Agribio

Agribio is a Division B and Division C event that was first run as a trial event in 2020 at Delaware regional tournaments. It was also scheduled to be run at the 2020 Florida state tournament, but this tournament was canceled due to the 2019-20 Coronavirus outbreak. In 2021, this event will be ran in Delaware, the Univeristy of Florida regional, and the Florida State tournaments. The event is run as an exam, focusing on plant biology, soil science and ecology and agricultural practices. Each team may bring four 8.5" x 11" note sheet with information on both sides, as well as one stand-alone non-programmable, non-graphing calculator.

Contents 1	Plant Anatomy and Morphology 1.1	Vascular Plants 1.2	Reproduction 1.3	Evolution and Paleo-Botany 2	Major Plant Groups 2.1	Algae vs. Multicellular Plants 2.2	Monocots vs. Dicots 2.3	Embryophytes vs. Cryptograms 2.4	Woody Plants vs. Herbaceous Plants 3	Division C Concepts 3.1	Horticulture 3.2	Plant Biochemistry 4	Energy and Nutrient Cycles 5	Genetically Modified Organisms 6	Plant Diseases 6.1	Nutrient Deficiencies 7	Resources Plant Anatomy and Morphology Vascular Plants The morphology of vascular plants have two key parts:

Shoot system (what sprouts above ground, which are the stem and leaves). Root system (what grows underground). Both systems depend on each other to function, as the shoot system needs the root system for water and minerals and the root system needs the shoot system for food and energy. If a plant loses one of the systems, it can regrow.

Among the many tissues and organs, vascular plants have 4 main organ systems: the stem, the roots, the leaves, and the reproductive organs. The stem holds the leaves and connects them to the roots through two tissues called the xylem and phloem. The roots hold the plant in place and absorb water and nutrients from the ground. The leaves grow from the stem and their purpose is to photosynthesize. The shape and structure of a leaf depends on the plant itself. The reproductive organs allow the plant to multiply in number, both asexually and sexually depending on the plant.

Reproduction Non-vascular Plants

Moss: Bryophytes Dispersal- Spores are dispersed into favorable environments such as moist soil or tree bark, where they may germinate and grow into haploid gametophytes (gamete-producing plant structure). Protonemata- Promising spores develop a mass of green, branched, one-cell-thick filaments called protonemata. Protonemata have large surface areas that enhance water and mineral absorption to continue germination. Haploid. Note that the developing gametophytes are anchored by rhizoids, not roots. Budding- Buds are plant structures that give rise to gametophytes. These are produced by the haploid protonemata through mitotic division. Male gametophyte- Contains inner structures known as gametangia, more specifically, antheridia, where sperms are produced and kept. Female gametophyte- Contains inner structures known as gametangia, more specifically, archegonia, where eggs are produced and kept. Fertilization- Upon favorable conditions, the flagellated sperm swim through a film of water toward eggs (produced by female gametangia). Zygotic Stage- A diploid zygote develops inside of the archegonium and develops into a sporophyte embryo. Sporophytic Stage- A young diploid sporophyte grows a long stalk (seta), again from the nutrient-dependent archegonium. Maturity- Looking at the entire plant, the mature sporophyte is on top (seta + capsule), and attached by the foot of the female gametophyte. Repetition- Meiosis occurs inside of the capsule (sporangium) where haploid spores develop. Upon capsule maturity, the lid pops off, and the spores are released to repeat the preceding steps. Seedless Vascular Plants

Ferns: Pterophytes Dispersal- Sporangia release haploid spores. Most fern species produce a single type of spore (botanical condition known as isospory) that develops into a bisexual photosynthetic gametophyte. Protonemata- Same function as in moss life cycle. Bisexual gametophyte- Antheridia and archegonia are produced but in different regions of of the mature haploid gametophyte. Do note that there is a reason why in most fern species, a gametophyte produces sperm and eggs at different times. Fertilization- Same as in the moss life cycle. Sporophytic Stage- Unlike bryophytes, these grow true leaves out from an archegonium gametophyte. Mature Sporophytic stage- Sori are found on the underside of the sporophyte's reproductive leaves. Each sorus is a cluster of sporangia. Repetition- Same as in the moss life cycle. Vascular Plants

Gymnosperms- Pines Bold text

Angiosperms- Flowers Bold text Homosporous spore production

Heterosporous spore production

Evolution and Paleo-Botany Evolutionary Advantage of Seeds Major Plant Groups Algae vs. Multicellular Plants Monocots vs. Dicots If an organism reproduces via enclosed seeds, it is either a monocot or a dicot. The terms "monocot" and "dicot" refer to the number of cotyledons present in the seed. A monocot (monocotyledon) has only one cotyledon, and dicots (dicotyledon) have two. Monocots and dicots are also differentiated by their leaf venation (leaf vein structure), stem structure, root systems, and floral patterns.

Leaf venation

Monocots have parallel leaf veins. Dicots have branching leaf veins. Stem structure

Monocots develop vascular bundles in groups that are placed arbitrarily around the stem. Dicots develop vascular bundles in groups that form a ring around the edge of the stem. Root systems

Monocots usually grow with a fibrous root system, meaning that there are many small roots that branch out from each other. Dicots usually grow a taproot, which is a deep and thick central root in which smaller roots branch out from. Floral patterns

Monocots usually flower in groups of 3 Dicots usually flower in groups of 5 Embryophytes vs. Cryptograms Embryophytes and Cryptogams are 2 large groups of plants. The term "plant" is a very general term in many ways and is used commonly to describe most organisms that aren't animals. Embryophytes are a clade of plants commonly associated with land plants, like trees, mosses, and flowering plants, while Cryptogams are a group that includes plants that reproduce with spores, such as fungi, algae, and mosses.

Embryophytes are classified by their ability to nurture the young sporophyte inside the tissue of the gametophyte. This includes groups such as nonvascular plants (mosses, liverworts, and hornworts), seedless vascular plants (such as ferns and lycophytes), gymnosperms (like coniferous trees and cycads), and angiosperms (flowering plants).

In contrast, Cryptograms are organisms that reproduce without seeds or flowers, with the use of spores. This includes groups such as thallophytes (such as fungi, bacteria, and algae), bryophytes (nonvascular plants), pteridophytes (seedless vascular plants).

Woody Plants vs. Herbaceous Plants Herbaceous plants and woody plants are 2 different groups of land plants. The main difference between the two groups is that woody plants are generally perennials which undergo secondary growth and have a woody stem. In contrast, herbaceous plants are generally shorter lived, and do not have a woody stem.

Herbaceous plants, or herbs, are mainly classified by not having a permanent woody stem. Herbaceous plants can be annuals, meaning that it takes one year to complete its life cycle,, meaning that it takes 2 years to complete its life cycle, or perennials, which live for more than 2 years. Annual herbs die after one year, while in other herbs, the stem dies every year, and the plant is left with just a small portion under the ground. After the cold or dry season ends, this portion regrows. Some herbs, usually fast-growing annuals, are pioneer species in succession. They usually don’t produce above-ground structures made of lignin, an important polymer in cell walls, meaning that they can colonize the land much faster than woody plants.

Woody plants produce wood and have sturdy stems. Since they need time to produce their stems, woody plants are almost always perennials. Unlike herbaceous plants, they survive during the winter in a dormant state where primary growth (lengthwise growth) is slowed or stopped and don’t need to regrow every year. During the cold or dry season, stem growth completely ceases and the plant stops growing. Most woody plants are trees or shrubs that are perennials. Many woody plants will remove branches or leaves that are no longer serving their purpose, in a process called self-pruning. In woody plants, the root is also woody and fortified with lignin. At the end of the growing season, new roots stop primary growth. However, they continue to undergo secondary growth, or growth that increases the diameter. Unlike the stem, roots continue to grow very slowly during the dormant season.

Division C Concepts Horticulture Plant Biochemistry Energy and Nutrient Cycles Genetically Modified Organisms Plant Diseases Nutrient Deficiencies Plants need a variety of nutrients to survive. When the plant is running low on these nutrients, there are telltale signs that to look for to determine what’s wrong. Some of the most important nutrients to plant growth are nitrogen, phosphorus, and potassium. On fertilizers, you often see the N-P-K ratio of the fertilizer, the concentration of nitrogen, phosphorus, and potassium. There are 2 types of nutrients: mobile and immobile nutrients. Mobile nutrients are able to move through the plant from the younger leaves to the older leaves when needed. This makes most of the early symptoms of theses deficiencies occur in the older leaves. Examples of mobile nutrients include nitrogen, magnesium, and molybdenum. Immobile nutrients are not able to move through the plant, and therefore occur first in the younger leaves. Example of immobile nutrients are calcium, boron, and iron. Zinc is a notable exception, since it can move, just not far. Therefore, zinc deficiencies show symptoms in the middle leaves of the plant.

Macronutrients

Macronutrients are nutrients that plants need a large amount of. Examples of macronutrients are nitrogen, phosphorus, and potassium.

Nitrogen - Nitrogen is one of, if not the most important element to a plant’s growth. It is used in many important organic molecules, such as nucleic acids, proteins, amino acids, and chlorophyll. Symptoms of a nitrogen deficiency include loss of coloration, called chlorosis, in mature leaves and necrosis, or the death of many or all cells in a tissue. The leaves also start to turn yellow, and the stem of the plant usually turns to a light green color.

Phosphorus – Phosphorus is another very important plant nutrient, used in organic molecules such as nucleic acids and ATP. Symptoms of a phosphorus deficiency are leaf tips with reddish-purple “flames” coming from the tips, and older leaves turning dark green or reddish purple.

A picture of a corn plant with a phosphorus deficiency Potassium - Potassium is used in plants to activate enzymes and in photosynthesis. Signs of a deficiency include older leaves wilting and looking scorched. The leaves also start yellowing on the sides and go along the edge of the leaf, leaving the interior untouched.

Calcium - Calcium is used in the construction and material of the cell wall. Symptoms of a calcium deficiency include new leaves growing shriveled and darken. The tips of leaves will also often become brittle and eventually die.

Magnesium - Magnesium is an important plant nutrient, since it is used as the center molecule in chlorophyll and an important molecule in ATP synthesis. Symptoms of a magnesium deficiency include older leaves yellowing at the edge, leaving the center of the leaf green.

Sulfur – Sulfur is an important plant nutrient used in the amino acids cysteine and methionine. Symptoms of a sulfur deficiency include yellowing of young leaves, and eventually yellowing of older leaves.

Micronutrients

Micronutrients are elements in plant tissue in very small quantities, measured in ppm (parts per million), but are still essential for plant growth.

Boron - Boron is a plant nutrient used in cell wall formation and reproductive tissue. Symptoms of a boron deficiency include the death of the terminal (or apical) bud, the primary point of growth in plants. Young leaves may also show chlorosis, and other leaves may develop dark brown spots that progress to the death of that tissue.

Copper - Copper is a nutrient needed for chlorophyll production and respiration. Symptoms of a sulfur deficiency include leaves darkening and growth stopping. Symptoms can also include delayed maturity and melanosis, or brown discoloration.

Iron - Iron is an important nutrient used in plant respiratory and photosynthetic reactions. Symptoms of an iron deficiency include chlorosis between the veins of the plants, and eventually chlorosis of the whole leaf. The veins of the plant appear very sharply defined next to the yellowing leaves.

Manganese - Manganese is a plant nutrient important for the chloroplast. Symptoms of a manganese deficiency include yellowing of the leaves between veins, dead spots on the leaves, smaller plant parts, and fronds having slowed or stopped growth (called frizzle top).

Molybdenum - Molybdenum is needed for enzyme activation and nitrogen fixation in some plants. Molybdenum deficiencies often have similar symptoms to a nitrogen deficiency, due to how it is used.

Zinc - Zinc is a plant nutrient used in the production of plant growth factors (or plant hormones). Symptoms of a zinc deficiency include yellowing of leaves between veins and sever chlorosis, turning the leaves to a pale green color, or even white if the deficiency is bad enough.