1. Introduction
Many soilborne diseases are persistent, recurrent problems in potato production. These diseases compromise plant growth and vigor, lower tuber quality, and reduce overall tuber marketability. Several soilborne diseases of potato (Solanum tuberosum), which are prevalent throughout the Northeastern US and most other potato-producing regions, include: stem canker and black scurf, caused by the fungus Rhizoctonia solani; silver scurf, caused by the fungus Helminthosporium solani; common scab, caused by the bacterium Streptomyces scabies; and powdery scab, caused by the protist-like plasmodiophorid pathogen Spongospora subterranea f.sp. subterranea.
Powdery scab is of particular concern, as occurrence of this disease has been increasing in the Northeast, as well as several other potato-producing regions [
1,
2,
3,
4,
5]. Powdery scab causes abundant lesions (pustules) on the tuber surface, directly reducing tuber marketability and potentially reducing yields following additional losses during storage. In addition, the pathogen also infects roots, causing root galls and reductions in plant productivity and yield [
4,
6]. Moreover, the disease’s causal organism,
Spongospora subterranea, is the sole vector of potato mop-top virus (PMTV), a serious disease that has been observed in potato production systems in Maine and Canada from 2002 on [
2,
7].
Spongospora subterranea is extremely long-lived in the soil, and is thought to persist indefinitely [
1,
8]. Current control measures using chemicals or cultural practices have not been very effective in managing the pathogen or disease [
1,
3,
9,
10,
11].
Although chemical treatments such as soil fumigants and seed treatments have shown some efficacy in reducing many soilborne diseases, their effects have generally been short-lived, and their use has not always been practical or sufficiently effective. Options for effective approaches that could be both economically and environmentally sustainable would be highly desirable. Crop rotations have long been used as a means to help manage soilborne diseases. Thus, an approach with much potential is in making improvements to optimize the disease-suppressive capabilities of rotations to be more effective at suppressing multiple diseases.
Use of
Brassica (and other related genera) plants as cover and green manure crops has been associated with reductions in soilborne diseases. Crops in the Brassicaceae family, which include broccoli, cabbage, cauliflower, kale, turnip, radish, canola, rapeseed, and various mustards, produce sulfur compounds called glucosinolates that break down to produce isothiocyanates that are toxic to many soil organisms as part of a process referred to as biofumigation [
12,
13]. This mechanism has been shown to reduce populations of multiple soilborne pathogens [
14,
15], nematodes [
16,
17], and weeds [
18,
19]. Many additional factors, such as soil type, plant growth stage, glucosinolate concentration/isothiocyanate composition, and method of incorporation, play crucial roles in the use of biofumigant rotation crops for disease suppression [
12].
Brassica crops grown as green manures, in particular, have been shown to be effective in reducing soilborne diseases, and particularly, soilborne potato diseases in numerous field trials [
15,
20,
21]. In addition to the potential disease benefits of biofumigation, studies also show improvements to many soil characteristics, such as increased porosity and organic matter content, which may lead to lower disease levels as well as increased crop yields when
Brassica crops are used [
22].
Brassica (and other) rotation crops may also suppress diseases, through their effects on soil microbial communities and development of suppressive conditions, that are separate from the biofumigation response. Larkin and Honeycutt [
23] observed that rotations containing canola and rapeseed (
Brassica napus) exhibited microbial community characteristics distinct from non-
Brassica rotations, and these rotations resulted in reduced incidence and severity of
Rhizoctonia disease in potato, even when the rotations were not incorporated as green manures. In addition, Larkin and Griffin [
15] observed that disease suppression was not consistently associated with high glucosinolate-producing crops, and that barley and ryegrass rotations resulted in disease reduction of multiple soilborne diseases of potato that was comparable to that of
Brassica green manures. Mazzola et al. [
24] observed that
B. napus seed meal amendments suppressed
R. solani and other related apple replant diseases regardless of the glucosinolate content. Cohen et al. [
25] determined that the observed disease suppression was associated with dramatic changes to the total bacteria and actinomycete populations in response to the seed meal amendments.
Although previous research has demonstrated the potential of Brassicas to reduce disease, it is not yet known which crops are best for which diseases, how to manage these crops for effective disease reduction, and how to best implement these crops into a potato rotation and production system. One factor of particular importance to growers is whether a full-season green manure crop is needed to achieve disease control. The disadvantage of green manure crops is that it takes the field out of any kind of production for that season. If use of a Brassica cash crop, such as condiment mustard or canola, can be effective in reducing disease, or if the Brassica crop can be effective as a fall cover crop implemented after a regular seasonal rotation crop, that would give growers more flexibility in how to effectively implement Brassicas for disease control into their production system. In other potato-growing regions, such as the western U.S., Brassicas can be grown as fall cover or green manure crops, but in the shorter-growing season of the Northeast, this may not be effective. The intent of this research was to evaluate the effects of a variety of different Brassica rotation crops managed in different ways (as green manures, harvested crops, fall cover crops) on several different aspects of potato production, including soilborne diseases and yield, in multiple field settings. Thus, the current field studies were established to assess these aspects of rotation crop selection and management as they relate to disease reduction and tuber yield.
2. Materials and Methods
2.1. Field Sites
Field study sites were established on-farm at two commercial potato farms in Aroostook County, Maine, one located in Central Aroostook and one in Northern Aroostook. At each site, two adjacent or nearby fields were prepared for establishment of rotation crops in 2005 and 2006 (designated as Year 0 and Year 1), respectively, and then potato crops were planted following the rotation crops, in 2006 and 2007 (designated as Year 1 and Year 2), respectively. Thus, at each site, two full two-year rotation cycles were achieved in three field seasons. Both sites had a known previous history of soilborne diseases, including powdery scab, black scurf, common scab, and silver scurf problems. In addition, at a third site located on the USDA-ARS Research Farm at Newport, ME (Southern Penobscot County), a single field was used and monitored through two rotation cycles (2005–2008). Experimental details for each site are explained below.
Central Aroostook Site. Fields were located on a commercial processing and seed stock operation. The soil type was a Caribou gravelly loam (fine-loamy, isotic, frigid, Typic Haplorthod). Prior to the plots being established in June and May of Years 0 and 1, respectively, the fields were planted to potato the previous year and remained fallow post-harvest. The grower’s typical two-year rotation was potato followed by canola. Experimental design in both fields was a randomized complete block consisting of five rotation treatments in each of four replicated blocks. In Year 0, plot size was 3.1 m × 18.3 m and in Year 1 plot size was 6.1 m × 30.5 m (smaller plot size due to available land limitations). Brassica rotation crops were planted with a cone seeder at 8 kg/ha on 21 and 22 June of Years 0 and 1, respectively.
Northern Aroostook Site. Fields were located on a commercial seed stock operation. Soil type was a Plaisted gravelly loam (coarse loamy, isotic, frigid, Oxyaquic Haplorthod). The fields had been in potato the previous year and remained fallow post-harvest. The grower’s typical two-year rotation was buckwheat followed by potato. The experimental design was a randomized complete block with eight rotation treatments in each of four replicate blocks (plot size 10.7 m × 45.7 m and 10.7 m × 30.5 m in Years 0 and 1, respectively). Brassica rotation crops were planted using the grower’s box-spreader at 9 kg/ha with 34 kg/ha 10-10-10 fertilizer on 21 and 22 June in Years 0 and 1, respectively.
Newport Site. This trial was conducted on previously established rotation plots (two-year rotation study begun in 2001) with a history of Rhizoctonia and common scab. Soil at this site was a Nokomis silt loam (coarse loamy, mixed, frigid, Typic Haplorthod). The experimental design was a randomized complete block consisting of four replicate blocks with three rotation crop treatments (
Table 1). Each rotation plot was 3.7 m × 18.3 m. This study also included a nonrotation control of continuous potato (cultivar “Shepody”), with potato planted each year. Rotation crops were planted in June 2005 and 2007, with the
Brassica crop planted at approximately 8 kg/ha.
2.2. Rotation Crops and Rotation Crop–Year Management
The following
Brassica rotation crop treatments were assessed in multiple trials: “Hyola-420” untreated canola (
Brassica napus), “Dwarf Essex” winter rapeseed (
Brassica napus), “Ace yellow” condiment mustard (
Sinapis alba), “Caliente 119” high-glucosinolate (High-GSL) white/oriental mustard blend (
Sinapis alba/Brassica juncea), and oriental mustard (
Brassica juncea). Oilseed radish (
Raphanus sativa) was planted at Northern Aroostook in Year 0 only (due to lack of seed in the following year) and was replaced by “Duchess Brown” condiment mustard (
Brassica juncea) in Year 1. The non-
Brassica rotation crops included buckwheat (
Fagopyrum sagittatum), buckwheat underseeded with mammoth red clover (
Trifolium pratense L.), perennial ryegrass (
Lolium perenne L.), and barley (
Hordeum vulgare) underseeded with perennial ryegrass, which represented the standard rotation crop at each of the three sites, respectively.
Table 1 shows characteristics of the rotation crops and which crops were planted at each field site and year. Plots were managed according to standard management practices by the grower throughout the growing season. Plots were monitored throughout the season for germination and stand quality.
Rotation crops that normally would be harvested for seed or forage rather than incorporated as a green manure were handled that way, so the yellow condiment mustard and ryegrass at the Central Aroostook site were harvested/mowed but not incorporated, and barley/ryegrass at Newport was not incorporated. All other rotations were mowed with a flail mower, and then immediately incorporated with a moldboard plow as green manures.
Above-ground rotation crop biomass samples were taken from each rotation plot in August prior to incorporation at each field site. All plants within two randomly-determined 1/8 m2 quadrats were removed at 5 cm above the ground. Biomass samples were weighed immediately and also after approximately one week of drying. Measurements were taken when plants were fully mature, but senescence had not occurred. Rotation crops were mowed/incorporated on 10 and 20 August in Years 0 and 1, respectively, at the Central Aroostook site, and 4 and 20 August, at the Northern Aroostook site.
The original intent of the study was to also have a fall cover crop of rapeseed (“Dwarf Essex”) following the summer rotation crops and planted on half of each plot (as a split-block treatment). This was attempted each year at the Central Aroostook site and in Year 0 at the Northern Aroostook site, with rapeseed planted with a cone seeder at 8 kg/ha on 14 and 18 September, in Years 0 and 1 at the Central Aroostook site, respectively, and on 26 August, Year 0 at the Northern Aroostook site. Stand emergence and growth was extremely poor both years, and post-germination plant growth was minimal. Data from these failed cover crops were not used in the analyses. In addition, at the Newport site, a series of timed plantings of rapeseed were made on 1 and 15 August and 1 and 15 September 2006 in demonstration plots just to determine feasibility of the fall rapeseed cover crop. Only the 1 August planting resulted in reasonable germination and substantial plant growth, with all later plantings failing to produce adequate biomass for use as a cover crop. Thus, further use of rapeseed as a fall cover crop was dropped from the study.
2.3. Potato Crop–Year Management
In the following spring after rotation crop treatments, all plots were planted to potato. At the Central Aroostook site, cultivar “Andover” (used for processing) was planted on 28 May in Year 1, potato variety “Dark Red Norland” (seed stock) was planted on 15 May in Year 2. At the Northern Aroostook site, all plots were planted to a Frito-Lay® proprietary seed potato cultivar in both years, on 1 and 3 June in Years 1 and 2, respectively. At the Newport site, all plots were planted to potato cultivar “Shepody” on 7 June and 15 May in Years 1 and 2, respectively. The potato plants were managed by the grower using conventional management practices common to the region. Potato plants and roots were assessed on-site for stem and stolon canker lesions and other root diseases in mid-August at each site. Two plants (including roots and tubers) from each of two middle-rows (for a total of four plants per plot) were hand-dug and above-ground biomass was removed, after which the stems and stolons were rinsed in water to remove excess soil and to make the lesions easier to identify. The rating scale was as follows: 0 = no symptoms present; 1 = mild discolorations on stems and/or stolons; 2 = distinct lesions visible, covering <25% of the stem or stolon circumference; 3 = lesions extending around 25–75% of stem or stolon circumference; 4 = greater than 75% lesion coverage of stem or stolon circumference; 5 = stem/stolons necrotic, complete desiccation.
Potato tubers were harvested from all plots in September of each year. From each plot, a 3.1 m section from each of two separate middle plot rows was harvested by hand (6.2 m total per plot). In Year 1 at the Northern Aroostook site, the grower independently harvested all plots before the intended hand-digging was scheduled to occur, and it was not possible to obtain yield data from these samples (disease ratings only). All harvested tubers were washed, weighed, and graded according to size. Tubers larger than 4.7 cm diameter were considered marketable by the growers. At the Central Aroostook and Newport sites in Year 1 only, tubers were graded as small, medium, and large according to the categories <4.7 cm, 4.7 cm–5.7 cm, and >5.7 cm. At all other sites, tubers were just classified as marketable (>4.7 cm) or unmarketable (<4.7 cm). All yield values were converted to represent Mg/ha. After tubers were washed and graded for size and abnormalities, they were visually assessed for incidence and severity of tuber diseases (if present). A random sample of 30 tubers per plot was used for these assessments, with severity determined as the percentage of tuber surface area that was covered by sclerotia or lesions of the particular disease. A severity rating of greater than 2% tuber coverage was used as a threshold above which most diseases become a problem for marketability. Thus, incidence of tubers with greater than 2% severity represented the proportion of tubers that are particular problems for growers as they could be rejected due to disease and was referred to as the incidence of substantial disease. This measure of incidence was used for reporting most disease data. However, where disease incidence and severity were particularly low, the measure of total incidence (percentage of tubers showing any disease symptoms) was used.
2.4. Statistical Analysis
Data from rotation crop biomass, disease ratings, and tuber yield assessments were analyzed by analysis of variance using the appropriate factor and interaction structure for the randomized complete block or split-block design, as needed. All experiments used four replications of each rotation treatment and data from each trial were analyzed separately using SAS Proc GLM (version 9.4, SAS Institute, Cary, North Carolina). Mean separation was accomplished using Fisher’s protected least significant difference (LSD) test. Correlation assessments among the different parameters were derived from Pearson’s Product-Moment Correlation Coefficient matrices. A parameter based on the relative ranking of glucosinolate production (0–6) for each rotation crop, as well as a parameter that combined the glucosinolate ranking with rotation biomass production, was used as an estimate of the potential role of glucosinolate for correlation analysis purposes. Significance for all tests was evaluated at P < 0.05.
4. Discussion
Several rotation crop treatments indicated capabilities for reducing multiple soilborne diseases, although the results were not always consistent from one site to another or from one year to the next. Although no single rotation provided consistent soilborne disease control, multiple rotations were observed to reduce certain diseases. The high-GSL mustard blend generally had the most significant effects on reducing soilborne diseases throughout the study, where reductions were observed in common scab (Northern Aroostook Year 1), powdery scab (Central Aroostook Year 1 and Northern Aroostook Year 2), and silver scurf and black scurf (Central Aroostook Year 1) compared to other rotations, and stem canker, black scurf, and common scab at Newport Year 1 and canker and black scurf at Newport Year 2 relative to a nonrotation control. Overall, the mustard blend was effective in reducing disease in 11 out of 15 disease interactions. Other Brassicas reduced diseases at one site or another, including winter rapeseed (reductions of common scab and powdery scab at Northern Aroostook), yellow condiment mustard (reductions of silver scurf and powdery scab at Central Aroostook Year 1), oilseed radish (reductions of powdery scab at Northern Aroostook Year 1), oriental mustard (reductions of common scab at Northern Aroostook Year 2), and canola (reductions of common scab at Northern Aroostook Year 1). However, the non-Brassica crops (perennial ryegrass, buckwheat and buckwheat/clover) also showed significant reductions in diseases comparable to those of the mustard blend and other Brassicas at some locations (ryegrass reduced common scab, silver scurf, black scurf, and powdery scab at Central Aroostook, buckwheat and buckwheat/clover reduced common scab and powdery scab at Northern Aroostook). However, no rotations reduced common scab at Central Aroostook in Year 1.
Perennial ryegrass and the mustard blend rotations significantly reduced the incidence and severity of powdery scab disease at the only field site where powdery scab was a substantial problem (Central Aroostook Year 1), with reductions of 31–55% relative to other rotations. This indicates that both a high-GSL
Brassica crop and a non-
Brassica grass crop can substantially reduce disease caused by this pathogen. Mustard blend also reduced powdery scab somewhat at Northern Aroostook in Year 2, although disease levels were very low. However, in Year 1 at Northern Aroostook, mustard blend was responsible for among the higher disease levels observed, although again, overall disease levels were low that year. Oilseed radish also substantially reduced powdery scab in the one year it was grown (Northern Aroostook Year 1), which may be worth further investigation. Larkin and Griffin [
15] demonstrated that Indian mustard (
Brassica juncea), canola, rapeseed, and “Lemtal” ryegrass rotations reduced the incidence and severity of powdery scab by 16–40% in previous field trials. These studies also suggested that some
Brassica crops may provide better control for powdery scab (such as Indian or oriental mustard), while others (canola, rapeseed) may provide better control for black scurf and
Rhizoctonia diseases. Larkin and Griffin [
15] indicated that canola, rapeseed, and yellow mustard reduced severity and incidence of black scurf by 48–78% in those studies, which are consistent with long-term field studies that demonstrate the effectiveness of canola and rapeseed rotations to suppress levels of
Rhizoctonia potato diseases [
23]. In the current study, no distinct separation among rotation crops was observed regarding preferential control of specific pathogens, although black scurf levels were consistently low at all field sites.
It should be noted that these trials represent results based on a single year of a rotation crop grown prior to potato, and that to fully evaluate the more long-term effects of these rotation crops, additional testing over multiple rotation cycles is needed. In previous field studies, Brassica crops used as rotation or green manure crops reduced black scurf and common scab over multiple cropping cycles and years [
26,
27,
28]. In other studies, two-year rotations with a variety of different crops (alfalfa, oats, vetch, lupine, buckwheat, and ryegrass) have all been observed to reduce the incidence and/or severity of some soilborne diseases, such as stem lesions of
R. solani by as much as ~50–80% relative to continuous potato [
29,
30]. Single-season green manure treatments of buckwheat or canola have resulted in significantly less Verticillium wilt and marginally less common scab as well as increased potato yield relative to fallow control plots [
31]. In these experiments, green manure treatments were also associated with an increase in the density and pathogen-inhibitory activity of indigenous Streptomycetes toward multiple soilborne potato pathogens (
S. scabies,
V. dahliae,
F. oxysporum, and
R. solani). Thus, it is not surprising that ryegrass or buckwheat rotations, as observed in this study, can be effective in reducing soilborne diseases.
Canola and rapeseed rotations in the current research resulted in higher yields in Year 1 at the Central Aroostook site, and both the mustard blend and barley/ryegrass rotations resulted in significantly higher yields relative to a continuous potato system at the Newport site. Overall, however, rotation crops did not greatly affect tuber yield. There was some indication that the high-GSL mustard blend may have depressed yield slightly, with lower yields at the Central Aroostook and Newport sites in Year 1 than some other rotations. In addition, relative glucosinolate rank was negatively correlated with yield at Central Aroostook over both site years. Larkin and Honeycutt [
23] reported that total and marketable yields were negatively correlated with black scurf incidence. In this study, common scab severity was negatively correlated with total and marketable tuber yield at some sites.
The parameter most consistently associated with higher yields was rotation crop biomass, which was correlated with total and marketable yield at both the Central and Northern Aroostook sites. This suggests that the increased organic matter added through incorporation of green manures may be related to yield improvements, which is consistent with numerous reports [
31,
32,
33]. Cover crops are known to improve productivity and soil properties [
26,
34], but green manures may have even greater effects [
20]. Green manures are known to increase microbial biomass and activity and soil microbial community characteristics [
26,
27,
35], and have also been shown to change soil microbial communities in ways that are distinctly different from other organic amendments [
36]. Friberg et al. [
37] also observed that incorporation of mustard residues consistently resulted in greater effects on soil microbial communities and greater reductions in soilborne diseases than other types of organic amendments. In a previous study examining different rotation crops (including Brassicas) managed as green manures vs. cover crops, all crops assessed were more effective at both increasing yield and reducing soilborne diseases when managed as a green manure than as a cover crop, and the known disease-suppressive crops (particularly mustard blend) were most effective of all [
38].
Although disease reductions due to the different rotation crops were variable, there was no clear association between either rotation crop biomass or relative crop glucosinolate levels and disease control. For example, at the Central Aroostook site, ryegrass produced the lowest crop biomass in both years and also contains no glucosinolate compounds, but was most effective in reducing common scab in Year 1 and reduced powdery scab comparable to the high-GSL mustard blend in Year 2. As further support of these observations, relative crop glucosinolate rank, rotation crop biomass, and the interaction of the rank and biomass parameters were not correlated with disease parameters at any of the sites. Such correlation analyses help determine the overall relationships across all rotation treatments and provide information on overall trends and mechanisms. These results do not support the notion that disease control is closely associated with glucosinolate levels or biofumigation potential of the rotation crops. In addition, in Year 1, ryegrass biomass was not incorporated, yet still resulted in substantial disease control, indicating that incorporation of the rotation crops as green manures was also not necessarily associated with improved disease control.
The capability of low glucosinolate
Brassica crops and non-
Brassica crops to reduce soilborne diseases suggests that a factor other than the toxicity of glucosinolate-derived compounds is an important mechanism of action in reducing soilborne diseases. Previous research has suggested that specific rotation crop effects on soil microbial communities may be at least as important, if not more important, than biofumigation in the reduction of soilborne diseases. Mazzola et al. [
24] used
B. napus seed meal amendments at varied rates and reported suppression of
R. solani and other related apple replant diseases, regardless of the glucosinolate content. The observed disease suppression was associated with dramatic changes to the total bacteria and actinomycete populations in response to the seed meal amendments, and Cohen et al. [
25] reported that additional changes within the microbial communities, including increased populations of nitrifying bacteria, were associated with disease suppression. Larkin and Honeycutt [
23] defined several associations between multiple soil microbial community characteristics, tuber yield, and
Rhizoctonia potato diseases.
Establishment of winter rapeseed as a fall cover crop, as has been successfully implemented in other potato-growing areas, was not successful at any of the three sites in this study. Additional attempts at establishing a fall
Brassica cover crop at Presque Isle and Newport, ME locations over the past few years have also been unsuccessful when planted later than Mid-August (unpublished data). Planting dates of the fall rapeseed crops ranged from late August to mid-September in these trials, which are typical of the period available for fall planting following most summer rotation crops. The short growing season of Maine does not appear to be very amenable to fall planting with most of the currently-available
Brassica crops. From our work, it appears that for successful Brassica cover crops, fall plantings need to be made by the first week of August in Northern Maine and by mid-August in the rest of Maine to assure a productive cover crop. For use as a disease-suppressive green manure, even earlier plantings may be needed. Based on these results, the use of
Brassica as a fall cover crop in Maine (and other areas with short growing seasons) may be extremely limited. Thus, under these conditions, inclusion of
Brassicas in potato cropping systems in the northeast appears to be best used as a full-season, or early-season rotation crop or green manure. However, other crops, such as winter rye or ryegrass, can be successfully used as a cover crop later into the fall in Maine, with generally favorable results for the reduction of soilborne disease [
26].
Although one specific rotation crop did not emerge as clearly better than others for reducing soilborne diseases in these trials, and results were somewhat variable from site to site, this does not necessarily suggest that the rotations were not effective at reducing disease. The results from the Newport site clearly demonstrated the increased disease pressure and low yields that occur when no rotation is used, as well as the substantial reductions in disease (by 14–58%) and improved yield (by 14–48%) that effective rotations can provide. At the other sites (which did not have continuous potato as a treatment), it was more difficult to distinguish among the rotations, in part because all the rotations used were fairly similar, and generally would be considered to be “good” rotations for use in potato production. Disease levels for black scurf, powdery scab, and silver scurf were generally lower than would be expected for these fields, possibly due to the rotation crops. Common scab, however, was present at moderate-substantial levels at all sites, and appeared to be less affected by the rotations (lower disease reductions) than other diseases. The variability in disease reduction that was observed at the different sites and years are likely due to a variety of interactions among numerous abiotic factors, such as soil properties, moisture, and temperature, and biotic factors, such as pathogen inoculum, crop dynamics, soil microbial community characteristics and fluctuations, that were occurring at each site, sub-site, and micro-site during the individual growing year. It is common for there to be much variability in the occurrence and development of soilborne diseases, in general, and for disease control, in particular. This variability accurately represents the reality and challenges associated with real-life on-farm disease management applications. Additionally, because the sites were located on different commercial farms and a research farm, the rotations were exposed to varying management practices, such as tillage and fertilization histories. In a survey summarizing the results from over 70 individual field trial interactions consisting of several different
Brassica crops and rotations and under a variety of methodologies, conditions and locations, overall Brassica rotations and green manures were effective in increasing potato yield in over 50% of the trials, and effective in reducing black scurf disease in 70% of the trials, common scab in 40%, and powdery scab in 46% of the trials where those diseases occurred [
20]. Thus, despite variability from trial to trial, overall results showed consistent benefits.
In this research, as well as in previous studies [
15],
Brassica crops were observed to reduce various soilborne diseases, and in some cases, the high-GSL
Brassica crops (mustard blend, oriental, and Indian mustard) were the most effective of the
Brassicas. However, in both these research studies, particular
Brassica crops were never clearly superior to some other
Brassica crops or to other non-
Brassica rotations, producing generally comparable disease reduction. Thus, although a variety of
Brassica crops do appear to offer potential for disease reduction and make positive contributions to the potato rotations, there is no clear evidence from these studies that
Brassica rotation crops are significantly better than certain other rotation crops that also provide good disease control and crop benefits, such as perennial ryegrass.