
Crops entered for certification are inspected at least twice during the growing season. A random representative sample of plants is inspected for pathological and physiological faults and the incidence of disease is expressed as a percentage of the crop. Many diseases and faults can be controlled through roguing to ensure the crop meets the required tolerances at inspection. Roguing is the removal of potato plants that are atypical of the cultivar in appearance or diseased, including plants presenting blackleg or wilting symptoms (Kerlan et al. 1987). Effective roguing ensures that sources of infection are removed from the crop during the growing season and less symptomatic material is harvested with the crop. This reduces disease spread and losses in storage. Certification is normally based on a visual assessment of the crop. However, some countries choose to use laboratory testing in addition to a visual inspection for some diseases, particularly virus related, to detect and control latent or late infections. Tables 6.1 and 6.2 detail the tolerances for blackleg and tuber soft rot applied at growing crop and lot inspections for the top 5 seed potato producing countries in the EU for blackleg and soft rot, respectively.
There are no official post-harvest diagnostic testing programs for SRP, although advisory testing is offered in some countries for management purposes. In a pilot study, the Netherlands experimented with obligatory post-harvest tests for blackleg causing SRP between 2012 and 2018. All marketable PB and S class seed material was tested for SRP by qPCR. The objective of the experiment was to support farmers in selecting PB and S class seed in order to reduce the incidence of blackleg in the seed potato chain. Initial results showed a clear correlation between latent infection in the sample and blackleg symptoms in the field in the following year. However, this correlation varied between the different SRP, possibly due to variation in virulence, resulting in the test being deemed unsuitable for certification purposes.
Although certification schemes in most countries are similar in their approach to the management of blackleg, their regulations account for local plant health pressures and there is flexibility to adapt the scheme accordingly.
6.2.2 Certification and Testing in Canada
To impede introduction of foreign pests, Canada limits entry of potatoes for planting to tissue-cultured plantlets, except from the US. Imported plantlets are screened within a Potato Post-Entry Quarantine (PPEQ) Program operated by the Canadian Food Inspection Agency (CFIA) to ensure freedom from all pathogens, including blackleg- and soft rot-causing bacteria. Laboratory testing in the PPEQ program utilizes ISO17025 certified methodologies for ELISA, PCR, qPCR and Next Generation Sequencing (NGS) tests to detect pathogens. Laboratory testing of potato plantlets is complemented with grow-out tests in contained greenhouse space. Other potential avenues of introducing foreign pathogens such as flower bulbs and ornamental plants are addressed by import requirements and visual inspections.
The Canadian seed potato program combines tolerances for blackleg disease with all wilts and certifies based solely on field scouting and visual inspection of plants during the growing season. The nuclear and pre-elite are the highest of eight classes of seed potatoes in the certification scheme and they have a zero tolerance level for blackleg and wilt, while the lowest class, the certified class, has a tolerance of 3% for blackleg and wilt during seasonal inspections and a 2% tolerance for the last field inspection. The intermediate classes of seed have tolerances ranging from 0.1 to 1.0%. As in Europe, roguing is an acceptable practice to lower the incidence of blackleg and wilts in seed potato crops and is used by growers as a management strategy to ensure these diseases are within tolerance levels. The Canadian seed potato certification program relies on the use of pathogen-tested tissue culture for the nuclear class and the flush through concept, in which each next generation is automatically downgraded one class, to control tuber-borne diseases such as blackleg.
Other than for the seed potato certification program, CFIA does not conduct national regulatory testing or certification of stock potato production for any of the soft rotting plant pathogens. However, some of the provincial departments of agriculture carry out their own field scouting and laboratory testing and diagnosis for plant pathogenic pests, including those causing blackleg and soft rot diseases.
While not required for certification, the CFIA has laboratory capacity to test for and identify SRP. The laboratory has available immunofluorescence and ELISA protocols for identifying P. atrosepticum, and PCR methods for detecting and identifying SRP associated with potatoes (see Chap. 5). Some commercial laboratories in Canada that offer plant diagnostic services also have the capability to test for SRP but none have been approved by the certification agency to conduct these tests for domestic or international trade requirements.
6.3 Cultivation Measures and Hygiene
6.3.1 Use of Clean Seed and Planting in Pathogen-Free Area
As SRP are seed-borne pathogens, they can move during plant growth from infected plant tissue, including the mother tuber, via free water in soil to progeny tubers or through the vascular system of the plant. During (post)harvest activities, contact with infected (rotten) tubers and contaminated machinery can result in a further increase of infection rates (Ansermet et al. 2016; Czajkowski et al. 2012a). Therefore, the use of clean seed is the most important cultivation measure to control SRP populations in potato crops. This can be achieved by beginning with good hygiene in the early stages of plant material multiplication to ensure pathogen-free propagative material (Baghaee Ravari et al. 2013). This is usually achieved through the implementation of seed certification schemes (see Sect. 6.2). The efficiency of control is variable, due partly to the presence of latent infections in seed lots that can persist even in multiple consecutive generations. Prevailing environmental conditions play an important role in disease development and expression (Czajkowski et al. 2011b; Bontemps-Gallo et al. 2013; Dubois Gill et al. 2014).
In theory, cutting of seed can facilitate infections through wounds, and possibly transmit the pathogens through bacteria remaining on the device used to cut the seeds. De-sprouting of tubers at planting may also transmit the pathogen (Elphinstone and Toth 2007). Wastie et al. (1994) investigated the effect of seed tuber inoculation with P. atrosepticum on the development of blackleg symptoms and on yield in 15 cultivars. Tubers were planted either whole or as pieces. Inoculations reduced the mean yield per plant by 8% for whole tubers and by 12% for cut tubers, although there was no correlation between blackleg symptoms and yield loss. In the Netherlands, it is generally seen that if seed cutting is done with a cutting knife that is continuously disinfected, and freshly cut tubers are treated with talcum powder to absorb moisture, no increase in blackleg prevalence is found (Van der Wolf, Wageningen, NL, pers. comm.). Planting in potato production areas free from specific SRP is another option to avoid an increase in blackleg intensity. In these protected areas, measures should be taken to avoid the introduction of new SRP species through import of infected planting material (Lumb et al. 1986; Sławiak et al. 2009; Laurila et al. 2008; Tsror et al. 2009). It further requires intensive surveys and an effective eradication program to prevent spread of the pathogen in case of an outbreak. In countries with a so-called “Safe-Havens Scheme” the introduction of SRP from abroad are avoided but not necessarily the dissemination of pathogens regionally (Toth et al. 2011). Only disease‐free micro-propagation material can be imported from outside the area, and subsequent generations should be grown on farms that cannot use seed tubers produced outside the scheme (Potato_Council 2009). As a result, so far D. solani has never been found on seed potatoes grown in Scottish fields, including those grown from Scottish origin seed (Saddler, SASA, Edinburgh, Scotland, unpublished results).
6.3.2 Influence of Soil Conditions on Blackleg and Soft Rot
Several studies have been conducted to determine the survival of SRP in soil, although results are often biased by the lack of sensitive detection methods (Pérombelon and Hyman 1989; EFSA 2013a, b). Even the most sensitive detection methods, based on enrichment and the use of DNA-amplification, have a limit of detection higher than the cell densities able to infect plant roots (EFSA 2013a, b). In addition, SRP present in a viable but not-culturable (VNBC) state in the soil will go unnoticed if detection methods reliant on culturing are used (McDougald et al. 1998). Nonetheless, studies on the survival of SRP in soil have shown that it is unlikely that these pathogens can overwinter freely for extended periods in soil in the absence of a host or plant debris. Introduction of SRP into pathogen-free soils can occur through irrigation or surface water, aerosols (Franc et al. 1984; Graham et al. 1977) or through survival in weeds or volunteers (Tsror et al. 2010), subsequently leading to infection of crops (see also Chap. 3). Soil moisture content, temperature, soil nutrient status, organic matter content and soil microbial composition all play a role in pathogen survival (Pérombelon and Hyman 1989; Moh et al. 2011; Czajkowski et al. 2011b). A high soil moisture is conducive for pathogen survival, proliferation and disease development as was found for experiments with D. solani in soil in which root infections occurred more easily in wet than in dry soil (Czajkowski et al. 2010). Rahman et al. (2012) confirmed that irrigation creates a moist soil environment, which favours infections by blackleg pathogens. The same is true for the development of diseases in other hosts, for example, soft rot of Zantedeschia spp. caused by Pectobacterium carotovorum is most severe when plants are under stress from low soil aeration, high temperatures or high humidity (Funnell and Mackay 1999; Wright and Burge 2000; Luzzatto et al. 2007), as is the case with soft rot of carrots (Farrar et al. 2000). Therefore, planting in well-drained soils and avoiding over-irrigation can help to reduce disease development.
6.3.3 Effect of Plant Nutrition on Blackleg and Soft Rot
Nutrition affects the resistance/tolerance status of the plant and/or virulence of the pathogen. Plants with an optimal nutritional status have the highest resistance to disease, while deficiency or an excess of essential elements may result in an increased susceptibility to diseases (McGovern et al. 1985; Huber et al. 2012).
Nitrogen (N) is the fourth most abundant element in plants and is found in various parts of the plant in different forms. N is a component of proteins, enzymes, hormones, phenolics and phytoalexins, which all affect disease development (Huber and Thompson 2007; Elmer and Datnoff 2014). The effect of nitrogen levels on blackleg has been explored by Graham and Harper (1966), who showed that blackleg incidence caused by P. atrosepticum was lower in field plots with a relatively high N supply (Fig. 6.1). With a low amount of 56 kgN/ha, an average of 25% of blackleg was observed at the end of the growing season, while with a high amount of 224 kg N/ha the percentage of blackleg was about 10% lower (16%). Graham and Harper (1966) observed that there was no interaction between variety and nitrogen supply, suggesting that this tendency holds whatever the variety. Others found that a high nitrogen supply promotes blackleg. For example, Dubois Gill et al. (2014) indicated that N input, jointly with the content of organic matter in the soil, contributes to 9% of the variability of blackleg symptom expression in the field. High nitrogen supply also increases nitrate content in the progeny tubers (Maltas et al. 2018), which could theoretically promote the development of soft rot in the progeny tubers after harvest through a proliferation of SRP using nitrates simultaneously as a nitrogen source and an electron acceptor (Smid et al. 1993). Nevertheless, this has never been experimentally tested with potatoes. A high N supply may also have other negative effects on potato crops, e.g. by increasing the incidence of late blight of foliage (Bangemann et al. 2014) or reducing starch content in the progeny tubers (Maltas et al. 2018).
Calcium (Ca) is a macronutrient improving the structural integrity of the cell membrane and cell wall components and is also involved in numerous biotic and abiotic environmental signals (Dodd et al. 2010; Lecourieux et al. 2006). The Ca content in plant tissues has been positively correlated with resistance against SRP in several studies (McGuire and Kelman 1984; da Silva Felix et al. 2017). The mode of action of Ca against SRP appears to be due to an interaction of Ca ions with cell wall pectin, which strengthens the plant cell walls and results in higher resistance to pectinolytic enzymes released by SRP that act to degrade the cell wall (White and Broadley 2003; Barras et al. 1994). Ca fertilization is known to reduce soft rot caused by SRP in Chinese cabbage (da Silva Felix et al. 2017; Park 1969), in bean (Platero and Tejerina 1976), in chicory (Schöber and Vermeulen 1999) and in potato (Ngadze et al. 2014; McGuire and Kelman 1984; Lambert 1991; Ngadze 2018b). However, field trials in Scotland by McGuire and Kelman (1984) revealed that bacterial soft rot caused by P. atrosepticum is negatively correlated with Ca concentration in tubers, and Mantsebo et al. (2014) came to the same conclusions for P. brasiliense after field trials planted in Zimbabwe. A study of blackleg control carried out with tubers inoculated with P. atrosepticum and planted in soils enriched with gypsum (CaSO4) at a rate of up to 27 tonnes/ha, revealed a delay in the outbreaks of blackleg symptoms (Bain et al. 1996). Nevertheless, no significant difference in blackleg incidence was observed 15 weeks after planting. A more recent study using calcium nitrate as an amendment revealed that a supply of 250 kg/ha (19% Ca) allowed an average reduction of 20% blackleg symptoms, with a maximum of 50% (Ngadze 2018a). The corresponding experiments were carried out with seed tubers inoculated with a mixture of P. atrosepticum, P. brasiliense and D. dadantii. In this study, the blackleg incidence in Ca enriched plots remained lower even 12 weeks after emergence (Fig. 6.2). While soil with Ca amendment appears to have an effect on blackleg and soft rot symptom expression, seed treatment with Ca had no clear effect on soft rot disease (Bartz and Kelman 1986) It must also be considered that Ca amendment can promote the development of other potato diseases such as common scab, as the content of exchangeable Ca in the soil favours the development of this disease (Lambert 1991; Goto 1985; Davis et al. 1974).
Higher magnesium (Mg) content in tubers was found to correlate with a lower soft rot incidence (McGuire and Kelman 1986), as well as a lower stem rot incidence (Bain et al. 1996) but to a lesser degree than equivalent amounts of Ca. These experimental data are in line with the results of Dubois Gill et al. (2014) indicating that Mg input can delay blackleg disease outbreaks in the field.
In conclusion, plant nutrition has an influence on soft rot and blackleg incidence. Plant nutrition also affects other diseases and is a determinant factor for potato yield and quality (Lambert et al. 2005). Several examples are given above to show that adapting fertilization may reduce blackleg and/or soft rot incidence, although this may also have detrimental effects on other diseases and on potato quality. Balancing nutrition in the potato crop is therefore an important aspect of production.
6.3.4 Minimising the Sources of Infection (Plant Debris, Alternative Hosts and Roguing)
When a crop is grown for marketing as seed potatoes, roguing is a key component in maintaining the health status of the crop. Roguing of blackleg diseased potato plants is recommended by the seed certification procedures. Nevertheless, the efficacy of this method in controlling the spread of SRP bacteria is controversial since it does not always ensure sanitization of the entire crop (Bonde 1950; Pérombelon 1992). In the Netherlands, the efficacy of roguing has been tested experimentally but results were inconclusive (Boomsma et al. 2012). It is expected that roguing in controlling blackleg is only effective if the entire plant is physically removed, including the mother tuber as well as the progeny tubers, and measures are taken to prevent contact of diseased tissue with other plants in the field (De Boer et al. 2012).
Volunteer plants can be a concern in potato-growing areas for various reasons: they can be a source of varietal mixtures in potato crops, pose weed control issues in other field crops and can also act as a reservoir for potato pathogens where they may impact on the phytosanitary status of seed potatoes. These volunteer plants grow from tubers remaining in the field following harvest because a significant proportion of tubers are too small to be collected by harvesters and will remain in the soil over the winter crop (Rakotonindraina et al. 2011). Nevertheless, in climates in which the top layer of soils are frozen during winter time, the survival of those volunteers is limited and clearly less than the time period from one potato crop to another in an average crop rotation system (c. 3–5 years). During this time, the volunteers would have been destroyed by frost or due to the decay of the mother tuber (Lutman 1977; Boydston et al. 2006; Cooke et al. 2011; Pérombelon 1992). Therefore, it is recommended that short crop rotations be avoided (Elphinstone and Toth 2007). When volunteers are present in the potato crop, it is fundamental to remove them from the field as soon as possible as they may be a source of SRP inoculum (Toth et al. 2011) but also an inoculum source for other pathogens, such as viruses or Phytophthora infestans.
Most of the weed species in temperate regions are annual plants (Simić et al. 2016) growing in spring after germination of the seed. Some of these weeds are known hosts of Pectobacterium and/or Dickeya spp., such as plants of the Amaranthaceae, Brassicaceae, Fabaceae and Poaceae families (reviewed in Ma et al. 2007). SRP can be found on weeds in potato fields (see Sect. 3.2.4). For example, P. atrosepticum was detected in 15% of the weed samples collected in two potato fields in Scotland (Avinash et al. 2013) but it is not known whether those weeds were infected from potato plants or from other sources in the potato ecosystem. It is further unknown whether potato plants can become infected via contact with contaminated weeds. Finally, debris remaining from a previous non-potato crop may present a threat to the following potato crop (Toth et al. 2006). For cropping systems using rotation, potato crops can be infected by debris of other crops that have been identified as hosts of SRP. For example, sugar beet and sunflower are known to be hosts of Pectobacterium spp., while carrot and chicory are known as hosts for both Dickeya and Pectobacterium spp. (Ma et al. 2007; Baştaş et al. 2009; De Haan and Garcia Diaz 2002). While there is no clear data on the importance of this potential source of contamination, as a precaution it is recommended that these crops do not appear in a rotation prior to potatoes.
6.3.5 Haulm Killing Management and Harvest Management
It is a common practice to destroy the potato crop by killing the haulm when it is still partly green and tubers are still growing, inducing the artificial maturation of the progeny tubers, especially skin setting. This haulm killing can be performed mechanically, chemically or by combining mechanical and chemical methods (Kempenaar and Struik 2007).
Pérombelon et al. (1979) showed that P. atrosepticum was present in aerosols produced during mechanical haulm destruction (haulm flailing) of potato crops presenting blackleg. The authors concluded that mechanical haulm killing in seed crops with blackleg would increase contamination and disease risk in subsequent crops. Nevertheless, the infection of the progeny tubers was not evaluated in this experiment. More recently, trials were set up in Scotland to compare the effects of mechanical haulm killing (haulm flailing) with chemical haulm killing (Diquat—0.34 l/ha) in two potato fields heavily infected by P. atrosepticum (61 and 27% of blackleg) (Wale et al. 2013). In these experiments, there was no evidence that mechanical haulm killing resulted in increased contamination of the progeny tubers over the chemical (Diquat) treatment. However, this experiment was performed only twice and it may be that the risk would be higher when haulm destruction is performed in wet conditions, as bacteria could multiply in debris remaining on the soil surface after flailing of the haulm and may infect the progeny tubers underground (Burgess et al. 1994; Kastelein et al. 2020). It is also recommended that rapid haulm destruction is performed to reduce the exposure of the crop to potential infection (Elphinstone and Toth 2007; Toth et al. 2011).
At harvest and grading, rotting tubers must be removed rapidly from the harvester and grading machines before their disintegration and the spread of rotting tissue, as one rotting tuber is able to contaminate up to 100 kg of healthy tubers (Elphinstone and Pérombelon 1986; Pérombelon 2002). This precaution must be coupled with an adequate adjustment of the machines to avoid wounding of the progeny tubers that would facilitate their infection, as bacteria can survive after wound healing (Pérombelon 1992; van Vuurde and de Vries 1994). It is also recommended to harvest in dry conditions and at temperatures above 10 °C as cold temperatures increase the potential for potatoes to shatter bruise or for fissures to occur, and thus allow the entry of pathogens such as SRP (Olsen et al. 2012; Toth et al. 2011). Harvest must be initiated after a proper skin set of the progeny tubers, as Pectobacterium spp. are unable to breach healthy tuber periderms. A well-set skin is therefore the best defence against soft rot disease in storage (Charkowski 2015) and is also a good protection against wounding. It has been shown that thorough washing and disinfection of the machinery used for planting, spraying, haulm killing and grading reduce the risk of introducing the soft rot bacteria to healthy seed lots (Pérombelon 2002; Pérombelon and Kelman 1980).
6.3.6 Optimized Storage Conditions
To reduce disease development and spread in storage, damage to fresh produce must be minimized at harvest and during grading. Rotting tubers should be removed before storing and packing, with graders and sorters being disinfected regularly and good hygiene maintained in the store. Washing of seed tubers or potatoes for market should be avoided unless necessary. In such cases, disinfectant is added to the wash water, and the water replaced regularly (Charkowski 2015). Numerous physical, chemical and biological treatments have been evaluated for the control of soft rot and although some have shown potential, they are either costly or require additional research for optimisation (Elphinstone et al. 2018).
SRP enter tubers through lenticels, vascular tissue and wounds. Efficient wound healing and skin set will therefore reduce the potential number of entry points for bacteria. Optimal conditions for curing of potatoes vary with cultivar and SRP present, but according to Knowles et al. (1982) wound healing at 9 °C for about 25 days was optimal to reduce rotting without compromising the physiology of the tubers.
Potatoes should be stored in well ventilated conditions at 3–4 °C, as soft rot develops very slowly at temperatures below 10 °C (Kushalappa and Zulfiquar 2001; Wicks et al. 2007). Good storage facilities include both refrigeration and ventilation, with some refrigeration systems providing positive ventilation of the storeroom (Elphinstone et al. 2018). However, dead air pockets can still occur in storage facilities in which average temperature, relative humidity and ventilation are controlled. Such dead air pockets in piles or boxes can result in microclimates with increased temperature, thus causing condensation and lowered oxygen concentrations around tubers (Pringle and Robinson 1996) creating a favourable environment for the development of soft rot (De Boer and Kelman 1978). Proper control of temperature, relative humidity and oxygen concentration throughout storage facilities should lower tuber inoculum load and keep rotting to a minimum.
6.4 Physical and Chemical Treatments of Seed Tubers to Control Blackleg and Soft Rot
Seed tubers are the main route by which SRP infect potato plants to cause blackleg disease and tuber soft rot. Therefore, effective seed treatments may reduce seed decay, blackleg and aerial stem rot symptoms in the field and tuber soft rot in storage (Elphinstone and Pérombelon 1986).
Most of the available information on physical and chemical control of bacterial pathogens in potato comes from the control of Pectobacterium spp., whereas only limited information is available on the control of Dickeya spp., which has recently been reviewed (Czajkowski et al. 2011b). Physical and chemical treatments applied to seed tubers have focused on reducing SRP populations in latently infected tubers (Czajkowski et al. 2011b; Charkowski 2015). However, the inability of these treatments to fully kill the bacteria located deep in the vascular system of the tuber or in the lenticels, without negatively effecting the plant or tuber development, significantly limit their efficacy.
Physical seed treatments, such as hot water, steam, hot dry air and UV radiation are environmentally friendly and recognized as competitive to biological and chemical methods, as they may be effective against a broad range of pathogens and registration is not required (Czajkowski et al. 2011b). However, they may negatively influence tuber emergence and affect beneficial microorganisms. Hot water seed treatment for 5 min (at 55 °C) followed by drying under forced ventilation resulted in effective blackleg control obtained in field experiments (Pérombelon et al. 1989). The use of steam treatment as an alternative to hot water treatment reduced infection of tuber periderm from 26–59% to 1–3% (Afek and Orenstein 2002). In Israel, on a limited scale, steam treatments are used now in practice not only to reduce damage by SRP but also by other tuber-borne diseases (Tsror, Gilat, Israel, pers. comm.). Application of hot dry air at 50 °C, which dries the tubers and stimulates wound healing without interfering with tuber sprouting as much as hot water treatment, eliminated external populations of Pectobacterium spp. (Bartz and Kelman 1986). UV radiation was also reported as effective in eliminating superficial contamination of Pectobacterium spp. (Ranganna et al. 1997). Currently, these methods are not available for high throughput application and therefore are not implemented in practice (Czajkowski et al. 2011b; Charkowski 2015).
A wide range of chemical compounds has been tested to reduce infection by SRP on or inside tubers. Most compounds contain antibiotics (mainly streptomycin and its derivatives), inorganic and organic salts or combinations of these compounds (reviewed by Czajkowski et al. 2011b). However, antibiotics are not used in potato production because of the risks of introducing resistance to bacterial pathogens of humans or animals. As an alternative to antibiotics, a wide range of potential bactericides has been tested (Czajkowski et al. 2011b). Organic compounds such as hydroxyquinoline and 5‐nitro‐8‐hydroxyquinoline were effective for control of soft rot in wounded potato tubers (Harris 1979). Inorganic and organic salts, including aluminium acetate, sodium metabisulphate, propyl paraben, sodium benzoate, potassium sorbate, calcium propionate, sodium hypochloride, sodium bicarbonate, aluminium chloride and copper sulphate could inhibit the growth of P. carotovorum and P. atrosepticum in vitro (Mills and Hurta 2006). The ability of bacteriocides and sanitizers such as ethanol, sodium hypochlorite, copper sulphate, peracetic acid, hydrogen peroxide, benzoic acid, tri sodium phosphate and caffeine to reduce SRP concentrations was recently evaluated (Czajkowski et al. 2013). However, in greenhouse experiments, treatments with all disinfectants except hydrogen peroxide and caffeine resulted in high phytotoxicity, reducing sprouting of tubers by 10–100% (Czajkowski et al. 2013). Sodium hypochlorite and benzoic acid applied to inoculated tubers prevented development of soft rot symptoms on tubers under conditions conducive for soft rot (Czajkowski et al. 2013). Essential oils have been considered as an alternative to sustainable management of pests due to their recognized antimicrobial activity. Among the tested oils, essential oil of thyme, with thymol as the main constituent (57%), showed the highest antibacterial activity against P. carotovorum (Minimum Inhibitory Concentration = 0.2%), whereas, anise and white basil essential oils showed relatively weak activity (Rojas et al. 2014). Antibacterial activity of silver nanoparticles (AgNPs) stabilized by pectin (PEC) or sodium dodecyl sulfate (SDS) tested against SRP demonstrated bactericidal activity, with minimum inhibitory concentrations of 5.5 and 0.75–3 mg L−1, respectively (Dzimitrowicz et al. 2018). The application of these compounds for tuber treatments should be further investigated and evaluated as part of a blackleg and soft rot management strategy (Dzimitrowicz et al. 2018). SRP can infect the haulms of potato plants during the growing season. Foliar sprays with copper-containing compounds contribute to the control of bacterial stem rot by protecting wound sites from infection (Johnson et al. 2011) but are undesirable from an environmental point of view.
The potential of antimicrobial peptides from animal or plant origin for control of SRP has also been explored as an alternative to the use of antibiotics. González-Rodríguez et al. (2005) showed that the antimicrobial peptide melittin at relative low concentrations had an inhibitory effect against different strains of SRP, although D. chrysanthemi was moderately resistant. Another study assessed the antimicrobial activity of a material hybrid (HDL/BAM) that associated the ZnAl matrix with anions of ceftriaxone as a biologically active molecule (BAM). The matrix is capable of releasing BAM against P. carotovorum, a pathogen rarely responsible for blackleg disease but often for post-harvest losses. The matrix had no biocidal activity, but the hybrid material was bactericidal (Morales-Irigoyen et al. 2018).
To conclude, none of these treatments enable the eradication of SRP post infection. Nevertheless, application of these treatments may help to reduce the incidence of blackleg and may be used to avoid infections of plant materials by the SRP in a preventive way.
6.5 Biological Control of Pectobacterium and Dickeya spp.
The current European policy to reduce the use of synthetic chemical plant protection agents and simultaneously ensure consistent quality and quantity of crops creates a large demand for environmentally friendly bio-formulations and bio-products, such as microbial agents. Considering the on-going reinforcement of the integrated plant protection policy in Europe (Directive 2009/128/EC of the European Parliament and of the Council), the new strategies require alternative plant protection tools to chemical agents, such as natural compounds and microorganisms.
An alternative strategy for protecting plants during their growth, as well as under post-harvest storage conditions, might be through the application of a Biological Control Agent (BCA) (Jafra et al. 2009; Kastelein et al. 2018; Kloepper 1983; Krzyzanowska et al. 2012a), either alone or combined with physical and/or chemical treatments as part of so-called Integrated Pest Management (IPM). The activity of BCAs against SRP can result from different mechanisms: (i) the production of antimicrobial compounds (Bakker et al. 2002; Ongena et al. 2005; Krzyżanowska et al. 2016); (ii) interference in the quorum sensing (QS) mechanism (Czajkowski and Jafra 2009; Grandclément et al. 2016); (iii) supporting colonization of the niches occupied by SRP by competition for nutrients with saprophytic microorganisms (Compant et al. 2010); and/or (iv) activation of a natural plant defence system by induced systemic resistance (ISR) (Bakker et al. 2007; Ongena et al. 2007). As the current state-of-the-art for potential BCAs was described recently by (Czajkowski et al. 2011b), here we describe only the more recent advances in the field (since 2011).
6.5.1 Selection of BCA Strains
It is already well accepted that bacteria from the plant rhizosphere or plant endophytes may successfully protect plant tissues against SRP. The majority of this research was focused on the selection of strains inhibiting the growth of these pathogens via production of antimicrobial compounds, competition for nutrient and iron (Gerayeli et al. 2018; Krzyżanowska et al. 2016; Des Essarts et al. 2016) or by attenuation of the activity of the pathogen via interference with the QS mechanism (Czajkowski et al. 2011a; Barbey et al. 2013; Garge and Nerurkar 2017; Krzyzanowska et al. 2012b). These isolates were mainly classified to the genera Bacillus, Pseudomonas and Serratia (Beneduzi et al. 2012; Matilla and Krell 2018; Jafra et al. 2009; Ossowicki et al. 2017).
The ability to chelate iron highly enhances microbial competition in the plant environment (Expert et al. 1996), hence the producers of strong siderophores may also contribute to the plant tissue protection towards soft rot pathogens. Numerous bacterial strains have proved their antagonistic potential towards SRP in artificial growth media, as well as in plant tissues under laboratory conditions. However, few were tested under greenhouse/field conditions and none have been developed into a commercial product specifically for use against SRP, although tests are ongoing.
Frequently, the efficacy of a BCA is based on the expression of various mechanisms. For example, Serratia plymuthica strain A30 was selected as an antibiotic producer that inhibits the growth of D. solani (Czajkowski et al. 2012b) but it was also able to induce systemic resistance in tissue-culture grown potato plants, and by doing this also attenuated the growth of D. solani in planta (Czajkowski et al. 2015). Recently, Gerayeli et al. (2018) characterized several Bacillus spp., i.e. B. subtilis IrB2, B. pumilus IrB8, B. amyloliquefaciens IrB12, and B. thuringiensis IrB14, which showed antagonistic potential towards P. brasiliense. These strains were also able to induce a systemic response in potato tuber tissue and two of them, viz. B. subtilis IrB2 and B. thuringiensis IrB14, were able to interfere with the QS regulation of the pathogen. The latter is a common phenomenon in Bacillus spp. due to the ability of these bacteria to enzymatically degrade QS signal molecules (Dong et al. 2004; Krzyzanowska et al. 2012b; Garge and Nerurkar 2017). Another biological control agent Pseudomonas donghuensis P482 was found to produce a strong non-fluorescent siderophore, which might contribute to the antibacterial activity of this strain towards SRP as well as towards other plant pathogenic bacteria (Krzyżanowska et al. 2016).
6.5.2 Greenhouse and Field Experiments
Limited studies have been performed on the control of SRP using BCAs under greenhouse conditions (Czajkowski et al. 2012b; Des Essarts et al. 2016; Li et al. 2018), and there has only been one published field scale experiment (Tsuda et al. 2016). Czajkowski et al. (2012b) selected a set of antagonists against D. solani IPO2222. Firstly, potential antagonistic bacteria were isolated from the rotting potato tuber. In total 650 isolates were screened for antagonistic activity towards D. solani in an in vitro assay followed by a tissue protection test on potato tuber slices. Where possible, antagonistic isolates were phenotyped and their taxonomic classification determined. This strategy resulted in the selection of twelve isolates for greenhouse experiments to verify their effectiveness in protecting potato plants against D. solani. The first greenhouse trial resulted in the selection of four candidates for a second greenhouse experiment: Bacillus simplex A19, Serratia plymuthica A30, Obesumbacterium proteus S9 and Pseudomonas fulva S23. From these isolates, the endophyte S. plymuthica A30 proved to be efficient in blackleg disease control in greenhouse experiments under disease-inducing conditions. S. plymuthica A30 produces antibiotics, biosurfactants and plant growth promoting auxins. Due to its motility and capacity to colonize, it protected potato plants by reducing blackleg symptoms caused by D. solani by 100% and colonization of the stems by 97%. A subsequent post-harvest treatment of seed tubers with A30 resulted in a reduction of soft rot during storage, as well as reduced blackleg in the following growing season (Hadizadeh et al. 2019). Various isolates of Serratia plymuthica have already shown antagonistic capacity towards fungal pathogens, with strain S. plymuthica HRO-C48 included in the commercial biocontrol product Rhizostar® (EU Patent 98,124,694.5) developed against Verticillum wilt.
Another study on the isolation, screening and selection of antagonistic bacteria towards strains of Dickeya and Pectobacterium spp. was performed by Des Essarts et al. (2016). More than 10, 000 bacteria originating from rhizosphere soils, asymptomatic potato tuber tissue and blackleg and soft rot diseased potato tissue were successively screened. In the first screening more than 240 isolates were selected as capable of inhibiting growth of D. dianthicola and P. atrosepticum. Subsequent screenings resulted in selection of six isolates, which showed the highest protection of potato tissue after infection by pathogens. The isolates classified as Bacillus simplex BA2H3 and Pseudomonas brassicacearum PA1G7 and PP1-210F were effective towards P. atrosepticum induced symptoms, while Pseudomonas fluorescens PA3G8 and PA4C2 and P. putida PA14H7 were highly antagonistic towards D. dianthicola spp. The last three strains were further tested in four independent greenhouse experiments to establish their potential for protecting potato plants artificially infected with D. dianthicola RNS04.9. The level of reduction varied per location (Brittany or Nord-Pas-de-Calais) and per experiment, but the best reduction of disease symptoms and transmission of the pathogens to progeny tubers was observed when the three strains were applied together in the mixture. In silico analysis of the genome sequences of the P. fluorescens PA3G8 and PA4C2 and P. putida PA14H7 strains revealed the presence of genes encoding biosynthesis of bacteriocins, adhesins important for biofilm formation, as well as different types of siderophores. All these potential features may be involved in antagonistic activity by the selected strains.
6.5.3 Bacteriophages
The idea of using lytic bacteriophages (phages) to control plant pathogenic bacteria was introduced as early as in 1920s (Mallmann and Hemstreet 1924), less than ten years after phages were discovered and described for the first time. In 1925, it was demonstrated that lytic viruses were able to provide protection against P. atrosepticum inoculated into potato tuber tissue (Coons and Kotila 1925). Between 1980 and 2010s, several proof-of-principle experiments were carried out to test whether lytic phages could be used against different SRP and in several different scenarios (Balogh et al. 2010; Czajkowski et al. 2014; Eayre et al. 1995). Most of these studies were, however, restricted to laboratory experiments and only in a few cased was the usefulness under field conditions tested. In a field experiment in Belgium, tuber treatment resulted in a slight yield increase but not in a significant reduction of the percentage of infected progeny tubers (Adriaenssens et al. 2012). Currently, it has not yet been agreed how to apply SRP phages for effective control of blackleg in the field. However, for control of soft rot in the potato packing industry, the commercial product Biolyse® is available from APS Biocontrol Ltd. in Scotland, UK (https://www.apsbiocontrol.com/).
6.5.4 Conclusions and Perspectives
The number of publications presenting new potential biocontrol strains against SRP is growing. However, there is still the need to move laboratory, glasshouse and limited field studies into commercial products that can effectively protect plants against diseases caused by SRP. So far, the only commercial biocontrol product based on a non-pathogenic strain of P. carotovorum has been developed in Japan for protection of vegetable, cyclamen and potato tuber against soft rot disease. It is available on the market as BIOKEEPER® (Central Glass Co., Ltd., Tokyo, Japan).
It is expected that using a mixture of antagonists that have different modes of action will increase the potential of BCA for plant protection compared to the use of individual species. Antagonistic strains in a mixture may also interact with each other, possibly resulting in an increased synthesis of compounds involved in the control of the pathogens (Des Essarts et al. 2016; Tyc et al. 2014).
6.6 Breeding Potato for Resistance
Information on breeding of potato for resistance has been summarized and extensively reviewed previously (Czajkowski et al. 2011b; Lebecka 2017). In this chapter, therefore, we focus on information not previously discussed, although overlap is unavoidable for a more comprehensive overview. Consecutively, the susceptibility of cultivars to SRP, bioassays to test for resistance, attempts to breed for resistance, mechanisms of resistance and the biotechnology approach will be examined.
6.6.1 Susceptibility in Commercial Cultivars
Modern potato varieties have a narrow genetic base and are mainly derived from the Chilean Solanum tuberosum Group (Gp) Tuberosum and with contributions from Gp Andigena (Pavek and Corsini 2001). This may have resulted in lack of immunity against SRP in commercial cultivars, although they largely vary in their susceptibility.
In field studies in Switzerland in 2014, in which twenty commercial cultivars were tested, large differences were observed in their susceptibility against blackleg symptoms (Dupuis, Agroscope, Switzerland, unpublished results). Tubers were submerged in a suspension of D. dianthicola before planting and scored for the development of blackleg. The cultivars with the lowest disease incidences were Markies (0.5%), Panda (1.5%) and Desiree (2%) and with the highest incidences were Agria (23%), Kondor (24%) and Agata (30%).
There is also a considerable variation in the susceptibility of potato varieties for tuber soft rot (Chung et al. 2013; Pasco et al. 2006; Tzeng et al. 1990). In France, in total 93 cultivars developed between 1935 and 1987, and 157 cultivars developed between 1987 and 1997 were tested (Pasco et al. 2006). A wide variation in mean rot volumes was found six days after inoculation of cut tubers. Studies in the USA also showed significant differences in the susceptibility of soft rot for 14 cultivars grown on a loamy sandy soil or a silt loam and assayed by subsequent inoculation of tubers with P. atrosepticum and incubation in a mist chamber (Tzeng et al. 1990). The ranking of resistance was similar for both soils. Susceptibility was correlated with a combination of Ca content and dry matter in the tubers. In other studies in the USA, 65 potato clones cultivated in the same field were tested for tuber maceration by P. carotovorum directly after harvest and at two-month intervals (Chung et al. 2013). During six-month of storage, significant differences in susceptibility were found between clones. The cultivars Freedom Russet, Anett and Alaska Red Eye were most resistant. The susceptibility for soft rot did not change during the 6 months of storage.
6.6.2 Testing for Resistance
To test for blackleg resistance, inoculation of seed tubers by vacuum-infiltration and scoring for disease development is preferred, as it mimics the natural way of tuber infection (Allefs et al. 1995). This way of testing, however, is costly in terms of time and space and is only applicable in an advanced stage of selection. Other testing protocols, including testing for tissue maceration after inoculation of tubers, stems or etiolated sprouts do not correlate well with susceptibility for blackleg (Allefs et al. 1996), although it may correlate with susceptibility for soft rot during storage. Recently, a cost-effective system was developed to quantify blackleg symptoms on the shoots of in vitro potato plants (Burra et al. 2015) and good consistency in infection between in vitro-based screening and existing greenhouse assays was found.
There remains a need for cost-effective, high throughput bioassays that can predict field resistance against diseases caused by SRP. The assays would need to test for multiple features of a potato plant that may limit introduction, colonization, population growth of the pathogen, as well as symptom development. This may be a single assay, such as the field test with vacuum-infiltrated seed tubers but also multiple ones testing for introductions via tubers, roots or/and haulms, resistance against tuber soft rot, transmission from seed to stem, for stem soft rot, haulm infections and transmission from stem to stolon and progeny tubers.
6.6.3 Breeding for Resistance
Breeding for resistance is hampered by the (quantitative) polygenic nature of resistance against SRP (Zimnoch Guzowska et al. 2000), the absence of an adequate technique to test for resistance, and possibly by the limited genetic diversity in the material used in breeding programs (Tzeng et al. 1990). Moreover, the susceptibility, expressed as the disease prevalence, is dependent on the aggressiveness of the bacterial strain tested, the physiology of the plant material, e.g. tuber size and maturity (Marquez-Villavicencio et al. 2011), and by various environmental factors including evapotranspiration and soil moisture (Gill et al. 2014). Unfortunately, results from tests in breeding programs with a released cultivar often do not coincide with the blackleg incidences found in practice (Kooman, NAK, Emmeloord, NL, pers. comm.). In addition, resistance for blackleg and for tuber soft rot are often not correlated (Pérombelon and Salmond 1995).
Breeding for resistance is also slow because commercial cultivars are tetraploids (Jansky 2000). Breeding strategies and bioassays need to be further developed to utilize the gene pool effectively for the generation of blackleg resistance cultivars. Nevertheless, resistance of wild relatives of potato with a high level of tuber and foliar resistance to P. atrosepticum has been introduced into a S. tuberosum line by inter-crossings with Solanum chacoense and S. yungasense (Zimnoch Guzowska et al. 2000). The F1 hybrid population was used to locate quantitative trait loci for resistance, which allowed complex inheritance of pathogen resistance to be studied. QTLs for tuber resistance and leaf resistance were located on 10 different chromosomes, although the contributions of the QTLs to leaf resistance were not well reproducible.
Similarly, resistance against tuber soft rot caused by P. atrosepticum was derived in 35% of the progeny of 4x–2x crosses between tetraploid potato lines and diploid hybrids having genetic material in their origin from S. tuberosum, S. chacoense, S. yungasese, S. phureja, S. gourlayi and S. demissum (Lebecka et al. 2005). From the 1425 tetraploid clones, 11% showed a good tuber appearance, yield and weight.
A molecular marker-assisted introgression was also successfully used to introduce resistance present in the tuber bearing S. commersonii against P. carotovorum into the cultivated S. tuberosum gene pool (Barone et al. 2001). S. commersonii is an interesting species as it also carries several useful traits including resistance to abiotic stresses, bacterial wilt, Potato Virus Y and a high capacity for cold acclimation. The interspecific barriers between the two species were overcome using a breeding scheme involving ploidy and Endosperm Balance Number manipulations (EBN). Back crossings (BC) with cultivated S. tuberosum resulted in a mean value of S. commersonii-specific RAPD or AFLP markers of ca. 92% in BC1, 75% in BC2 and 38% in BC3. Five resistant genotypes were found in the BC3, which largely resembled the S. tuberosum type, including a relatively low level of glycoalkaloids (Carputo et al. 2003).
Using a leaf petiole test, stem rot resistance was found against P. atrosepticum in a high percentage of the accessions of S. boliviense (31%), S. chacoense (50%), S. sancta-rosae (67%), whereas most accessions of S. canasense, S. tarijense and S. spegazzinii were susceptible (Bains Piara et al. 1999). A petiole assay was also used to test 532 genotypes from 340 accessions comprising most known potato species, for tolerance against P. parmentieri, P. carotovorum and D. solani (Rietman et al. 2014). Under stringent test conditions, four genotypes belonging to Yungasensa subclades, including S. chacoense, were considered tolerant against Pectobacterium spp., from which only one was also tolerant against D. solani. Most of the tested species are diploids, which facilitate the generation of introgressions with S. tuberosum. The authors found an association between the susceptibility of a genotype against SRP and its origin. In particular, genotypes from a geographic region with a high soil humidity seem to be less susceptible. This contradicts information previously published by Spooner et al. (2009) who, in an evaluation of literature data, did not find an association between susceptibility of germplasm for blackleg causing agents and host taxonomy or climatic variables.
6.6.4 Resistance Mechanisms
Resistance to SRP has been found to correlate with the degree of methyl esterification of pectin present in the cell wall and was expressed even under anaerobic conditions (McMillan et al. 1993). Clones derived from a somatic fusion between S. brevidens, a non-tuber producing genotype with a high degree of pectin esterification, and S. tuberosum subsp. tuberosum were backcrossed with commercial cultivars resulting in a progeny segregated into resistant clones with a high level of methylation and susceptible clones with a low level of methylation (Pérombelon 1992). A high methyl esterification, however, negatively affects the cooked potato tuber texture, which may have affected the application of resistance based on this trait in practice (Stewart et al. 2010).
Various other traits were identified which determine the susceptibility of potato for SRP. A correlation was identified between susceptibility of tuber soft rot for 18 tested cultivars and the activity of polyphenol oxidase (PPO), peroxidase (POD), phenylalanine ammonia lyase (PAL), chlorogenic acid and total soluble phenols 8 h after cutting of tubers (Ngadze et al. 2011). The results may be used in selection programs for tolerant cultivars, while the identification of the genetic basis may allow the selection of genetic markers. In other research, tolerance to blackleg has also been found to be associated with the jasmonic (JA) and salicylic pathways (SA) (Burra et al. 2015). JA insensitive and SA deficient transgenic lines were more susceptible to blackleg than the non-transgenic control plants. It was further shown that a JA marker (lipoxygenase) and a SA (PR1) marker were induced in potato plants infected with D. solani (see Sect. 4.3.3).
The level of resistance in commercial cultivars may be strengthened using somaclonal variation or using resistance. Somaclonal variants of Russet Burbank variety, initially generated against Streptomyces spp. causing common scab, were tested for their resistance against the tuber soft rot pathogens P. atrosepticum and P. carotovorum (Thangavel et al. 2014). Some clones displayed a significant decrease in disease severity (percentage of rotted tissue) compared to the parental line, indicating that somaclonal variation may contribute to tuber resistance.
6.6.5 Biotechnology Approaches
The availability of plant genome sequences and efficient transformation systems have largely supported the generation of transgenic lines. Most plants engineered for resistance against SRP are transformed with antimicrobial peptides and proteins but there are also examples of transgenic plants producing enzymes inducing a resistance response, quenching the signal transduction of bacteria or increasing the level of antimicrobial metabolites.
6.6.5.1 Antimicrobial Peptides
Full resistance in potato against P. atrosepticum was derived in transgenic potato plants overexpressing the potato gibberellin Stimulated-Like 2 (GLS2), an antimicrobial peptide (Mohan et al. 2013). In glasshouse experiments, transgenic plants overexpressing the peptide showed no symptom development, whereas in the non-transgenic lines 93% of the plants displayed blackleg symptoms. Similarly, the expression of magainin, an antimicrobial peptide originally identified from the clawed frog Xenopus laevis, in potato plants resulted in an increased level of soft rot tuber resistance. Magainin interacts with the lipid A of the bacterial cell membrane resulting in the septic shock syndrome (Fukuoka et al. 2008). In three consecutive experiments, progeny tubers harvested from transgenic plants displayed a lower susceptibility for soft rot caused by P. atrosepticum (Barrell and Conner 2009). Transgenic potato plants expressing high levels of attacin or cecropin, antimicrobial peptides found in the cecropia moth, exhibited an increased resistance against SRP compared with the untransformed control. Resistance was revealed by a reduced severity of blackleg or soft rot symptoms (Arce et al. 1999). Transgenic potato plants have also been generated by stacking antimicrobial genes (Rivero et al. 2012). Plants were transformed with genes encoding (i) osmotin, a stress responsive antifungal protein from tobacco, belonging to the pathogenesis-related (PR)-5 family, (ii) dermaseptins, belonging to a superfamily of antimicrobial host defense peptides that are made in the skin of Hylidae frogs and (iii) a lysozyme from the red junglefowl. In particular, the expression of dermaseptin and lysozyme contributed to the resistance of plants against P. carotovorum. Stacking of the genes also resulted in resistance against Streptomyces scabies, Phytophthora infestans, Rhizoctonia solani and Fusarium solani.
6.6.5.2 Quorum Quenching
Another approach to introduce resistance is by interfering with the quorum sensing mechanism of SRP. Pectobacterium spp. sense their population density using a communication system based on signal molecules called acyl-homoserine lactones (AHLs) and receptor proteins that sense the concentration of AHLs in the environment. This communication system is vital for the expression of virulence factors, including the production of cell-wall degrading enzymes but can be disrupted using enzymes called lactonases that break down these signalling molecules (Mahmoudi et al. 2013; Dong Yi et al. 2000; Toth et al. 2004). Tobacco plants expressing a lactonase from Bacillus sp. were found to hydrolyse AHLs and enhance resistance to P. carotovorum (Dong Yi et al. 2001). For Dickeya spp., AHLs do not seem to play a pivotal role in the cell-dependent control of virulence genes (Nasser et al. 1998; Mehdbi-Hajri et al. 2011) but are instead under the regulation of the Vfm quorum sensing system (Nasser et al. 2013). Consequently, plants expressing lactonases may not be resistant against Dickeya spp.
As far as is known, none of the plants produced biotechnologically plants have been tested under anaerobic conditions, which will impair the resistance mechanism of the plant. Due to public concern on human health and environmental risks, so far only a limited number of transgenic potato lines have been released for commercialization (Hameed et al. 2018) but none with a resistance against SRP.
6.6.5.3 Production of Cell Wall Degrading Enzymes
Engineered potato plants expressing pectate lyases strongly induced the transcription of the plant defence related gene that encodes phenylalanine ammonia-lyase (PAL) via the degradation of unsaturated oligogalacturonates, resulting in resistance to infection by P. carotovorum (Wegener 2002, Wegener et al. 1996).
6.6.5.4 Other Compounds
Increased resistance to tuber soft rot caused by P. carotovorum was found after increasing the level of anthocyanin 5-O-glucosyltransferase (5-UGT) in potato tubers (Lorenc-Kukuła et al. 2005). In these tubers a significant increase in anthocyan compounds and starch, and a decrease in sugar content, was found. It remains unclear which of these changes was responsible for the decreased susceptibility to the pathogen.
6.6.5.5 New Breeding Technologies
New breeding technologies, such as transcription activator-like effector nucleases (TALENs) and clustered regularly interspaced palindromic repeats/CRISPR-associated 9 (CRISPR/Cas9), are being used to generate potato lines with resistance to potato pathogens in a more targeted approach (Hameed et al. 2018). CRISPR/Cas9 has been used to engineering resistance against plant pathogenic bacteria in other crops (Jia et al. 2017) and the expectations are high. Nevertheless, the commercial success will largely depend on the public and government acceptance of crops derived in this way. Possibly a cisgenic approach, which involves the genetic modification of a recipient plant with a natural gene from a crossable sexually compatible plant, rather than a transgenic approach, used in the early days of biotechnology, may be helpful to overcome objections against the use of such crops (Schouten et al. 2006).
6.6.6 Concluding Remarks
Although resistance in wild Solanum spp. have been found, no genes have so far been identified that are useful to confer resistance in commercial potato varieties against SRP. Nevertheless, the increasing availability of genome data, in combination with new breeding technologies such as TALENs and CRISPR/CAS 9, may lead us to a break-through.
Another new development that may support the management of blackleg and soft rot diseases is the use of true potato seed (TPS), collected from the berries of potato plants. To produce TPS, homozygous parental diploid lines are crossed to obtain F1 hybrid cultivars, from which the true seeds are harvested (Lindhout et al. 2011). Using TPS, the risks for tuber-borne diseases, including bacterial and viral diseases, are largely avoided. TPS are small compared with tubers thus reducing costs of and negative impact on quality during transportation. TPS are particularly important for farmers in countries with a high temperature and limited cooling facilities in storage, as the TPS require considerably less storage space and are much less likely to develop diseases. However, true seeds demand a higher temperature to establish seed and potato production requires a longer growing season. Till recently, TPS technology resulted in genotypes with a lack of seedling vigour and a lack of uniform stand of the seedlings but the quality is improving rapidly. The first TPS cultivar (Oliver F1) was introduced commercially in 2019 by Bejo Seeds but more companies are now developing TPS cultivars.
6.7 Disease Management in Other Crops
SRP cause economically important losses in crops other than potato, including several vegetables and ornamentals (see Table 3.1). Since the economic losses caused by SRP in these crops is less than in potato, disease management is less well developed. However, due to severe outbreaks between 1990 and 2000, disease management strategies were developed for chicory and ornamentals. For example, losses caused by these bacteria in the Netherlands were fivefold higher in 2007 than in 2002, reaching 15 million euro for bulb flowers and up to 50% losses (with 90% of infected roots) in chicory production (Le Hingrat et al. 2012).
6.7.1 Chicory
In addition to Pseudomonas spp., the causal agents of soft rot in witloof chicory (Cichorium intybus) have been identified as both Pectobacterium and Dickeya spp. (Bouvard 1987; Vantomme et al. 1989; Le Guern et al. 1992; Samson et al. 2005; see Table 3.1).
Soft rot symptoms may occur during the three phases of production: open field root growth, root storage and forcing of the white head from mature roots. In the field, soft rot is only rarely observed, which seldom hinders root harvest (Bouvard 1987). The more critical phase for soft rot development is during head forcing, which has become a more significant problem since the introduction of hydroponic systems for this stage of the process, which uses circulating nutrient solutions. In these systems, losses of 50% or more total production regularly occur when susceptible cultivars were used (Vantomme et al. 1989; Le Guern et al. 1992).
Disease management may be applied either during root growth in the field or during chicory head forcing. In the field, controlling nitrogen fertilization may help to lower chicory head soft rot incidence. Indeed, an high nitrogen content in roots enhances chicory head susceptibility to soft rot caused by SRP, and nitrogen provided during root production in the field is positively correlated with the amount of the nitrogen content in the roots (Schöber and Vermeulen 1999). Breeding programs have included selection for soft rot tolerance, and current chicory varieties harbour a large range of tolerance to soft rot (Schöber and Vermeulen 1999). Such tolerance is often linked to nitrogen metabolism and the effect of nitrogen fertilisation varies from one variety to another. Some varieties remain tolerant whatever the nitrogen status, while others become more susceptible to soft rot in high nitrogen conditions (Laville and Benigni 1997).
A good prophylactic measure also consists of minimizing physical injuries to roots, e.g. by root harvesting when the soil is not too dry, to limit wounding that may constitute entry sites for the bacteria. As in potato, treatments with copper or calcium also provide some protection against soft rot during forcing. Both products may be applied during pulverisation of root crowns before forcing (removing mature roots to a warm, dark place in order to coax them into rapid and early growth). Copper derivatives may also be supplied a few days before root harvesting in the field, while calcium may be provided by root immersion in a calcium chloride solution just after root harvest (Schöber and Vermeulen 1999). During forcing, only physical treatments for disease management have been proposed, such as reducing the incubation temperature to 17–19 °C or decontaminating the nutrient solution used in hydroponic cultures with UV light (Bouvard 1987; Marc Benigni, Association des Producteurs d’Endives, France, pers. comm.).
6.7.2 Chinese Cabbage
Bacterial soft rot is one of the most destructive diseases in Chinese cabbage (Brassica rapa (syn. campestris) subsp. pekinensis) (Ren et al. 2001). As with potato, chicory and other crops, disease expression is strongly favoured by a high temperature and humidity. Disease management is based on crop rotation, hygiene and cultivation measures including the use of raised beds, optimized sowing date (Fritz and Honma 1987) and the use of less susceptible cultivars (Ren et al. 2001). Studies showed that tolerance to soft rot can be conferred in Chinese cabbage by expression of N-acyl-homoserine lactonase (AHL-lactonase) via transformation of plants with the aii gene (AHL-lactonase gene from Bacillus sp. GH02) fused to the PinII signal peptide, protease inhibitor II from potato (Vanjildorj et al. 2009). Similarly, a reduced susceptibility was found after transformation with a gene (BAA1) encoding bromelain, a proteolytic enzyme from pineapple trees (Jung et al. 2008). Finally, transformation of plants with a gene encoding the rice leucine-rich repeat protein (OsLRP) conferred resistance to soft rot in Chinese cabbage (Park et al. 2012).
For the biocontrol of P. carotovorum in Chinese cabbage, Lactic Acid Bacteria (LAB) were selected from Japanese traditional fermented foods (Tsuda et al. 2016). Interestingly, LAB isolates produce bacteriocins but they may also influence the microenvironment of infection due to the production of organic acid and hydrogen peroxide and decrease in pH that, in turn, can have an effect on the pathogen’s growth and development. More than 1160 isolates of LAB were screened in a leaf disk assay. Further analysis led to selection of isolates SHH15 and SOK04 for further field experiments. The effectiveness of these two isolates was compared in field trials with a non-pathogenic strain of P. carotovorum, re-isolated from the commercial product BIOKEEPER®. The isolate SOK04 significantly reduced disease symptoms on Chinese cabbage and was even more effective than the non-pathogenic P. carotovorum strain. A further study revealed that SOK04 is a mixture of two different isolates presented by big yellow colonies (BY) and small white (SW) colonies. Both type-isolates were tested in field experiments carried out independently in two seasons. BY, characterized as Lactobacillus plantarum, was effective in all field trials. BY could only establish a stable population on wounded leaves and could not persist on the healthy ones. It prevented pathogen colonization of the damaged plant or their penetration into vascular tissues. LABs are considered as BCA with a high potential for development into commercial products. They are associated with fermented foods and generally recognized as safe, with many of them being considered as probiotics and may be well accepted by the consumers.
6.7.3 Soft Rot in Ornamental Horticulture
The annual global value of the flower bulb industry exceeds a billion US$ without orchids (Benschop et al. 2010). However, it is difficult to provide the economic figures for soft rot losses in this industry because of its diverse nature and lack of data. For example, the bulb industry includes more than 800 different genera (De Hertogh et al. 2013) but is dominated by about 10 genera with thousands of cultivars, many of which have been reported as hosts for Pectobacterium or Dickeya spp. (Byther and Chastagner 1993; Van Doorn et al. 2011). For some hosts, the difference in susceptibility between cultivars has been studied in detail, e.g. the white flower Zantedeschia aethiopica cultivar is more resistant to soft rot than coloured species (Snijder and van Tuyl 2002). Environmental conditions largely influence the occurrence of soft rot in ornamental plants. For example, disease in Zantedeschia spp. caused by P. carotovorum is most severe when plants are under stress from low soil aeration, high temperature or high humidity (Funnell and Mackay 1999; Wright and Burge 2000; Luzzatto et al. 2007).
The last group of ornamental hosts impacted by soft rot are orchids. The most popular are Cattleya, Cymbidium, Dendrobium, Oncidium and Phalaenopsis, with hundreds of hybrids in trade and the largest markets worldwide. Orchids are consistently ranked among the best sellers in the global potted plant trade and comprise 10% of all fresh cut flowers traded internationally. Exports of potted orchids from the Netherlands alone were valued at ca. 500 M euro in 2015 (Hinsley et al. 2018). Production is expanding rapidly in Asia, mainly in Thailand and China but also in Eastern Europe, with exports directed to the European market, United States and Japan (Hinsley et al. 2018). This industry is particularly sensitive to bacterial diseases as production costs are relatively high and growth conditions are extremely conducive to bacterial spread. Several reports on soft rot infections in orchids are found in the literature (Cating et al. 2008; Cating and Palmateer 2011; Cating et al. 2009). Most losses in orchids are caused by Dickeya spp., although infections with Pectobacterium spp. have also been reported (Charkowski 2018; Dahaghin and Shams-Bakhsh 2014; Alic et al. 2015; Cating and Palmateer 2011; Table 3.1).
The globalization of the flower industry, with its expansion to Latin America, Africa and Asia, and with increasing exports to Europe, United States, Canada and Japan have assisted dissemination of soft rot pathogens, e.g. D. solani and P. brasiliense on potato in Europe (see Chap. 8), supported by the latent nature of the pathogen in plant propagation material (Charkowski 2018). The large number of crops and worldwide transportation and trade make this industry extremely vulnerable to the spread of bacterial pathogens. Climate change and global warming support this trend and allow strains from warm climate countries to invade and proliferate in more temperate zones. Such outbreaks are largely dependent on the transfer and quality of the propagation material, the environmental conditions (temperature and humidity), growing conditions (soil, substrates, nutrition), irrigation systems and the presence of vectors such as insects and human. Semi-controlled environments such as greenhouses and covered tunnels, which are common to cultivation of ornamental plants, allow growers to have better control of the climate conditions (temperature, hail and precipitation) but also provide favourable conditions for infection. Accordingly, control measures include strict sanitation procedures, starting with clean and healthy plant material, achieved by sorting out poor quality or disease suspected material (Chastagner et al. 2013; Czajkowski et al. 2011b).
Such management proved to be highly efficient in the case of carnation (Dianthus) bacterial stunt disease caused by D. dianthicola. D. dianthicola was first detected in carnation in 1956 and more than 25% of mother stock plants were reported to be affected (Hellmers 1958). Severe outbreaks continued in the 1960s and 1970s leading to the classification of D. dianthicola as a quarantine pest in carnation. Certification schemes and very strict hygienic and sanitation measures where implemented, including the use of pathogen-free in vitro plants as starting material for cuttings propagation, steam sterilisation to disinfect growth substrates and surfaces, disinfection of tools and use of sterilized or filtered water for irrigation, growth on elevated benches to reduce the risk of water logging, and use of insect-proof contained areas in glasshouses. Furthermore, in field production, machines and materials used in carnation production rarely now come into contact with other crops considered as important hosts of D. dianthicola, e.g. potato and dahlia. The implementation of a certification scheme together with these strict sanitation procedures used in the production of planting material, have been very effective in controlling D. dianthicola, resulting in little damage being recorded in recent years (EFSA 2013a, b) and leading to the dropping of the quarantine status for D. dianthicola. This method is now also the mainstay of SRP control in other horticultural (ornamental) crops (Altman and Loberant 1997).
Unfortunately, diagnosis and detection of SRP are not yet applied on a wide scale in the flower bulb industry, mostly due to cost considerations. When cost effective, growers prefer in vitro tissue culture produced plantlets in order to start with pathogen-free propagation material. Keeping the sanitation of the packing house during processing of bulbs, control of storage conditions (including temperature, humidity and aeration) at all phases, and temperature-controlled transportation, may all help to prevent contamination and disease outbreak. Soil or growing media sanitation is also an important factor, especially in greenhouses where soil-free mixtures can be easily treated by steam-pasteurization, chemicals or soil solarization (Chastagner et al. 2013). Growth conditions could be further optimized to limit soft rot disease, mainly through reducing humidity by limiting irrigation, increasing aeration, improving soil drainage and by optimizing plant nutrition with an emphasis on calcium fertilization. Only mature bulbs should be harvested and wounds and contaminations should be avoided during harvest and transport. Inspections for and control of soft rot diseases should also be carried out to avoid transmission of the bacteria and secondary infection of injured plants.
The potential of biocontrol agents (BCA) was explored to control soft rot in ornamental calla lily plants caused by P. carotovorum (Li et al. 2018). In this study, bacteria from Myxococcus spp. were selected as a potential BCA. Myxococcus spp. are saprophytic bacteria that grow on dead organic matter and exhibit multicellular swarming behavior called “wolf-pack”, which facilitates predatory feeding on other microorganisms. This feature prompted researchers to screen isolates of myxobacteria from soil collected in different regions of China. From 12 isolates obtained, the one that showed the greatest swarming capacity, classified as Myxococcus sp. strain BS, was selected for pot experiments. Myxococcus spp. can produce antimicrobials, although the most important mechanism of antagonism in strain BS against P. carotovorum was found to be a direct cell-to-cell contact and predatory behaviour of the BS strain. The BS strain significantly reduced the soft rot incidence when applied together with P. carotovorum to soil and showed growth promotion in potato plants as it was able to increase the number of progeny tubers.
In ornamentals, resistance against SRP was found after introducing genes that expressed antimicrobial peptides into plants. Phalaenopsis plants displayed resistance against P. carotovorum after introduction of the wasabi defensin gene (Sjahril et al. 2006). Ornithogalum, which express the antimicrobial peptide tachyplesin I of the Asian horseshoe crab in transgenic lines showed resistance to Pectobacterium infections (Lipsky et al. 2016).
Overall, however, in a similar way to other agricultural systems, scientific advances that have been made in the laboratory and experimental systems have not yet been translated into available products in ornamental horticulture to prevent disease (Chastagner et al. 2013). Nonetheless, implementation and dissemination of integrated pest management practices and the importance of cultural management help the bulb growers to improve and manage soft rot bacteria.
6.7.4 Concluding Remarks
Due to the broad host range of several SRP spp., infections in chicory and ornamentals may have implications for potato production and vice versa. Indeed, isolates of Dickeya spp. from potato plants with blackleg disease can macerate chicory heads and, even if symptoms in chicory are rare in the field, chicory might be a reservoir for SRP that subsequently affect potato. This is particularly important because, in certain regions, chicory is part of the same crop rotation programs used for potato cultivation. Some farms produce both potato and flowers and it was hypothesized that outbreaks of blackleg on potato in the 2000s was caused by a strain of D. solani that originated from greenhouse-grown ornamentals (Sławiak et al. 2009).
6.8 Final Conclusions
After years of research, the set of tools available for the management of SRP and the diseases they cause is still limited, mostly comprising tools that have been available for many years. During potato cropping hygiene, the use of (certified) pathogen free starting material, crop rotation, the use of cultivars less susceptible for SRP, the avoidance of water logging and the avoidance of crop damage are among these tools. Harvesting under dry weather conditions plays a key role in management of both blackleg and soft rot diseases, preferably when mother tubers are no longer present. If possible, rotten tubers should be removed from machines and tuber wounding avoided. Drying of harvested tubers and storage in well-ventilated rooms at low temperatures are essential to avoid multiplication of SRP and tuber decay. Crop growth under contained conditions will also help to avoid the introduction of SRP, including new variants present in wider agricultural ecosystems. For management of soft rot diseases in crops that are grown in contained facilities, the control of environmental conditions (particularly temperature and humidity) and optimization of nutrition are key elements in the management of SRP.
Major breakthroughs in the fight against SRP related diseases are not expected in the short term. Nevertheless, there are new management tools, strategies and germplasm being developed and tested. New breeding techniques may allow the introduction of resistance genes in commercial cultivars, while, although the use of true potato seed is still in its infancy, it is expected to become a powerful tool in eliminating disease problems in the future. Biocontrol agents are also in development although, while laboratory studies have been successful, in-field applications need to be improved. We may also see the increased use of beneficial microbes in the form of bio-inoculants. The availability of reliable and sensitive methods that can act on all relevant SRP variants remains an important consideration in the development and evaluation of new management tools.
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van der Wolf, J.M. et al. (2021). Management of Diseases Caused by Pectobacterium and Dickeya Species. In: Van Gijsegem, F., van der Wolf, J.M., Toth, I.K. (eds) Plant Diseases Caused by Dickeya and Pectobacterium Species. Springer, Cham. https://doi.org/10.1007/978-3-030-61459-1_6
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