Survey of Candidatus Liberibacter Solanacearum and Its Associated Vectors in Potato Crop in Spain

Simple Summary Zebra chip disease (ZC) in potato is an economically important disorder, documented in North and Central America and New Zealand. It is associated with the bacterium ‘Candidatus Liberibacter solanacearum’ (CaLsol), which is transmitted by the psyllid Bactericera cockerelli. The characteristic symptom of ZC is a dark and light striped pattern in chips, making them commercially unacceptable. Naturally CaLsol-infected potato tubers were reported in Europe, where the threat of ZC for European potato crops is a major concern. This work studied the presence and abundance of ZC symptoms and CaLsol in potato plants, as well as those psyllid species that eventually could transmit the bacterium, in the main producing areas in Spain. Very few symptomatic and CaLsol-positive plants were detected in Mainland Spain, and any positive plant was detected in the Canary Islands. Most of the adult psyllids captured were identified as Bactericera nigricornis, and some of them as Bactericera trigonica, but no B. cockerelli was detected. B. nigricornis was found widely distributed in the northern half of the Iberian Peninsula, and it was the only one able to feed and reproduce on potato plants. However, this psyllid does not seem sufficient to pose a threat to potato production, due to the scarce number of specimens and because the frequency of B. nigricornis specimens that were CaLsol+ was very low. Abstract ‘Candidatus Liberibacter solanacearum’ (CaLsol), the etiological agent of potato zebra chip (ZC), is transmitted to potato plants by the psyllid Bactericera cockerelli (Šulc, 1909) in North and Central America and New Zealand. The risk of the dispersion of ZC in Spain depends on the presence of an efficient vector. This work studies the presence and abundance of ZC symptoms and CaLsol in potato plants, as well as the presence and abundance of psyllid species associated with potato crops in the main producing areas in Spain. Eighty-eight plots were surveyed punctually to detect ZC symptoms and psyllid species in the main potato-producing areas. Furthermore, fourteen potato plots were surveyed by different sampling methods during the cropping season to detect psyllid species from 2016 to 2018. Very few symptomatic and CaLsol-positive plants were detected in Mainland Spain, and any positive plant was detected in the Canary Islands. Most of the adult psyllids captured were identified as Bactericera nigricornis (Foerster, 1848), and some of them as Bactericera trigonica, but no B. cockerelli was detected. B. nigricornis was found widely distributed in the northern half of the Iberian Peninsula; however, this psyllid does not seem sufficient to pose a threat to potato production, due to the scarce number of specimens and because the frequency of B. nigricornis specimens that were CaLsol+ was very low.


Introduction
Candidatus Liberibacter solanacearum (CaLsol) is a Gram-negative bacterium living as a phloem-limited obligate parasite in plants and is associated with zebra chip disease (ZC) in potato. This is an economically important disorder, documented in commercial fields in North and Central America and New Zealand [1]. In the USA, potato yield losses were estimated to reach up to 100% for farmers [2], and chemical management of the disease has an estimated cost of approximately 9.5 million euros per year only in the Pacific Northwest region, where half of the potato crops of the country are cultivated [3]. In Europe, CaLsol is mainly associated with Apiaceae crops [4][5][6]. The impact on carrot and other Apiaceae productions seems to be highly variable between the European regions [7], although it could give rise to severe yield losses [4,8] or losses of commercial value [9]. Since potato production is one of the most important horticultural crop systems in Europe (55.3 million tons in 2020) [10] and Spain (2.14 million tons in 2020) [11], the annual direct economic impact of an eventual infestation of solanaceous crops with CaLsol is estimated at 222 million euros [12], so the threat of ZC for European potato crops is serious. Naturally CaLsol-infected potato tubers have been reported with and without symptoms of ZC in Spain and Finland, respectively [13][14][15], but, so far, no studies have been carried out on the real incidence of this disease.
The characteristic symptom of ZC is a dark and light striped pattern in fresh plants and especially in chips, affecting their appearance and taste and making them commercially unacceptable. Foliar symptoms associated with ZC include upward rolling of the top leaves developing into a basal cupping of the leaflets, accompanied by yellowish or purplish discoloration, proliferation of axillary buds, shortened internodes, swollen nodes, aerial tubers, leaf chlorosis and scorching, and rapid plant death [1]. Symptoms in affected carrots include leaf curling; yellowish, bronze, and purplish discoloration of leaves; stunting of the shoots and roots; and proliferation of secondary roots [6].
The bacterium is transmitted by psyllid species belonging to the family Triozidae (Hemiptera: Psylloidea), which feed on plant phloem sap. The latent period of CaLsol in potato psyllid is approximately two weeks and the bacterium is transmitted in a persistent, circulative, and propagative manner [16,17].
Ten haplotypes of CaLsol have been described so far, causing damages in crops [7]. Haplotypes A and B are associated with diseases caused by the bacterium in potatoes and other Solanaceae species [18], and they are widely spread by Bactericera cockerelli (Šulc, 1909) throughout Central and North America and New Zealand. In Europe, haplotype C is associated with carrot and Trioza apicalis Foerster, 1848 in Finland [19]. Haplotypes D and E are described in carrots and other Apiaceae crops in the Mediterranean Basin [9,18], Spain [4,8,20], France [5], and North Africa [21]. In these production areas, CaLsol is transmitted by Bactericera trigonica Hodkinson, 1981 [22][23][24]. A sixth haplotype was found in the psyllid Trioza urticae (Linné, 1758) and stinging nettle (Urtica dioica, Urticaceae) in Finland, and named haplotype U [25]. A seventh haplotype has been identified, designated haplotype F, which is now the third member of this bacterium that has been found to infect potatoes in the United States [26]. Recently, two new haplotypes, G and H, have been detected. Haplotype G has been detected in samples of Solanum umbelliferum (Solanaceae) from Kern and Riverside counties (United States) from the University of California Riverside herbarium collection [27]. Haplotype H has been found and described in Apiaceae and Polygonaceae family plants from different regions of Finland [28].
Little is known about the role played by different psyllid species involved in CaLsol transmission, particularly in Europe, where different haplotypes, plant species, and vectors have been reported in the last few years. In particular, scarce information is available about the abundance and distribution of psyllid species in potato crops in Europe.
The presence of B. trigonica and Bactericera nigricornis (Foerster, 1848) in potato crops has been reported in Mainland Spain, and B. trigonica in the Canary Islands [20]. Moreover, Antolínez et al. [22] conducted surveys in potato and carrot crops in Mainland Spain in 2016 and 2017 during the cultivation cycle. These authors cited both species in carrot and potato crops, with B. trigonica being the most abundant in carrot and B. nigricornis the most abundant in potato. Antolínez et al. [29] considered that the risk of transmission of CaLsol from carrot to potato by B. trigonica seemed to be very limited. As B. nigricornis was found on both crops, this species could be responsible for the transmission of CaLsol from carrot to potato in Spain, since results of transmission experiments under controlled conditions showed that B. nigricornis was able to transmit CaLsol from carrot to potato plants [30]. Another species of Bactericera that could be involved in CaLsol transmission is Bactericera tremblayi (Wagner, 1961), the onion psyllid. This species was reported in a Spanish horticultural production area, causing important damages in leek crops [31], although it was stated as a carrier but not as a vector of CaLsol [29]. These three species are morphologically similar and belong to the B. nigricornis Foërster complex [32], but more extensive and systematic surveys are required to elucidate the actual role of each psyllid species in CaLsol transmission from carrot to potato crops.
In order to assess the real threat of CaLsol to potato production in Spain, regular and occasional surveys were carried out in large potato-producing areas of the country. The specific aims of this work were as follows: i, to determine the incidence of the disease in the main potato-producing areas, by detecting symptoms of the disease in plants and the bacterium by molecular methods; ii, to identify the psyllid species associated with potato crops in the main producing areas in Spain; and, iii, to study their abundance during the potato cropping season in order to determine the risk as a vector species of CaLsol.  Figure 1 shows sampling points for occasional surveys in Mainland Spain and in the Canary Islands. Monitoring for symptomatic plants was performed in occasional surveys. Twenty plants were collected per location in the mainland (≥1 ha was inspected per plot), and three plants in the Canary Islands (since the average size of the plots inspected was 0.1-0.2 ha). If plants did not have symptoms associated with zebra chip, asymptomatic plants were collected. Each sample consisted of three or four shoots from each plant, which were individually saved and kept at 4 • C until subjected to the laboratory procedure for DNA extraction. At the same time, potato canopies were sampled with a sweep net for psyllid identification and CaLsol detection in insects.

Sampling Sites
Regular surveys. Four different potato-growing areas in Spain were regularly surveyed throughout the growing season over three years (from 2016 to 2018), for monitoring the seasonal abundance of psyllid vectors ( Figure 1). Potato-growing areas of Castile and Leon were monitored in three different locations, Aldearrubia (Salamanca), Gomezserracín (Segovia), and Zamadueñas (Valladolid), using different psyllid sampling methods: trapping by sticky yellow traps, sweeping, visual inspection of plants to look for psyllid eggs and nymphs (Gomezserracín and Zamadueñas in 2016), and horizontal green tile water traps (Zamadueñas 2017 and 2018). Several potato plots were monitored in the north of the Iberian Peninsula. Five potato fields were monitored by sticky yellow traps during the 2017 season in Cantabria, and three during the 2018 season, as well as another potato field by Moericke traps in Iturrieta, Euskadi (2016Euskadi ( , 2017Euskadi ( , 2018. Finally, in Tenerife (Canary Islands), during 2016, three potato plots were sampled in Güímar, Tegueste, and Valle de Guerra, over the cultivation cycle, using three different sampling methods: trapping by sticky yellow traps, visual inspection of plants, and horizontal yellow water traps. Insects captured by horizontal water traps and sweep nets were identified to species and gender level and then analyzed for CaLsol.  Euskadi (2016Euskadi ( , 2017Euskadi ( , 2018. Finally, in Ten (Canary Islands), during 2016, three potato plots were sampled in Güímar, Tegueste, Valle de Guerra, over the cultivation cycle, using three different sampling methods: t ping by sticky yellow traps, visual inspection of plants, and horizontal yellow water tr Insects captured by horizontal water traps and sweep nets were identified to species gender level and then analyzed for CaLsol.

Sampling Methods for Insects
Several methods have been used for the detection and population monitoring of p lids depending on convenience and with the aim of capturing all the species involve most of the sampling periods.
Yellow sticky traps. These traps were sticky on both sides, 25 cm high and 10 wide, and were placed 0.5 m above ground on a wooden stake to trap adult psy (TA168, Sanidad Agrícola Econex, S.L., 30149 El Siscar, Murcia Spain). Sampling for ad began when the plants emerged and continued until the senescence of the canopy. N traps were placed in each plot, forming a square of 20 m size. Traps were collected f each field every 7-10 days, and psyllids on the sticky traps were observed under a bi ular microscope and the number of specimens of Bactericera spp. was recorded.
Sweep net sampling. Potato canopies were sampled for adult psyllids using a scopic folding sweep net. Each sample consisted of ten consecutive sweeps at ten diffe points, to obtain a total of ten samples per plot and date. Each sample was placed

Sampling Methods for Insects
Several methods have been used for the detection and population monitoring of psyllids depending on convenience and with the aim of capturing all the species involved in most of the sampling periods.
Yellow sticky traps. These traps were sticky on both sides, 25 cm high and 10 cm wide, and were placed 0.5 m above ground on a wooden stake to trap adult psyllids (TA168, Sanidad Agrícola Econex, S.L., 30149 El Siscar, Murcia Spain). Sampling for adults began when the plants emerged and continued until the senescence of the canopy. Nine traps were placed in each plot, forming a square of 20 m size. Traps were collected from each field every 7-10 days, and psyllids on the sticky traps were observed under a binocular microscope and the number of specimens of Bactericera spp. was recorded.
Sweep net sampling. Potato canopies were sampled for adult psyllids using a telescopic folding sweep net. Each sample consisted of ten consecutive sweeps at ten different points, to obtain a total of ten samples per plot and date. Each sample was placed in a plastic zip-bag and stored in the laboratory at −20 • C for 48 h to kill the insects. Then, psyllids were selected and preserved in tubes with ethanol 70%, until sex and taxonomic identification and CaLsol analysis were performed.
Horizontal water traps. Moericke water traps (0.5 m × 0.5 m) were placed at canopy level, and one of them was located facing north and the other facing south at each sampling plot. Insects were recovered from the traps once a week. Insects obtained from Moericke water traps were preserved in 70% ethanol, which was then changed to 95% ethanol + 5% glycerol, and refrigerated.
Horizontal green tile water traps (also called Irwin traps) [33] were composed of methacrylate (16.5 cm × 16.5 cm × 4.5 cm) with a green-colored ceramic tile (15.5 cm × 15.5 cm) inside the container (Cambridge 815 from Cambridge tile C., PO Box 15071, Cincinnati, OH 46215, USA), filled with a 50% solution of ethylene glycol in water. The trap was placed at canopy level [22]. Collected insects were preserved in 70% ethanol until taxonomic identification.
Visual inspection of plants. To assess the developmental stages of psyllids, visual inspection of plants was performed to look for psyllid eggs and nymphs. Inspection was carried out from plant emergence to the senescence of the canopy. On each observation date, twenty plants were randomly selected in the plot, and the numbers of eggs and nymphs settled on each plant were counted. Nymphs were collected and reared in the laboratory until adult emergence for identification purposes (see below). The same procedure was also used in the occasional and regular surveys in the Canary Islands in 2016. Nymphs of stages 4 and 5 found on potato plants from regular surveys in Zamadueñas (2016) were taken with shoots, introduced in plastic tubes, and kept in the lab to allow their development at environmental conditions (17 tubes with at least one nymph/tube). Emerged psyllid adults reared in the laboratory from potato plants were identified as described below.
Morphological identification of psyllids. Intact psyllids collected with sweep net sampling and horizontal water traps were separated by gender and identified by morphological examination following the description of the species of the Bactericera nigricornis Foerster complex [31,32] using a Nikon SMZ1000 Zoom Stereo Microscope (Melville, NY 11747-3064, USA.).

CaLsol Detection in Psyllids and Plants
Preparation and DNA extraction of plant samples. Approximately 1 g of the plant sample was crushed into a Bioreba mesh plastic bag at 1:5-10 (wt/vol) in phosphatebuffered saline (PBS) extraction buffer (NaCl 8 g/l; NaH 2 PO 4 2H 2 O, 0.4 g/L; and Na 2 HPO 4 12H 2 O, 2.7 g/L; pH 7.2) with a Homex 6 homogenizer (Bioreba, 4153 Reinach, Switzerland). One ml from each sample was stored at -20 • C until use. DNA was purified from 200 µL of crude plant extract using a modification of the cetyltrimethyl ammonium bromide (CTAB) protocol without β-mercaptoethanol [34], as described in [7]. Purified DNA was preserved at −20 • C until use.
DNA extraction of psyllids. A non-destructive DNA extraction protocol using whole individual specimens was performed using the Chelex protocol [35]. Each specimen, with the head carefully separated from the body, was placed in a 1.5 mL Eppendorf tube, 10 µL of Proteinase K was added, and each tube was incubated at room temperature for 30 min. One hundred and fifty µL of 10% Chelex 100 resin solution in water was added to each tube; the tubes were sealed and incubated overnight at 55 • C. The mixture was centrifugated at 13,000× g for 3 min. The supernatant was extracted and the specimen was then removed and conserved in 70% ethanol for morphological identification. The material used during the preparation was cleaned and disinfected between specimens. The extracted DNA obtained was used for the CaLsol detections. The extracts were analyzed immediately or preserved at −20 • C until use.
Analysis for the detection of CaLsol was performed using the PlantPrint Detection Kit by Real-Time PCR (Taqman) using the conditions, primers, and probes described by [9]. This kit uses a master mix with all the components necessary for the amplification of the specific DNA (Taq polymerase, oligonucleotides, buffer, MgCl, primers, and TaqMan FAM/TAMRA probe). The PCR mix was prepared with 9 µL of master mix and 3 µL of total DNA of insects or plants, and amplification was performed using an initial cycle of 95 • C for 10 min and 45 cycles of 95 • C (15 s) and 64 • C (1 min). Controls supplied by the PlantPrint Kit were used as positive and negative controls.  (Table 1). In the Canary Islands, 64 samples with symptoms, from 45 locations, were analyzed in occasional surveys. The proportion of symptoms among these samples was as follows: deformed leaves (36%), yellowish leaves (34%), curling leaves (18%), purple leaves (17%), chlorotic leaves (11%), plants with aerial tubers (6%), and dwarf plants (5%). None of the plants tested positive for CaLsol.

Psyllid Species Associated with Potato Crop in Spain
In occasional surveys, 661 adult Bactericera psyllid specimens were captured in 36 out of 44 visited plots in Mainland Spain (Tables S1 and 1). Specifically, 97% of psyllids captured by sweep nets were identified as B. nigricornis (639 out of 661). Only eighteen specimens of B. trigonica and four of B. tremblayi were captured, most of them in four potato fields located in Segovia province (Mozoncillo, Cogeces de Íscar, Chatún, and Remondo), where most of the carrot and leek crops are located in Spain, which also explains why the number of captured specimens was higher in Campo de Cuéllar (Segovia).
Specimens of B. nigricornis captured in occasional surveys showed low percentages of insects positive for CaLsol: only 12 out of 639 individuals yielded positive results (1.88%), and the bacterium was detected in 2 out of 18 captured insects identified as B. trigonica (Table 1).

Study of the Abundance of the Psyllid Species during the Potato Cropping Season
In Mainland Spain, plots monitored with yellow sticky traps during the potato cropping season showed a high number of captured psyllids per trap ( Figure S2A). On the plot located in Aldearrubia (Salamanca), population levels of psyllids were low throughout the season, reaching a peak in mid-June, and with an overall mean of 21.20 adults/trap. In Gomezserracín (Segovia), the potato plot showed higher levels of psyllids on traps, reaching the population peak in late August (684.67 ± 322.57 insects/trap). Finally, on the potato plot located in Zamadueñas (Valladolid), the peak psyllid population was higher (226.67 ± 38.71 insects/trap) and occurred later (in early July) than in Aldearrubia (Salamanca).
In Cantabria (north of the Iberian Peninsula), in 2017, we could identify three periods of time that showed population peaks on several field plots ( Figure S2C). Firstly, some potato fields showed a population peak at the end of June (277 insects/trap in Cubillo de Ebro). Then, a second population peak was observed at the end of July (212 insects/trap in San Martín de Elines). Finally, a third population peak was observed at the end of August in San Martín de Elines (204 insects/trap). This pattern was reproduced in 2018, although with fewer catches ( Figure S2D). It is necessary to highlight that, in these types of traps, it was not possible to distinguish the Bactericera species, but it was possible in other types of captures, such as sweep net sampling or water traps.
The most common species captured by sweep net sampling was B. nigricornis (Table 2). A total of 539 insects were captured at all sampling points throughout the study, of which 450 were identified as B. nigricornis and 89 as B. trigonica. Particularly in 2016, 71 insects identified as B. trigonica were trapped by this sampling method in Gomezserracín throughout the season, and 15 individuals of carrot psyllids were captured in Zamadueñas. These two plots were close to carrot crops, the main host plant for B. trigonica.  The weekly evolution of sweep net sampling captures in the field located in Aldearrubia (Salamanca), where only B. nigricornis adults were collected (see Figure 2A), showed that the first psyllids appeared in early June, reaching the maximum population peak at the end of this month (0.60 ± 0.20 psyllids/sweep); then, the psyllid population decreased and remained at low levels until the end of the season. In the field located in Gomezserracín (Segovia), both species had been collected, B. nigricornis and B. trigonica; the first psyllids appeared in late June; the B. nigricornis population level was low throughout the season and the B. trigonica population reached a small peak in late August ( Figure 2B). On the plot located in Zamadueñas (Valladolid), psyllid population levels were also low during the whole season; the earliest appearance in potato fields occurred at 23 May 2017 ( Figure 2C) and the maximum population peak in early July (0.73 ± 0.41 psyllids/sweep). In this location, B. trigonica was collected only in 2016 in late June and early July.  Figure 2D). Captures were higher from mid-June to early September, with a maximum peak in mid-July.
A horizontal green water tile was installed in Zamadueñas (Valladolid) in 2017 and 2018 ( Figure S3). No B. trigonica or B. tremblayi adults were captured during any season. No psyllid was captured in 2018, although a significant number of adults were captured by sweep net sampling. In 2017, a total of 25 psyllids were captured, all of them identified as B. nigricornis ( Table 2). The largest number of captures (14 specimens) occurred at the beginning of the season (23 May 2017) and at the end of June (9 specimens).
The numbers of eggs and nymphs counted by visual inspection in two potato fields  Figure 2D). Captures were higher from mid-June to early September, with a maximum peak in mid-July.
A horizontal green water tile was installed in Zamadueñas (Valladolid) in 2017 and 2018 ( Figure S3). No B. trigonica or B. tremblayi adults were captured during any season. No psyllid was captured in 2018, although a significant number of adults were captured by sweep net sampling. In 2017, a total of 25 psyllids were captured, all of them identified as B. nigricornis ( Table 2). The largest number of captures (14 specimens) occurred at the beginning of the season (23 May 2017) and at the end of June (9 specimens).
The numbers of eggs and nymphs counted by visual inspection in two potato fields are shown in Figure 3. In Gomezserracín (Segovia), the numbers of eggs and nymphs were low throughout the season, reaching a higher level at the end of the season in mid-September. In contrast, the numbers of eggs and immatures were higher in Zamadueñas (Valladolid), increasing drastically in early July, to reach the maximum number of eggs in 08 June 2016 (4.80 ± 0.22 eggs/plant), and the maximum number of nymphs N1-N2 ten days later (3.15 ± 2.64 nymphs/plant). Thirteen adults were obtained from nymphs reared in the lab, and all of them were identified as B. nigricornis.  In the Canary Islands, yellow sticky traps captured fewer psyllids of the Bactericera spp. (Figure S2B) than in Mainland Spain. Regarding horizontal water traps, 233 psyllids were captured, all of them were identified as B. trigonica, and B. nigricornis was not found (Table 2). Finally, neither psyllid eggs nor nymphs were observed in visual inspection in any of the visited potato fields. As B. trigonica cannot reproduce in potato [32], and no B. nigricornis specimen was found in horizontal water traps, we conclude that all Bactericera spp. captured by yellow sticky traps belonged to the B. trigonica species, and so we can state that B. nigricornis was not present in potato crops in the Canary Islands.

Study of the Psyllids as Vector of CaLsol
The analysis for CaLsol in psyllids of the B. nigricornis species in regular surveys showed that the number of positive specimens was very low, both in males and females (Table 2), detecting the bacterium only in 14 males and 6 females out of 290 and 323 individuals, respectively, which constitutes 3.26% of positive insects overall (Table 2). On the contrary, the bacterium was detected in 267 of the 314 individuals identified as B. trigonica, reaching a percentage of 85.03% of CaLsol+ psyllids (Table 2), almost entirely captured in the Canary Islands. Although the rate of positive specimens of carrot psyllids was much higher than that of B. nigricornis, the presence of B. trigonica in potato crops was lower.

Discussion
CaLsol has been present in Europe for a long time; however, haplotype identification determined that American potato haplotypes (A and B), which cause zebra chip disease, are not reported in Europe [7], and no specimens of B. cockerelli, which is the CaLsol vector in America and New Zealand, have been found [1]. Otherwise, CaLsol is a major concern In the Canary Islands, yellow sticky traps captured fewer psyllids of the Bactericera spp. ( Figure S2B) than in Mainland Spain. Regarding horizontal water traps, 233 psyllids were captured, all of them were identified as B. trigonica, and B. nigricornis was not found (Table 2). Finally, neither psyllid eggs nor nymphs were observed in visual inspection in any of the visited potato fields. As B. trigonica cannot reproduce in potato [32], and no B. nigricornis specimen was found in horizontal water traps, we conclude that all Bactericera spp. captured by yellow sticky traps belonged to the B. trigonica species, and so we can state that B. nigricornis was not present in potato crops in the Canary Islands.

Study of the Psyllids as Vector of CaLsol
The analysis for CaLsol in psyllids of the B. nigricornis species in regular surveys showed that the number of positive specimens was very low, both in males and females (Table 2), detecting the bacterium only in 14 males and 6 females out of 290 and 323 individuals, respectively, which constitutes 3.26% of positive insects overall (Table 2). On the contrary, the bacterium was detected in 267 of the 314 individuals identified as B. trigonica, reaching a percentage of 85.03% of CaLsol+ psyllids (Table 2), almost entirely captured in the Canary Islands. Although the rate of positive specimens of carrot psyllids was much higher than that of B. nigricornis, the presence of B. trigonica in potato crops was lower.

Discussion
CaLsol has been present in Europe for a long time; however, haplotype identification determined that American potato haplotypes (A and B), which cause zebra chip disease, are not reported in Europe [7], and no specimens of B. cockerelli, which is the CaLsol vector in America and New Zealand, have been found [1]. Otherwise, CaLsol is a major concern for potato growers in Europe since naturally CaLsol-infected potato tubers have already been reported in Spain and Finland [14,25]. Carrot CaLsol haplotypes have been identified in these positive potato samples (haplotypes C, D, and E) [15,25], but the distribution and prevalence in potato fields in Europe are still unknown.
The results of our survey showed very few CaLsol-positive plants in Mainland Spain, and many in the Canary Islands. Most of the symptoms described on potato plants were non-specific, finding, as a result, very few CaLsol+ symptomatic plants. Zebra-chip-like symptoms such as chlorotic, yellow, purple, curling, or deformed leaves; aerial stem tubers; and dwarf plants, alone or in combination, were mainly caused by potato leaf roll virus (PLRV), Rhizoctonia, or phytoplasmas when they were analyzed (data not shown). The aerial tubers were the most characteristic symptom of the disease, found in only one plot, since all the plants with this symptom were CaLsol+. Moreover, a single plant without any symptom but CaLsol+ was found, as reported in other production areas in Europe [25]. Symptom development depends on the cultivar tolerance and the period of CaLsol infection inside the plant, finding cultivars that develop symptoms from three to eight weeks after the moment of inoculation [36]. As the number of CaLsol+ plants detected was extremely low, we can consider that the incidence of the disease in potato crops in Spain is minimal at present.
It seems clear that any psyllid species could eventually transmit CaLsol from carrot to potato when plots of both crops are close in proximity. In spite of the high number of inspected fields, no B. cockerelli specimen was found in this study in any of the collected samples, neither in seasonal nor occasional surveys, regardless of the sampling method used. Therefore, the presence of the bacterium on potato fields in Spain (haplotypes D and E) [15] could potentially be due to any of the psyllids present in this crop. B. nigricornis, which has polyphagous habits, has been suggested as the vector responsible for CaLsol transmission from carrot to potato in Spain [22,30] and North Africa [23], since it has been found in both crops and shows a similar geographical distribution, although the capacity of this species to develop its entire life cycle in this crop had not been cited until now. Two other Bactericera species were tested as CaLsol vectors: B. trigonica and B. tremblayi. B. trigonica showed a very low transmission rate in potato [29], and B. tremblayi was able to acquire the bacterium when it was forced to feed on infected carrots, but no effective transmission to any crop was reported [29]. In order to evaluate the risk of the wide spreading of CaLsol in potato crops in Spain, we surveyed fields throughout the most important production areas.
B. nigricornis was found to be widely distributed in the northern half of the Iberian Peninsula; it was present in most of the visited potato plots in Castile and Leon, Euskadi, and Cantabria, but not in the Canary Islands. Moreover, B. nigricornis was the more frequently found psyllid species in potato crops in Mainland Spain, in accordance with the results obtained by Antolínez et al. [22], regardless of the method used for monitoring. The number of captured specimens of B. trigonica was higher than B. nigricornis only in Gomezserracín (Segovia), where the carrot crop is more important than potato, and the peak of B. trigonica captures matched with the most common period of carrot harvest; psyllids are widespread in this context, looking for new fields to feed on and colonize. B. trigonica was also abundantly caught by Moericke traps in the Canary Islands. Plots in Tenerife are small and potato plots are usually close to carrot ones, where B. trigonica is very abundant. Moreno et al. [30] reported that B. nigricornis was able to oviposit in potato under controlled conditions, but we detected immature forms of a psyllid species living on potato in Spain. In addition, when we reared immature forms of psyllids collected on potato fields in our laboratory, only adults of B. nigricornis were identified. Therefore, we can conclude that this psyllid species is the only one that could be a threat for potato crops, as plague or as a CaLsol vector, in Spain.
However, the number of captured psyllids was much lower than reported in other crops such as as carrot or celery in Europe [20,22] or potato in the USA [37], and it was similar to results reported by Antolínez et al. [22] for potato in Spain. The presence of B. nigricornis in Spanish potato fields was very scarce compared to other related psyllid species that cause serious damage to other crops, both by feeding on them and via the transmission of CaLsol. The maximum population peak reported in this study was 0.73 insects/sweep in Zamadueñas in regular surveys, while population peaks in B. trigonica in carrot were 35 insects/sweep in Íscar [22] and 3 insects/sweep for B. cockerelli in potato in the Northern USA [37]. Most of the insects captured by sweep nets in Zamadueñas were identified as B. nigricornis, which suggests that the peak of 227 individuals/yellow sticky trap every 10 days would match mostly with this species. These values do not differ significantly from those obtained by Nissinen et al. [38] for T. apicalis in carrot (100 specimens/trap and week), but they are far from the levels of 500 individuals/trap and week reported by Antolínez et al. [22], or the 300 individuals per week obtained for B. cockerelli in potato in the Northern USA [37].
In addition, in regular surveys, B. nigricornis remained during the whole crop cycle, variable depending on the year and the location but generally when the plant presented higher foliage during the months of June and July, in the conditions of the Northern Mainland. From the month of August, when the senescence of the crop starts, the population of psyllids decreases.
Less than 10% of the B. cockerelli field population in the United States were found to carry CaLsol [39]; however, the proportion of the T. apicalis population harboring CaLsol in Finland was 61% to 67% [6,40]. In our study, CaLsol+ insect percentages varied between 1.88 and 3.90% in B. nigricornis and 33.33% and 85.03% in B. trigonica. Although carrot psylla showed sufficient levels of bacteria-carrying insects, it was reported that the risk of CaLsol transmission mediated by B. trigonica in potato was very low [29]. Regarding B. nigricornis, despite the low number of CaLsol+ captured specimens, it has been reported that it is able to transmit CaLsol to potato plants, although in a less efficient manner than in carrot [30].
Several methods have been used for the detection and population monitoring of psyllids, such as suction traps, vacuum sampling of plants, sweep net sampling, visual inspection of plant material, horizontal water traps, and colored sticky traps. Suction traps and vacuum samplers were found to be ineffective for detecting and sampling B. cockerelli, respectively [39,41]. However, sweep nets and sticky card traps are used extensively [37,39,41]. These methods, sweeping and trapping by yellow sticky cards, were also used for B. trigonica and B. nigricornis [22,23]. Moreover, visual inspection provided detailed information regarding the population density of these pests and was used for B. cockerelli [37,39,41], B. trigonica [22,23], and B. nigricornis [23] population monitoring. Water horizontal traps were used for determining which species were landing over the crop, looking for a plant to feed on [33]. This tool was used in carrot and potato by Antolínez et al. [22], being effective to catch the early immigrants. In our study, monitoring by sweeping net was very effective; samples could be identified at species level and subsequently CaLsol could be analyzed in insects. However, a long training time is necessary to carry out the identification. Yellow sticky traps have been widely used since they are very useful for detecting adult population peaks and are easy to manage, although individuals cannot be identified to species level, but only genus level. Further, these traps exert attraction for insects, collecting individuals that are not properly found in the sampling plot. On the other hand, visual inspection provides detailed information about the population density of immature forms of these insects in plants, allowing us to identify the moment of the initial appearance of the pest in the crop. Furthermore, in this work, thanks to visual inspection, it was possible to observe, for the first time, the development of B. nigricornis in potato crops in Spain, where this insect has managed to complete the cycle. The results show that the psyllid B. nigricornis is not a threat species in potato crops, regardless of the capture method used.

Conclusions
Although CaLsol haplotypes in Europe are different from American ones and some epidemiological differences could exist, the abundance of B. nigricornis does not seem sufficient to pose a threat for potato production, due to the scarce number of specimens and because the frequency of B. nigricornis specimens that are CaLsol+ is very low. The maximum population of this species matched with the vegetative growth of potato plants, the optimum moment of CaLsol infection, and suitable temperatures for ZC symptom development. These conditions allow the presence of ZC symptoms in harvesting tubers.