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Seed and Seed Quality


Seeds are the foundation of agriculture. Technology has modernized much of farming’s day-to-day operations, but without a steady supply of high-quality seed, yields and crop quality would be greatly decreased.

Seed quality plays an important role in the production of agronomic and horticultural crops. Characteristics such as trueness to variety, germination percentage, purity, vigor, and appearance are important to farmers planting crops and to homeowners establishing lawns and gardens. Achieving and maintaining high seed quality is the goal of every professional seed producer.

This publication presents basic facts about seed, seed quality, and seed laws. This information can help seed producers, farmers, and homeowners understand the important role that seed plays in producing superior crops, landscape plants, and lawns.

Seed Development and Structure

Seed Development

The process of seed development begins within the flower, the plant’s reproductive structure. The flower is a modified leaf structure and can be both male and female. The female part is the pistil, and the male part is the stamen. One flower may contain the pistil and stamen, as in beans, or they may occur in different flowers, as in corn.

A typical flower and its parts are illustrated in Figure 1. The pistil has a top portion (stigma), a middle portion (style), and a lower portion (ovary). The ovary may contain one or more ovules. The surface of the stigma produces a sweet, sticky solution as it becomes receptive to pollen fertilization.

Pollen is produced in the anthers at the ends of the stamen. Pollination occurs when pollen grains come into contact with the stigma. Wind and insects are largely responsible for the transfer of pollen from the anthers to the stigmas. Methods of transfer differ from one species to another.

If conditions are favorable, pollen grains begin to grow on the stigma surface and form pollen tubes. The pollen tube grows down the style and into the ovary, where it comes into contact with the ovule. Male gametes are transferred through the pollen tube into the ovule. Fertilization occurs when the male gametes unite with the female egg in the ovule. After pollination and fertilization, ovules develop into seeds.

In self-pollinated plants, pollen produced within each flower pollinates the stigma of the same flower. Cotton, barley, wheat, oats, tobacco, soybeans, okra, peanuts, and peppers are examples of self-pollinated crops. In cross-pollinated plants, the pollen grains pollinate flowers other than the one from which they originated. Examples include corn, rye, tall fescue, alfalfa, carrots, cucumbers, squash, and onions.

Fertilization occurs shortly after pollination and begins the process of seed development. Early stages in the development of strong plants depend on favorable growing conditions. Seed quality, on the other hand, is largely dependent upon environmental conditions and the promptness with which the seed is harvested after it matures.

Effects of Pollination Type on Varietal Purity

Varietal purity is heavily influenced by the type of pollination. Self-pollinated plants need be only a few feet apart to prevent the pollen of one plant from pollinating nearby plants of another variety. Cross-pollinated species, on the other hand, may need to be separated by several hundred feet to isolate them from plants of different varieties.

In self-pollinated crops, stray pollen from an off-type plant can pollinate flowers on several other plants, thus reducing varietal purity. Off-type plants should be removed before pollination occurs. In cross pollination, pollen is moved long distances. Thus, a single off-type plant in a seed field can pollinate flowers on hundreds of other plants.

Varietal purity is not easily achieved. It requires timely and careful roguing (removal) of off-type plants. Seed certification agencies and seed breeding companies use field inspection programs to maintain varietal purity.

Seed Structures

Knowledge of seed structure can help in understanding how seeds respond during harvesting, conditioning, germination, and seedling emergence.

Seed can be divided into two major classifications, monocots (monocotyledons) and dicots (dicotyledons), based on the number of cotyledons (seed leaves) in a seed. Monocots contain one cotyledon, whereas dicots have two.

Examples of plant species having monocot seeds are grasses–such as small grains, corn, or turfgrasses–and other crops such as onions. Plants with dicot seeds include legumes–such as peas, peanuts, soybeans, and clover–and other crops such as cotton and tobacco.

Seeds are composed of three basic structures: (1) the seed covering (seed coat or testa); (2) the embryonic axis (embryonic root or radicle and shoot or plumule); and (3) supporting tissues (the cotyledons and endosperm). The structures for monocots and dicots are illustrated in Figure 2.

If unbroken, the seed coat regulates water uptake by mature seeds. Variations in seed covering characteristics, especially in dicots, often affect the quality of seed when exposed to adverse weather. Some seeds, such as peanuts, have an extremely soft and delicate seed covering. This covering can easily break or slip and expose the embryo, making it susceptible to injury, deterioration, and pathogen attack.

Other seeds have extremely hard coverings that protect the seed from almost everything. Common weeds such as puncturevine, dock, knotweed, and pigweed are examples of these tough seeds. It is no wonder that most common weeds survive so long scattered across the land or buried in the soil. Lotus seeds have survived for many hundreds of years because of their tough, hard covering.

The embryonic axis normally includes the miniature plant, consisting of the root and shoot. Cotyledons and endosperm are usually considered supporting tissues. They are useful to the developing plant as a reserve food source through the course of germination and emergence until the plant can make its own food through photosynthesis. Supporting tissues in monocots are composed mostly of nonliving, starchy materials, whereas such tissues in dicots are composed of mostly fats and oils.

The location of seed structures plays an important role in determining the seeds’ susceptibility to mechanical injuries and weather damage. The embryonic axis is often just below the seed covering. Impacts to the embryonic axis can cause severe damage, resulting in abnormal seedlings or death of the seed. Peanut and soybean seeds can be damaged easily.

Figure 1.

Figure 1. A typical flower. It may contain both the pistil (female) and stamen (male). Many flowers contain only one pistil but usually several stamens.

Figure 1. A typical flower. It may contain both the pistil (female) and stamen (male). Many flowers contain only one pistil but usually several stamens.

Figure 1.

Figure 2.

Figure 2. The major botanical structures of monocotyledonous (for example, corn) and dicotyledonous (for example, soybeans) types of seed.

Figure 2. The major botanical structures of monocotyledonous (for example, corn) and dicotyledonous (for example, soybeans) types of seed.

Figure 2.

Sizes and Shapes of Seeds

Seeds come in many sizes and shapes. They range in size from the micro-miniature orchid seed, as small as a particle of dust, to the gargantuan double coconut seed, over 1 foot long and weighing many pounds. Shapes vary from the simple, round tobacco seed to the complex, aerodynamic, winged maple seed. Some seeds are hairy, such as the cotton or thistle. Others, like grass, have long spikes. Some have thorns.

Dispersal Mechanisms

The dispersal mechanisms of seeds range from the simple dropping of the seed from the parent plant onto the ground to the more exotic ways such as scattering by wind or “shooting” from the plant. The tumbleweed scatters its seeds in the wind as it rolls along the ground. Light, puffy seeds like those of the thistle and dandelion and winged seeds like those of the maple and pine can ride the wind for great distances. Some seeds, such as the cocklebur, hitch rides on passing animals. Among the most exotic dispersal mechanisms are the “shooting” seeds of plants such as mistletoe or touch-me-not that are “spring loaded” and flung from the parent plant into the air.

For seeds used in farming and landscaping, the primary dispersal mechanism is the planter. This mechanism can be very simple such as the primitive dibble stick used to scratch open a furrow or poke a seed hole into the soil. At the opposite extreme is the modem mechanized planter that plants four or more neatly aligned rows at one time.

Chemical Composition of Seed

Like all living organisms, seeds are composed of many different types of chemicals, but seeds are unique in that they are a storehouse of chemicals that are used as food reserves for the next generation plant. These chemical foods also serve as a significant part of our food supply.

Seeds store three major classes of chemical compounds: carbohydrates (sugars), lipids (fats and oils), and proteins. The quantities of these compounds stored in seeds vary with the type of seed, as shown in Table 1.

Seed chemicals can be very useful. Certain seed oils are particularly well suited to cooking. A prime example is peanut oil, highly prized as one of the best cooking oils. Others are particularly well suited to lubrication. Seeds of the jojoba (a little known but very useful desert plant from the American Southwest) contain an oil that has lubricating properties as good as those of the finest sperm whale oil. Seed oils are used to make soap, paint, printing inks, and other industrial supplies.

In the case of proteins, seeds may not have the ideal composition in terms of human nutritional needs. Proteins are made up of long chains of amino acids. Some seeds do not have the optimum quantities of amino acids for human nutrition. For example, corn proteins are generally low in the amino acid lysine but relatively high in the amino acid methionine. In contrast, soybean proteins are relatively high in lysine but somewhat low in methionine. When corn and soybean seeds are used together, a nutritionally satisfactory balance can be obtained.

Most seeds are not high in protein but are high in carbohydrates or lipids. Soybean (high in protein and relatively high in lipids) is the exception rather than the rule. The seeds of most plants store their food reserves mainly in the form of carbohydrates or lipids.

Through careful breeding and selection, the levels of seed storage reserves can be modified. In this age of biotechnology, it may be possible to breed a “designer” seed plant with the correct levels of carbohydrate, lipids, and protein to meet human nutritional and industrial needs.

Table 1. Approximate Chemical Composition of Various Kinds of Seed.
Kind of Seed % Carbohydrate % Lipid % Protein
Barley 76 2 9
Bean 56 1 23
Corn 62 5 10
Oat 66 5 12
Pea 40 2 20
Peanut 23 45 25
Soybean 17 20 40
Wheat 67 2 13

Germination and Field Emergence

The following definitions will help in understanding seed germination and seedling emergence:

  • Germination is the emergence from the seed and development of those essential structures that under favorable conditions produce a normal plant. Germination is more than just the protrusion of the root or shoot from the seed covering. It is important that all of the seedling structures necessary for continuation of the next generation be present and healthy.
  • Field Emergence is the elongation of the seedling axis resulting in protrusion of the seedling shoot from the soil.
  • Viability is the potential to germinate. A nonviable seed will not germinate under any conditions. Viable and a nonviable seeds may look exactly the same.
  • Dormancy is the state of nongermination in viable seed. During this period, germination is blocked by conditions within the seed. Dormant seeds are often thought of as being in a resting state. Dormancy is broken when the seed is exposed to specific conditions. The condition may simply be the passage of time, or it may be the removal or breaking of the seed coverings, a cold overwintering, or the effects of light or hormones supplied to the seed. Minor and subtle changes in the physical or chemical properties of the seed are usually required to break dormancy. A seed may take up water and look fully able to germinate but, because other necessary conditions are not present, may fail to germinate.

Various seed characteristics result in different germination and seedling emergence patterns.


Requirements for initiation of germination include:

  • a favorable moisture level in the seed;
  • a favorable temperature in the environment around the seed;
  • a favorable oxygen supply to the seed.

Note that favorable conditions must be present. Some seeds may require specific light conditions. Also, the seed’s dormancy must be broken for germination to proceed.

Germination occurs in several steps. The first is the absorption of water. Water begins certain biochemical processes within seed that accelerate cell activities. The minimum moisture level at which germination begins is known as the critical moisture level.

Critical moisture levels vary among crop seed. Most starchy seeds (monocots) will begin germination when they have a moisture content of approximately 30 percent. Most oily seeds (dicots), however, will not begin germination until they have a moisture content of at least 50 percent.

Germination will not occur above or below the critical temperatures. Each species has a minimum, an optimum, and a maximum temperature for seed germination. Most species have a minimum germination temperature of approximately 55°F (13°C) and a maximum germination temperature of approximately 110°F (43°C). The optimum temperature is usually from 75 to 85°F (24 to 30°C).

Seeds of plants such as beets, corn, cotton, okra, peppers, soybeans, and turnips sometimes germinate better with alternating temperatures than at a constant temperature. Favorable alternating temperatures for the seed of a given crop tend to follow the average day-to-night temperatures during the planting season.

Lack of oxygen is not usually a limiting factor for germination. However, wet or soggy soils may not contain enough oxygen for germination to begin. Seeds planted in such soils will absorb water quickly and have a tendency to decay.

Most agricultural seeds germinate equally well with or without light. However, many seeds such as those of tobacco, lettuce, and many types of grass, will germinate best in light. In contrast, onion seeds germinate best in darkness.

The internal conditions of seed, such as soundness and vigor, as well as the environment, affect the rate of germination. Seed vigor can be affected by maturity, age, mechanical injuries, disease infection, preharvest weather, and storage environment.

Adverse weather conditions after planting regularly influence the germination processes by affecting moisture, temperature, and oxygen levels. Weather patterns sometimes make early spring or late fall planting extremely risky.

Once cell activity is initiated, the root is the first structure to emerge from the seed coat. Root growth is a result of both cell division and elongation. Hypocotyl growth is mainly a result of cell elongation. Shortly after root growth begins, the shoot meristem emerges from the seed coat and continues development by cell division and elongation.

Field Emergence

Different species exhibit different seedling emergence patterns. The emergence patterns of soybean, pea, and corn seedlings are shown in Figure 3, Figure 4, and Figure 5. The illustrations represent three basic emergence patterns for agricultural seeds.

In soybeans and other crops such as cotton, clovers, squash, and radishes, root growth occurs by cell division and enlargement of the root (Figure 3a). As growth continues, the hypocotyl elongates by cell enlargement, and the midsection emerges from the soil (Figure 3b). The seed coat usually remains below ground. As the bent hypocotyl elongates, it gradually pulls the cotyledons above ground (Figure 3c). During the critical stage when the hypocotyl is still arched above ground and is pulling the cotyledons upward, damage to the hypocotyl can easily prevent seedling emergence.

Figure 4 shows the emergence pattern for peas. Elongation of the root and plumule occurs almost simultaneously (Figure 4a). The cotyledons and the seed coat remain below ground at planting depth, and the epicotyl advances upward through the soil (Figure 4b). When seedling emergence follows this pattern, a weakness in the epicotyl may cause emergence failure. Other crops with a similar emergence pattern include vetches and peanuts. Peanut cotyledons, however, tend to advance toward the soil surface but usually remain slightly below it.

The emergence pattern of corn is illustrated in Figure 5. Most monocots have this kind of emergence pattern. The elongation of the root and the coleoptile (penetrating organ) occurs almost simultaneously (Figures 5a and 5b). The seed remains underground at planting depth, and once the coleoptile (which is pointed like a pin) emerges above ground, it stops growing. The plumule continues to develop and grow upward through the coleoptile (Figure 5c). In this emergence pattern, a weakness in the coleoptile can cause emergence failure.

Figure 3.

Figure 3. Field emergence pattern of soybean seedlings.

Figure 3. Field emergence pattern of soybean seedlings.

Figure 3.

Figure 4. Field emergence pattern of pea seedlings.

Figure 4. Field emergence pattern of pea seedlings.

Figure 5.

Figure 5. Field emergence pattern of corn seedlings.

Figure 5. Field emergence pattern of corn seedlings.

Figure 5.

Seed Germination Tests

One of the official statutory test required for labeling purposes is the standard germination test. The rules for conducting this test are established by the Association of Official Seed Analysts (AOSA) and set forth in a handbook entitled Rules for Testing Seed. Most seed testing laboratories follow these rules. The AOSA has also set standards and procedures for the use of the tetrazolium test as an estimate of viability and germination.

The standard germination test measures the number of normal seedlings produced by a sample of seed under optimal conditions. Germination is reported as the percentage of seed producing normal seedlings. Normal seedlings are those that produce a vigorous set of primary and secondary roots; have a healthy hypocotyl, epicotyl, and cotyledon; and produce a healthy shoot meristem. Abnormal seedlings are considered nongerminative in the Standard Germination Test, and would not be counted in the total percent germination for that sample. See Figure 6.

Some seed producers use tetrazolium, cold test, growth rate, or some other testing technique to estimate seed vigor. These tests are designed to evaluate the seed’s ability to germinate and grow under less than favorable conditions.

Figure 6.

Figure 6. Corn seedlings with (a) normal seedling structures (that is, healthy shoot and root), (b) abnormal root structure, and (c) abnormal shoot structure.

Figure 6. Corn seedlings with (a) normal seedling structures (that is, healthy shoot and root), (b) abnormal root structure, and (c) abnormal shoot structure.

Figure 6.

Seed Vigor

Seed vigor is the property that gives seed the potential for rapid and uniform emergence and development of normal seedlings under a wide range of field conditions. Tests for vigor go beyond the germination tests conducted under controlled, favorable conditions in the laboratory to predict seed performance under practical conditions that may be encountered when the seed is planted in the field.

The concept of seed vigor has recently been officially defined and accepted as a testing guideline for seed. The standard germination test, in contrast, has been in use for many years. Although vigor testing is not required by law for labeling of seed, many seed producers use vigor tests as a quality control to ensure that the seed produced is of high quality.

Many factors, such as maturity level at harvest, age of the seed, mechanical injuries, disease infection, and storage environment, can influence seed vigor. Genetic factors also influence vigor.

Effects of Seed Vigor on Seedling Development and Field Emergence

If two lots of seed have the same germination percentage but one is of high vigor and the other is of low vigor, a difference in the germination speed, seedling growth, Or emergence can be seen. For example, gemination test results on two peanut seed lots were 99 percent (lot A) and 98 percent (lot B). In the field, seed lot A had a 98 percent emergence, whereas seed lot B had an emergence of only 60 percent. Underfavorable germination conditions, the two lots have only a small difference in speed of germination (Figure 7). Under unfavorable (cool) conditions, the two lots have a great difference in the speed of germination, a result of their difference in seed vigor (Figure 8).

Figure 7.

Figure 7. Speed of germination in laboratory vigor testing of two comparable peanut seed lots under favorable conditions.

Figure 7. Speed of germination in laboratory vigor testing of two comparable peanut seed lots under favorable conditions.

Figure 7.

Figure 8.

Figure 8. Speed of germination in laboratory vigor testing of two comparable peanut seed lots under unfavorable (low temperature) conditions showing the difference due to seed vigor.

Figure 8. Speed of germination in laboratory vigor testing of two comparable peanut seed lots under unfavorable (low temperature) conditions showing the difference due to seed vigor.

Figure 8.

Seed Quality

Quality Characteristics

Seed quality describes the potential performance of a seed lot. Trueness to variety; the presence of inert matter, seed of other crops, or weed seed; germination percentage; vigor; appearance; and freedom from disease are important aspects of seed quality. High-quality seed lots should meet minimum standards for each of these characteristics. The standards of official certification agencies are usually accepted as the minimum requirements for high-quality seed. (For information on standards, see the Certification Handbook published by the North Carolina Crop Improvement Association.)

Trueness to variety indicates that the seeds in a bag are of the variety stated on the label. Trueness is usually determined by records of seed sources and by field inspections of the plants that produce the seed. Field inspections are conducted by certification agencies or representatives of commercial seed companies.

Germination potential and vigor are at their highest potential when the seed reaches physiological maturity. But because seed moisture is so high, most crops are not ready to be harvested at that time. It is important that seed be harvested as soon as the moisture content decreases to a safe level (see Table 2). After maturity, germination potential and vigor begin to deteriorate.

The rate of deterioration depends on the weather during maturation and on harvesting, conditioning, and storage practices. Seed can deteriorate rapidly if excessive damage occurs during harvesting and conditioning (see Figure 9). Harvesting crops at the proper moisture content and keeping equipment adjusted will minimize mechanical injury to seed.

Seed moisture levels for harvesting and conditioning are slightly higher than those recommended for safe storage (Table 2). Seed storage conditions, which can also greatly affect deterioration rates, is discussed in more detail in a later section.

The quality of a seed lot can be improved by conditioning. Conditioning is used mainly to eliminate or reduce undesirable contaminants such as diseased and immature crop seed, weed seed, inert matter, broken or split seed, or other crop seed. In some crops, conditioning includes the addition of chemical seed treatment.

Table 2. Safe Harvest and Storage Moisture for Seed Crops Common to North Carolina.
Crop Species Harvest Moisture (%) Storage Moisture (%)
Soybean 12 to 14 8 to 10
Wheat, Barley 10 to 14 8 to 10
Peanut 20 to 25 (combine) 8 to 9

Figure 9.

Figure 9: Soybean seed: (a) healthy and sound, (b) immature and weathered, and (c) cracked coats caused by mechanical impacts.

Figure 9: Soybean seed: (a) healthy and sound, (b) immature and weathered, and (c) cracked coats caused by mechanical impacts.

Figure 9.

Chemical Seed Treatment

Pathogens (organisms that cause disease) are often present on or in the seed or in the soil. These organisms can cause diseases that destroy the seed or seedling. Chemicals applied to the seed can prevent or reduce the harmful attacks of many pathogens. These treatments include fungicides, insecticides, and, occasionally, antibiotics.

Fungicides are chemicals that are normally used to combat seed rots, surface molds, and seedling blights caused by seed- and soil-borne organisms. The ideal fungicide should be highly effective in controlling a specific disease organism. Insecticides are used to protect the seed from soil-borne insects and storage insects. Some treatments combine a fungicide with an insecticide to protect the seed against soil insects and disease organisms. The chemicals used should be harmless to seed, stable for long periods of time, easy to use, and low in toxicity to people and animals.

Systemic treatments are absorbed by the seed or developing seedling. These treatments protect both the seed and the young plants against diseases. For example, Baytan, a seed treatment that became commercially available in 1990, protects wheat, barley, and oat plants from many foliar diseases (including powdery mildew and rust) for up to eight weeks after seedling emergence.

Treatment chemicals are formulated as dusts, wettable powders, or liquids. The most important part of seed treatment is selecting the proper kind and form for a specific crop. A critical problem is obtaining uniform and adequate chemical coverage on each seed. Undertreatment is ineffective and overtreatment may injure the seed; therefore, accurate metering devices are necessary to dispense the proper amount of chemicals to a given quantity of seed. Many treatments are added by seed conditioners. However, several “hopper box” treatments are designed for easy on-farm use.

If you are interested in treating specific crops, refer to the current North Carolina Agricultural Chemicals Manual for recommendations on rates and treatments. County Extension Service agents and other agricultural leaders can also recommend treatment methods.

Containers of treated seed must bear a special label stating the treatment compound used and a warning about its dangers (see Figure 12). The law also requires chemically treated seeds to be dyed a bright color. If treated seeds are not planted, they should be disposed of as hazardous waste. (Consult federal and state seed laws for specific requirements.)

Certified Seed

The North Carolina Crop Improvement Association (NCCIA) is legally responsible for seed certification in North Carolina and is the official seed certifying agency. The NCCIA, founded in 1929, establishes and administers the standards for certification. It also inspects and supervises the production, conditioning, and marketing of certified seed under those standards.

The basic purpose of the production and sale of certified seed is to make genetically pure crop seed available to farmers. Genetic purity, or trueness to variety, is established and maintained by special purification and seed increase programs, by field and seed inspections, and by pedigreed records. Genetic purity is largely determined by production records and field inspections.

Certified-1 and Certified-2 are the categories of certified seed. Both categories meet the same high standards for genetic purity, but they differ in quality standards such as gemination percentage. Certified- 1 must meet higher standards. A purchaser of certified seed normally receives a bonus because certified seed usually has a higher germination percentage, lower inert matter, virtually no weed seed, and a very low percentage of seed from other crops as compared to uncertified seed.

Classes of Certified Seed

The classes of seed in the certification program are breeder, foundation, registered, and certified. The process of increasing seed from the plant breeder’s program to “blue label” certified seed is referred to as the seed chain, as shown in Figure 10. Supplies of breeder seed are usually maintained by the originator of the variety. Most often, the amount of a given variety available usually does not exceed a few pounds or bushels. Seed of new varieties must be made available to farmers for use in their farming programs, and pure seed stocks of older but satisfactory varieties must be maintained. Certification offers a program of planned production, whereby desirable varietal and seed purity is maintained for a rapidly changing list of superior varieties.

Breeder seed developed by public plant breeders is supplied to the North Carolina Foundation Seed Producers (NCFSP) for increase to produce foundation seed. The NCFSP increases the limited amounts of breeder seed available for each variety and makes the resulting foundation seed available to producers of registered or certified seed. The production of foundation seed is a highly specialized and closely supervised operation. Foundation seed lots do not normally enter routine trade channels. A white label with “Foundation Seed” boldly printed on it identifies foundation seed. A sample tag is shown in Figure 10a.

Private seed companies that develop new varieties normally maintain their own breeder and foundation seed programs. Where certification is involved, these seeds are inspected by certification officials and must meet the same standards as seed varieties developed by public agencies.

Seed produced from foundation seed is identified as registered, provided that it meets published standards of quality. Producers of registered seed are also highly specialized and must have considerable experience in seed production. In many crops, the registered seed producer must own certain conditioning equipment. Registered seed is identified by a purple seed label (Figure 10b).

Either registered or foundation seed can be used for production of certified seed. Certified seed is produced under strict varietal purity standards and identified with a blue seed label (Figure 10c). A limited-generation plan assures that certified seed is no more than three generations from breeder seed. Because of this plan, certified seed is not eligible for recertification. After extensive field and laboratory inspection, this seed enters the normal channels of trade and is used by most leading farmers throughout North Carolina. Its genetic purity and high quality make certified seed the standard of excellence by which all seeds are judged.

Membership in the NCCIA is open to qualified people or firms who want to grow certified seed. Members accept an obligation to uphold the high standards of certified seed and agree to abide by the rules and regulations of the NCCIA.

NCCIA offices are located on the North Carolina State University campus in Raleigh. Sources of Certified Seed, published annually by the NCCTA, lists seed growers and the varieties they produce. This booklet can be very useful to seed dealers and agricultural workers in locating sources of certified seed. Copies of Sources of Certified Seed can be obtained from the NCCIA, 3709 Hillsborough Street, Raleigh, NC, 27607-5499.

Figure 10.

Figure 10: This seed chain shows the seed labels that identify each class of seed.

Figure 10: This seed chain shows the seed labels that identify each class of seed.

Figure 10.

The North Carolina Seed Law and the Seed Analysis Label

The North Carolina Seed Law regulates the labeling of seed offered for sale. The basic purpose of the law is to prevent misrepresentation of the contents of a seed container. The seed law may be thought of as a “truth in labeling” law.

Seed Law and Regulations

A seed dealer should have a current copy of the North Carolina Seed Law and a copy of Title 2, Subchapter 48C (“Seeds”) of the North Carolina Administrative Code. These booklets will answer most questions relating to the North Carolina Seed Law and seed labeling. Copies can be obtained from the Seed Section, Plant Industry Division, North Carolina Department of Agriculture, PO Box 27647, Raleigh, NC 27611-7647.

Seed offered for sale must meet certain minimum standards. For example, the minimum germination percentage for most crop seed and lawn and turfseed is 70 percent. Exceptions to this standard can be found in the current seed law regulations. Germination standards for vegetable seed vary considerably. These standards can also be found in Subchapter 48C.

Seed lots that contain more than 1 percent weed seed are prohibited from sale in North Carolina. Certain weeds are classified as noxious and are prohibited or restricted in seed offered for sale. A list of noxious weeds is given in Table 3.

The seed law does not limit the percentage of other crop seed that is contained in a bag of seed. Each land of crop seed or variety, however, that exceeds 5 percent of the total must be stated on the analysis label, and the pure seed and germination percentages of each must be given. Such seed lots are identified as “mixtures.” Inert matter percentage must be stated on the label but is not limited by the seed law.

The seed law requires truthful labeling as to the contents of a container of seed. However, adherence to the seed law does not guarantee that seeds are of high quality, only that they meet the claims on the analysis label.

Seed inspectors from the North Carolina Department of Agriculture & Consumer Services visit seed stores to ensure that seed is adequately and truthfully labeled. Stop-sale notices are issued for seed found to be in violation. A stop-sale notice prevents sale until the deficiencies are corrected through relabeling or reconditioning. If the seed is not brought up to standard, it is ordered removed from sale. To determine quality violations, the inspector takes a representative sample from the seed lot. This official sample is analyzed by the North Carolina Department of Agriculture & Consumer Services Seed Lab to determine if the entire seed lot meets label claims and is in compliance with the law.

The seed inspector can be a valuable source of information for the dealer in keeping up to date on seed law changes and requirements. A common effort by the dealer and the inspector will provide the best seed.

Table 3. Prohibited and restricted noxious weeds of North Carolina.
Prohibited (none allowed)
Balloonvine (Cardiospermum halicacabum)
Crotalaria, Showy (Crotalaria spectabilis)
Crotalaria, Smooth (Crotalaria pallida)
Itchgrass (Rottboellia cochinchinensis)
Jimsonweed (Datura stramonium)
Johnsongrass (Sorghum halepense)
Serrated Tussock (Nassella trichotoma)
Witchweed (Striga asiatica)
Restricted (limited allowance) NC Seed Law maxiumum per pound of seed
Anoda, Spurred (Anoda cristata) 4
Bermudagrass (Cynodon dactylon) 27
Bindweed, Field (Convolvulus arvensis) 27
Bindweed, Hedge (Calystegia sepium) 27
Cocklebur (Xanthium spp.) 4
Corncockle (Agrostemma githago) 10
Cornflower [Ragged Robin] (Centaurea cyanus) 27
Dock, Broadleaf (Rumex obtusifolius) 54
Dock, Curly (Rumex crispus) 54
Dodder (Cuscuta spp.) 54
Foxtail, Giant (Setaria faberi) 54
Garlic, Wild (Allium spp.)
Small Grains or larger seeds
Grasses and small seeded legumes
4 bulblets
27 bulblets
Horsenettle (Solanum carolinense) 54
Moringglory (Ipomoea spp.) 8
Mustard, Wild (Brassica spp.) 54
Nutsedge, Purple (Cyperus rotendus) 2 tubers or 27 seeds
Nutsedge, Yellow (Cyperus esculentus) 2 tubers or 27 seeds
Onion, Wild (Allium spp.)
Small Grains or larger seeds
Grasses and small seeded legumes
4 bulblets
27 bulblets
Panicum, Texas (Panicum texanum) 27
Plantain, Bracted (Plantago aristata) 54
Plantain, Buckhorn (Plantago lanceolata) 54
Quackgrass (Elytrigia repens) 54
Radish, Wild (Raphanus raphanistrum) 12
Sandbur (Cenchrus spp.) 4
Sicklepod (Cassia obtusifolia) 4
Thistle, Blessed (Cnicus benedictus) 4
Thistle, Canada (Cirsium arvense) 27
Velvetleaf (Abutilon theophrasti) 4

Seed Analysis Labels

As previously discussed, the seed law requires containers of seed offered for sale to be properly labeled. An example of an acceptable label format is shown in Figure 11.

For most crop seed, the law requires that the analysis label contain the following information:

  • kind and variety
  • pure seed percentage
  • lot number
  • net weight
  • origin
  • inert matter percentage
  • other crop seed percentage
  • weed seed percentage
  • germination percentage for each kind and/or variety of seed
  • hard seed percentage
  • month and year of germination test
  • name and number per pound of restricted noxious weed seed
  • the name and address of the individual or company labeling the seed (the vendor).

Such information should be based on the germination and purity analysis testing of a representative sample taken from the seed lot. Vendors must keep a file sample and a complete record of seed that includes invoices showing lot number, kind and variety, origin, germination, purity, treatment, and the labeling of each lot for two years.

Analysis label information is very useful to purchasers. Let us examine each statement and see how it can help in buying seed. (Refer to the seed analysis label in Figure 11.)

Lot Number: This number allows the seed producer to identify a specific lot from which the seed was taken in case of performance problems. The term lot means a definite quantity of seed, identified by a lot number or other identification, that is uniform throughout for the factors that appear on the label.

Net Weight: The weight given is that of the contents without the container.

Kind and Variety: The kind of crop refers to the species (for example, wheat, cotton, and tobacco) and is always given on the seed label. The variety may or may not be stated. Under this definition, a hybrid name is acceptable as a variety name. If the variety is not given, the seed tag normally has the statement, “Variety not stated.” When two or more components are named, the word “mixture” or “mixed” must appear on the label.

Origin: This label entry identifies the state or country in which the seed was grown. If the origin is unknown, a statement “origin unknown” must appear on the label.

Pure Seed: This number tells what percentage of the total weight consists of seed of the kind and variety stated. If more than one kind or variety is named, the pure seed percentage of each component must be given. Generally, farmers choose seed with a high pure seed percentage (98 percent or more) and of one kind and variety.

Inert Matter: This number indicates the percentage of extraneous material such as dirt, stems, leaves, and seed parts in the seed lot. Inert matter reduces the value of seed. It is best to choose seed with less than 2 percent inert matter. The standards for certification and state seed law requirements for labeling differ for some crop species. An inert matter percentage is not required for cotton, peanut, or tobacco seed in North Carolina.

Other Crop Seed: This number indicates the percentage of the total weight made up of seed from a crop other than the kind and variety listed. In the field, other crop plants, such as corn in soybeans, may be as troublesome as weedy plants. High-quality seed should contain no seed from other crops or only a low percentage.

Weed Seed: The presence of weed seed is expressed as a percentage of total weight. This classification includes seed, bulblets, or tubers of plants recognized as common weeds by official regulations or by general agreement. High-quality seed should contain only a very low percentage or no weed seed.

Germination: The percentage of pure seed that germinates in a standard germination test is printed on the analysis label. This percentage is based on the number of seeds that produced normal seedlings during the test. A normal seedling is one that has the essential seed structures necessary for plant survival. Germination percentage is based on pure seed and not on the total contents of the bag. If more than one kind and variety is named, the germination percentage must be shown for each kind and variety. Choose seed that is high in germination (80 percent or more).

Hard Seed: This number indicates the percentage of seed that remains hard during the germination test. It is assumed that most hard seed will germinate, but that is not necessarily the case. Hard seededness is a characteristic of certain species (especially legumes) and is caused by water-impermeable seed coats. Where hard seeds are present, total germination percentages are customarily determined by combining germination and hard seed percentages.

Test Date: This date reveals the month and year in which the germination test was completed. The law requires that the germination test be made within nine months (not counting the month of the test) of the date the seed is offered for sale. For vegetable seed in hermetically sealed containers, tests are required every 24 months, not counting the month tested. Be sure to purchase seed with a current germination test date.

The law also requires the individual or company owning the seed to maintain a current germination test date. Therefore, dealers with carryover seed should have their seed retested and relabeled before the test date expires.

Noxious Weed Seed: Noxious weeds are plants that are extremely difficult to control with normal cultural practices. A noxious weed seed list has been established by the North Carolina Board of Agriculture. The name and number of restricted noxious weed seeds, bulblets, or tubers per pound of crop seed must be printed on the seed label.

In North Carolina, the noxious weed seed list includes prohibited and restricted noxious weeds. Seed containing any seed or tubers of prohibited noxious weed seed cannot legally be sold in the state. Restricted noxious weed seeds are permitted in crop seed, but the number of weed seed permitted per pound of crop seed is limited. Noxious weed seed and their limitations in crop seed are listed in Table 3. High-quality seed contains no noxious weed seed.

Seedsman or Vendor: The name and address of the person or company labeling the seed are given on the seed label. They are responsible for the accuracy of the label’s information.

Treated Seed: All seed that is treated with chemicals must be labeled to show the chemical used. Either “Caution,” “Poison,” or “Poison Treated” must be written on the label, depending on the harmfulness of the seed treatment to humans. The statement “Do not use for food, feed, or oil purposes” is printed on labels for treated seed (Figure 12). Chemically treated seed is also required by law to be dyed a bright color.

Figure 11.

Figure 11: The seed label serves as a means of communication between the buyer and seller.

This guide presents basic facts about seeds, including how they develop, how to store and germinate seeds successfully and the factors that influence seed…

The Benefits Of High Quality Seeds

The Benefits of High Quality Seeds

The Benefits Of High Quality Seeds

If it’s true that you reap what you sow, then it only makes sense to sow the very best. The higher quality your seeds are, the better they perform, and the more productive your crop will be and the greater the returns.

Seeds are graded as they’re cleaned to make sure only the purest and finest examples make it through the process. Higher quality seeds will have a significant impact on yield output and generally provide a more stable and consistent result. Here are some of the benefits you can expect from using high quality seeds:

  • Because they’re the best of the bunch, more seeds will emerge, therefore less seed is needed, which saves you money
  • Seedlings from high quality seeds will be strong and produce uniform plants
  • Plants will grow faster shortening the time from planting to harvesting
  • Seeds of higher quality are more resistant to disease and distress
  • Crops will produce a more uniform and robust end product that will demand a higher price
  • Larger seeds have more vigour. More vigour means quicker emergence. Quicker emergence means better disease control

Quality seeds have been shown to increase yields significantly and to provide greater returns on your initial investment. It makes little sense, therefore, to opt for seeds of lesser quality in the hope of saving money up-front. These poorer varieties will likely be contaminated by weeds, chaff and a mixture of foreign elements that could attract insects and fungi, making them more susceptible to disease and producing a smaller, less robust crop that brings in less revenue.

When it comes to planting seeds, don’t put the cart before the horse. Use the highest quality seeds you can find to guarantee the maximum yield of the strongest crop that fetches the highest prices. That is, after all, the whole point of the exercise.

The Benefits Of High Quality Seeds The Benefits Of High Quality Seeds If it’s true that you reap what you sow, then it only makes sense to sow the very best. The higher quality your seeds