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Stems, Leaves and Seeds by Evil Mr. Bleecker Woody plants in an evolutionary context Note that the evolution of photosynthesis occurred LONG before plants invaded terrestrial environments. “Woodiness” evolved after plants invaded land in response to intense competition for light. Dicots: all true “woody” angiosperms are dicots, but not all dicots are woody species Saguaro cactus Hepatica americana Monocots Coconut palm rice Shoot System Organization of the plant body Vegetative organs are the leaf, stem and root The body of a plant has a root system and a shoot system. Root System Organization of Stems Shoot tip produces new cells that elongate and add length to the stem. Monocot and dicot traits Herbaceous (nonwoody) Stems Mature herbaceous stems exhibit only primary growth. The outermost tissue is the epidermis (not bark), which is covered by waxy cuticle. Herbaceous dicot stem -vascular bundles are in a distinct ring Monocot stem -vascular bundles are scattered throughout Woody Stems A woody plant has both primary and secondary tissues. Primary tissues are new tissues formed each year from primary meristems right behind apical meristem. Secondary tissues develop during the second and subsequent years of growth from lateral meristems (vascular cambium and cork cambium). Secondary growth, (annual growth) increases the girth of a plant. Trees undergo secondary growth because of a change in vascular cambium. The secondary tissues produced by the vascular cambium, are called secondary xylem and secondary phloem, Secondary growth in a Dicot stem Pith rays are composed of living parenchyma cells (a type of xylem) that allow materials to move laterally. Section of woody stem Spring wood followed by summer wood makes up one year’s growth or annual ring. The bark of a tree contains cork, cork cambium, and phloem. A woody stem has three distinct areas: the pith, the wood, and the bark. Annual Rings This tree had a pith date of 256 BC and an outer ring of about AD 1320, making this tree nearly 1,600 years old when it died (it's about 3 feet across)! (photo © H.D. Grissino-Mayer and R.K. Adams). Tree trunk Modified stems Cross section of tree stem Exercise 1. How old is this tree? 2. How many rainy seasons occurred during the life of this tree? In what years did they occur? 3. How many dry seasons occurred during the life of this tree? In what years did they occur? 4. During what year of growth was there a forest fire? 5. What would happen if a porcupine completely chewed away the phloem tissue around the trunk of the tree? Why? Raven et al. Fig. 27-6 Development of primary vascular bundles Development of a ring of vascular cambium Early secondary growth Outer bark Inner bark Vascular cambium Secondary xylem Organization of primary tissues in a Young Dicot Stem (eg. Bean) The primary tissues of a Young Monocot Stem (eg. Corn) Fig. 9.20 Leaf diversity The leaves of a cactus are spines attached to a succulent stem. Climbing leaves are modified into tendrils. The leaves of a few plants are specialized for catching insects. Blade Petiole Attaches to the node here Monocots: Parallel veins (sugarcane, corn) Flowers have 3 or multiples of 3 (6,9,12, etc.) parts Dicots: Veins form a net pattern (oak tree) Flowers have 4 or 5 or multiples of 4 or 5 (8,10, etc.) parts Dicot leaves Generalized Leaf Anatomy – Dicot Leaf Typical Monocot Leaf X-Section Corn, Sugar Cane Vein Epidermis Phloem Xylem Stoma Leaf Stomata: Allow Gas Exchange Guard cells with chloroplasts Stomata in Zebrina leaf epidermis Stoma Subsidiary cells Figure 1. Guard cell enriched extract used for cloning and analysis of phosphoinositide signaling genes. Figure 2. HIC promoter trap lines show guard cell specific GUS expression. The HIC gene is involved in controlling stomatal development in response to elevated CO2. Guard Cells Leaf surfaces are dotted with millions of stomata such as this one. This stomate is lined by two guard cells that control its aperture. Because control requires movement, and movement requires energy, these cells contain numerous mitochondria and chloroplasts (the little green photosynthetic factories that look a bit like brussel sprouts in this shot). Thus they are the only cells in the epidermis that are green. Monocot Seeds Monocot seeds have: Endosperm seed coat endosperm cotyledon coleoptile One cotyledon radicle Dicot Seeds Dicot seeds have: No endosperm at maturity Two cotyledons Seed coat First leaves Early root Cotyledon Development of Seeds Function of seed structures: Endosperm Nutrition for embryo Cotyledons Nutrition for embryo Overall, what is the function of a seed? 1. Protects young embryo 2. Provides nutrition for the developing embryo 3. Allows dispersal of the embryo over time & space Seed to Seedling