- Author: Shimat Villanassery Joseph
- Author: Richard Smith
In the summer of 2014 we received an unprecedented number of plant samples with calcium disorders from growers and PCA's. Normally we expect to see a spike in tipburn samples in July into August on romaine, but this year we had samples from a wide variety of crops and the calcium related issues persisted into October. The most well known calcium disorder in our area is tipburn on head and romaine lettuce.
Calcium disorders are not generally related to low levels of calcium in the soil solution. In a study conducted in the Salinas Valley in 2006 with Tim Hartz, we observed that soil solution calcium ranged from 5 - 80 meq/liter and averaged 34 meq/liter. Each meq/liter = 20 PPM, therefore soil solution calcium ranged from 100 - 1,600 PPM. By comparison, hydroponic nutrient solutions used in greenhouse vegetable production typically contain only 150-250 PPM Ca. Calcium deficiency on vegetables is more of a physiological issue related to the affected tissue obtaining sufficient calcium from the flow in the xylem of the plant. The flow of xylem in the plant is driven by transpiration. If not enough water is moving through the plant, temporary and localized calcium deficiency may occur.
In crops like head lettuce, cabbage and nappa cabbage it is easy to envision low levels of transpiration may occur on leave on the inside of the head once the wrapper leave close in. In head lettuce a great deal of effort has taken place to select and breed for tipburn resistant varieties. In general, tipburn resistant varieties have worked well in head lettuce, but this year we observed greater incidence of tipburn on head lettuce (photo 1). Significant tipburn was also observed in both cabbage and nappa cabbage (photos 2&3).
Another crop that had significant calcium disorders was celery (photo 4). In celery it is called black heart and this year many fields were affected. Fennel is in the same plant family as celery and for the first time this year we had samples with black heart symptoms (photo 5). Other crops that were affected with calcium disorders included broccoli (brown bead), cauliflower and artichokes.
In the 2006 study we identified low evaporation due to fog as the main factor that increased the incidence of tipburn on romaine lettuce during the months of July and August. There has been less breeding for tipburn resistance in romaine and this crop is fairly susceptible to this calcium disorder. As a result growers do not plant romaine in the foggiest parts of the Salinas Valley for July harvests.
Rapid growth with low levels of transpiration is the main factor that drives calcium disorders in lettuce as well as other crops. One factor that people noted this year were the warm night time temperatures. Table 1 confirms that the minimum nighttime temperatures were higher in 2014 than in 2013 in July, August and September. We suspect that the higher nighttime temperatures allowed the crops to continue to grow rapidly in the night when there is no transpiration. Rapid growth that outstrips the crops ability to supply adequate levels of calcium to susceptible tissue is the main reason for calcium disorders in crops. Factors that induce rapid growth vary but include high soil moisture after a dry period, high levels of fertilization and high humidity. All of these factors can contribute to calcium disorders in crops. Keeping the growth rate of the crops as constant as possible may be a partial solution to this problem, but it is easier said than done, especially when there are periodic fluctuations in temperature and levels of humidity due to fog. This year it appears that the warm nights may have contributed to the issue and there was not much we could do about that.
Table 1. Monthly average maximum and minimum (nighttime) temperatures (°F) comparison between 2013 and 2014 (data from the North Salinas CIMIS station)
Month |
Maximum Air Temp |
Minimum Air Temp |
Difference (night - day) |
Average Air Temp |
June 2013 | 65.4 | 51.4 | 14.0 | 58.0 |
June 2014 | 64.9 | 51.1 | 13.8 | 57.0 |
July 2013 | 65.1 | 53.8 | 11.3 | 57.9 |
July 2014 | 67.9 | 55.8 | 12.1 | 61.0 |
August 2013 | 68.3 | 53.6 | 14.7 | 59.4 |
August 2014 | 68.9 | 58.0 | 10.9 | 62.1 |
September 2013 | 68.5 | 47.2 | 21.4 | 57.1 |
September 2014 | 69.2 | 56.6 | 12.6 | 62.1 |
- Author: Michael D Cahn
- Author: Oleg Daugovish
- Author: Mark Bolda
Establishing strawberry transplants using drip has several potential advantages compared to overhead sprinklers. Irrigation run-off can be greatly reduced, which protects surface water quality. Some growers have found that they can save water using drip for transplant establishment, and save costs associated with using overhead sprinklers. Often nitrogen fertilizer can be spoon fed to the crop through the drip system earlier in the season than in fields established with sprinklers, thereby reducing the reliance on pre-plant fertilizers that may result in nitrate leaching losses.
Nevertheless, growers are concerned that irrigating transplants using mainly drip may result in less vigorous growth and more dead plants during the establishment period, and yields during the production season will be lower than crops established with sprinklers. One of the specific concerns is that the drip lines adjacent to plant rows may not be as effective in leaching salts from the root zone of young plants as overhead sprinklers. Another worry is that if the transplants are not properly planted and gaps exist between the root crown and the soil, moisture will not move toward and imbibe young roots, and the plant may be set back or die.
Last year was challenging for establishing strawberries is many fields on the Central Coast due to the lack of rain, which normally helps to leach salts that may accumulate around young strawberry transplants. However, these challenging conditions were perfect for comparing vigor and yield of strawberries established using drip and overhead sprinklers.
Field trial description
We conducted a demonstration trial at a ranch in North Salinas beginning November 13, 2013. Soil was a loam texture. The field was planted with UC Albion variety in 2 rows on 52-inch wide beds. Two plots, each of approximately 1-acre in size, were located adjacent to each other in one of the irrigation blocks. Transplants were established using drip in one of the plots and with overhead sprinklers in the other plot. The irrigation foreman made all decisions on how long and often to irrigate both plots. Overhead sprinklers were used for the first 2 irrigations in the drip plot to assure that the transplants were in good contact with the soil. All subsequent irrigations were made using 2 lines of drip tape per bed. In the plot established with overhead sprinklers, transplants were also irrigated twice using the drip system. The last sprinkler irrigation was on January 25th, after which both plots were irrigated with only drip.
Applied water was monitored using flow meters installed on the drip submain and on the sprinkler main line until the end of February. Soil moisture was evaluated in the upper 6 inches of soil next to the transplants using a volumetric moisture sensor at weekly intervals during establishment. Soil salinity was also periodically monitored to a 4 inch depth next to the transplants using a soil salinity sensor (Fig 1.), or by sampling soil and analyzing saturated paste extracts for salts. Plants were rated for vigor and evaluated for canopy cover until mid February (Fig 2.). Marketable fruit yield was evaluated between late April and mid July.
Figure 1. A 5TE decagon probe was used to measure bulk salinity near strawberry plants.
Figure 2. Transplants were periodically evaluated for canopy size by measuring plant width or using a multi-spectral NDVI camera.
Results
Applied water during transplant establishment was about 25% less for the drip treatment compared to the standard sprinkler treatment. As shown in Fig. 3, irrigation water applied to the drip treatment equaled 6.8 inches between Nov. 13 and Feb. 20th. During the same period, water applied in the sprinkler treatment equaled 9.1 inches. An additional 1.5 inches of rainfall were also measured during this period. Estimated evapotranspiration (ET) losses during establishment were 3.2 and 1.1 inches for the sprinkler and drip treatments, respectively. The lower estimated ET amount for drip was due to less wetting of the furrows than in the sprinkler treatment.
Figure 3. Irrigation water and rainfall for the drip and sprinkler treatments between Nov. 13 and Feb. 20th.
Soil moisture measured near the transplants was similar among the drip and sprinkler establishment treatments except for 4 dates between mid December and mid January when the sprinkler plot had higher soil moisture levels than the drip plot (Fig 4).
Figure 4. Volumetric soil moisture measured next to transplants for the drip and sprinkler treatments.
Bulk electrical conductivity (EC), an indirect measure of soil salinity, was slightly higher next to the drip established transplants than the sprinkler established transplants for 4 of 5 dates measured between December and early February (Fig. 4). Bulk EC values were generally low for both treatments, which was confirmed from the saturated paste extracts of soil sampled on January 24 2014 (3rd evaluation date). The EC of the saturated paste extract was 0.80 and 1.83 dS/m, respectively, for the sprinkler and drip established plots. Saturated pasted extract values below 2 dS/m would not be expected to harm strawberry plant growth. Plant vigor (Fig. 5) and canopy cover (Fig. 6) were not different between the sprinkler and drip establishment treatments. Likewise cumulative fruit yields (Fig. 7) were the same for the two methods of irrigation establishment.
Figure 5. Bulk electrical conductivity of the soil adjacent to strawberry transplants, measured using the Decagon 5TE probe.
Figure 6. Plant vigor of drip and sprinkler established transplants, where 0 equates to dead or dying plants, and 5 signifies all plants are very healthy.
Figure 7. Percentage of ground shaded by leaves, measured using a multi-spectral infra-red camera.
Figure 8. Cumulative marketable fruit yield for sprinkler and drip established plants.
Discussion and Conclusions
The results of this field trial demonstrated that drip can be successfully used to establish strawberry transplants during the winter on the Central Coast, even during drought conditions when rainfall is minimal. Marketable fruit yields were the same between the drip and sprinkler established plots. Additionally, 25% less water was used under drip than in the sprinkler plots during the initial establishment phase. Salinity was maintained at a sufficiently low level in the soil as to not impair transplant vigor and initial growth under drip.
Low water demand of plants during the late fall and early winter is an import factor that helped us successfully establish plants using drip. New transplants have few leaves and reference evapotranspiration, on average, is less than 0.07 inches per day. Since water demand is low, the main purpose of irrigation during establishment is to keep crown roots hydrated and to leach salts from the root zone. Using good planting techniques is critical to successfully using drip for establishment. Transplant roots need to be in contact with the soil and should not be “J” rooted. Also, soil salinity should be low as possible before planting. Preplant fertilizer bands should be located a sufficient distance from the transplant roots so that emerging new roots are not burned by fertilizer salts.
For this trial, we irrigated the drip treatment twice with overhead sprinklers to assure that the roots were in good contact with the soil. Under normal weather conditions on the Central Coast, rain often occurs between late November and February, which can also assist with the establishment of transplants by maintaining high soil moisture and leaching salts from the root zone of young plants.
Acknowledgements
We thank Dole and their employees for their help and partnership with this trial, and we thank Walmart for funding this project.
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- Author: Steven T. Koike
- Author: Jim Correll
Denomination of Pfs: 15, a new race of downy mildew in spinach
Jim Correll, Steven Koike, Diederik Smilde, Jan de Visser
A new race of the downy mildew pathogen (Peronospora farinosa f. sp. spinaciae) on spinach was first identified in November 2012 in Imperial Valley, CA, U.S. This race overcomes the resistance of several important varieties. The isolate was designated UA4712 and was characterized with a standard set of differential varieties. Subsequently, isolates with the same reaction pattern on the differential set have been found in numerous locations. After careful evaluation of the significance of this development to the spinach industry, the International Working Group on Peronospora farinosa (IWGP) has denominated isolate UA4712 as race Pfs: 15.
Race Pfs: 15 gives the same disease reactions as Pfs: 4 on the standard set of differentials, but is able to overcome the resistance of race 1-14 resistant varieties such as Caladonia (see chart below). Also, Whale is susceptible to Pfs: 15 whereas it is resistant to Pfs: 4. Although this is a new race, a number of commonly used resistances are effective on this race.
New races and deviating strains of the Pfs: pathogen continue to appear in many spinach growing areas of the world. The IWGP is continuously monitoring the appearance of strains of the pathogen that deviate in virulence from the known races. In this way the IWGP aims to promote a consistent and clear communication between public and private entities, such as the seed industry, growers, scientists, and other interested parties about all resistance-breaking races that are persistent enough to survive over several years, occur in a wide area, and cause a significant economic impact.
The IWGP is located in The Netherlands and is administered by Plantum NL. The IWGP consists of spinach seed company representatives (Pop Vriend, Monsanto, RijkZwaan, Nunhems, Takii, Sakata, Bejo, Enza, Syngenta, and Advanseed) and Naktuinbouw, and is supported by research centers at the University of Arkansas and the University of California Cooperative Extension (Monterey County) in the U.S. Researchers all over the world are invited to join the IWGP initiative and use the common host differential set to identify new isolates.
For more information on this subject you can contact Jim Correll (jcorrell@uark.edu), Steven Koike (stkoike@ucdavis.edu), Diederik Smilde (d.smilde@naktuinbouw.nl), or the IWGP chairperson Jan de Visser (JandeVisser@popvriendseeds.nl).
Disease reactions of race 15 (UA4712) observed on spinach differentials by the IWGP compiled July 2014.
aDisease reactions observed in controlled inoculation tests by 11 different participants of the IWGP.
“ + ” indicates susceptible disease reaction; “ - “ indicates resistant disease reaction.
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