Production - 223-Lowbush Blueberry Nutrition Series: N-P-K
Fact Sheet No. 223, UMaine Extension No. 2093
Prepared by Dr. John M. Smagula, Professor of Horticulture, in cooperation with Tom DeGomez, Extension Blueberry Specialist, The University of Maine, Orono, ME 04469. June 1987.
The lowbush blueberry is a slow growing woody plant. It spreads by means of an underground horizontal stem called a rhizome. The rhizome also serves as a storage organ for food reserves and nutrients, such as nitrogen. The rhizome and root system makes up about 70% of the mature plant; about 30% of the plant is seen as shoots above ground. Prior to pruning, most of the reserve food made in the shoots has been moved to the rhizome.
Growth of new shoots is dependent on stored food and nutrients and available nutrients in the soil. The roots that develop on the rhizome are not as fine as many other plants. In fact, all plants of the same family (Ericaceae) seem to lack these root hairs. Perhaps to compensate for the lack of root hairs, members of this family of acid-loving plants have fungi associated with their roots. The thread-like body of the fungi extends into the soil and serves to extract and move nutrients into plant roots.
Lowbush blueberries need a balance of nutrients to remain healthy and productive. Dr. Walter Kender grew lowbush blueberry plants without specific nutrients to determine their specific deficiency symptoms. The following is a list of nutrients with a description of their function in the plant and deficiency symptoms.
Nitrogen
Functions
Nitrogen (N) is one of the three “major” nutrients needed to support good plant growth. Plants use nitrogen to form amino acids needed in the formation of protein. Nitrogen is also required in the formation of chlorophyll. It governs, to a certain extent, the use of other nutrients and it encourages vegetative growth of the plant.
If nitrogen is applied in excess, a lack of magnesium (Mg) and calcium (Ca) might develop, and excessive vegetative growth may lead to increased winter injury and lower yields.
Deficiency Symptoms
Lack of adequate nitrogen reduces the formation of chlorophyll, which results in pale or yellow green leaves (chlorosis). The last green to disappear is along the midrib. Since nitrogen is “mobile,” the symptoms appear first in the older leaves. Reddish tints gradually appear at the leaf margins and spread toward the midrib or central vein. In advanced stages, all leaves develop a deep red coloration. Defoliation occurs in severe nitrogen shortage. Leaves are small and overall growth is markedly reduced.
Phosphorus
Functions
Phosphorous (P) is used to store and transfer energy within the plant. It is used in forming nucleic acids (DNA, RNA).
Phosphorous stimulates early growth and flowering, promotes fruiting and seed production, encourages root development and balances the effects of excess nitrogen. It also stimulates more vigorous plant growth. Young growing parts contain considerable amounts of phosphorous.
The efficiency of phosphorous uptake seems to increase in the presence of nitrogen.
Deficiency Symptoms
Deficiency symptoms for phosphorous are not as obvious as those of nitrogen. Growth is reduced and foliage is dark green and abnormally small. In advanced stages, large patches of purple appear in the interveinal areas.
Potassium
Functions
Potassium (K) remains in tissues in ionic form and is not used in the synthesis of new compounds as are nitrogen and phosphorous. Potassium is mobile in plants and tends to move from older to younger, more active growing tissue.
Potassium seems to be important in the formation of proteins, carbohydrates (sugar and starch), and chlorophyll. It is necessary for the translocation of sugars and the formation of starch. Potassium stimulates root growth and improves size and quality of fruit.
Deficiency Symptoms
Potassium deficiency symptoms first appear as interveinal chlorosis of the youngest leaves. In advanced stages, the leaf margins turn red and subsequently develop into a marginal leaf scorch (dry, dead tissue) starting at the tip of the leaf.
Nutrient Standards
Levels of nutrient concentrations have been reported by Trevett, and Lockhart & Langille (Table 1). These values will help you evaluate the nutritional status of the blueberry plants in your fields. If the concentrations of nutrients in you blueberry leaf samples are below the satisfactory level, you should refer to Wild Blueberry Fact Sheet No. 222 “Lowbush Blueberry Nutrition Series – Leaf and Soil Sampling Procedures.”
| Foliar Nutrient Levels of Lowbush Blueberries* Standard Range |
||||
| Element | Trevett | Lockhart & Langille | ||
| MIN | MAX | MIN | MAX | |
| Nitrogen (N) | 1.60% | 2.00% | 1.84% | 2.38% |
| Phosphorous (P) | 0.125% | 0.222% | 0.133% | 0.184% |
| Potassium (K) | 0.40% | 0.90% | 0.54% | 0.74% |
| Calcium (Ca) | 0.27% | 0.52% | 0.37% | 0.49% |
| Magnesium (Mg) | 0.13% | 0.25% | 0.12% | 0.15% |
| Boron (B) | 24 ppm | 60 ppm | 13.60 ppm | 22.20 ppm |
| Iron (Fe) | 50 ppm | 100 ppm | 39 ppm | 59 ppm |
| Manganese (Mn) | 750 ppm | 1490 ppm | 1479 ppm | 2394 ppm |
| Zinc (Zn) | 25 ppm | 50 ppm | 22 ppm | 41 ppm |
| Copper (Cu) | 7 ppm | 14 ppm | 6.40 ppm | 9.20 ppm |
| Molybdenum (Mo) | 1.20 ppm | 3.30 ppm | 0.33 ppm | 0.17 ppm |
| Aluminum (Al) | 50 ppm | 75 ppm | 73 ppm | 127 ppm |
| Sources: Trevett, 1972 and Lockhart & Langille, 1962. * Vaccinium angustifolium | ||||
Information in this publication is provided purely for educational purposes. No responsibility is assumed for any problems associated with the use of products or services mentioned. No endorsement of products or companies is intended, nor is criticism of unnamed products or companies implied.
©1987
Published and distributed in furtherance of Acts of Congress of May 8 and June 30, 1914, by the University of Maine Cooperative Extension, the Land Grant University of the state of Maine and the U.S. Department of Agriculture cooperating. Cooperative Extension and other agencies of the U.S.D.A. provide equal opportunities in programs and employment.
Call 800-287-0274 or TDD 800-287-8957 (in Maine), or 207-581-3188, for information on publications and program offerings from University of Maine Cooperative Extension, or visit extension.umaine.edu.
Print This Page