BIO1 11_12 Q1 0204 FD - Structures and Functions of Modified Cells (PDF)
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This document discusses various cell modifications and their adaptations according to their functions. It explores different types of cells, like microvilli, cilia, flagella, and others in animals and plants. It also provides the location and functions of these structures.
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Lesson 2.4 Structures and Functions of Modified Cells General Biology 11/2 Science, Technology, Engineering, and Mathematics Have you ever wondered what your talents are? 2 Why do we consider this a fish? 3 What makes these animals unique?...
Lesson 2.4 Structures and Functions of Modified Cells General Biology 11/2 Science, Technology, Engineering, and Mathematics Have you ever wondered what your talents are? 2 Why do we consider this a fish? 3 What makes these animals unique? 4 What makes us unique as humans? 5 Organisms’ special structures and abilities are developed based on what they need to survive or to adapt in their environments. 6 Similarly, microscopic structures in the body are specialized in that they carry out activities that other structures cannot. 7 What do special microscopic structures look like? How do they function? 8 Learning Competency At the end of the lesson, you should be able to do the following: Describe some cell modifications that lead to adaptation to carry out specialized functions (e.g., microvilli, root hair) (STEM_BIO11/12-Ia-c-5). 9 Learning Objectives At the end of the lesson, you should be able to do the following: Enumerate the specialized cells in animals and plants. Locate the specialized cells in animals and plants. Determine the functions of each specialized cell in animals and plants. 10 Specialized Cells and Cell Structures Parts of a typical animal cell 11 What are the specialized cells in animals? What makes them essential components of the animal body? 12 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Basal Infoldings and Hemidesmosomes Cell Junctions Blood Cells and Sex Cells The microvilli in the small intestine 13 Specialized Cells and Cell Structures in Animals Microvilli Function of Microvilli Cilia and Stereocilia These increase the surface area for Flagella the absorption of nutrients and other Basal Infoldings and essential substances from the gut Hemidesmosomes cavity into the underlying tissues and Cell Junctions blood vessels. Blood Cells and Sex Cells 14 Specialized Cells and Cell Structures in Animals Microvilli Location of Microvilli Cilia and Stereocilia They are found in the small Flagella intestines, Basal Infoldings and Hemidesmosomes kidneys, egg cells, and white Cell Junctions blood cells. Blood Cells and Microvilli in small intestine Sex Cells 15 Specialized Cells and Cell Structures in Animals Microvilli Structure of Cilia Cilia and Stereocilia Flagella Basal Infoldings and Hemidesmosomes Cell Junctions A cilium’s structural core is made of nine pairs of Blood Cells and Sex Cells microtubules on the outside ring with 2 microtubules on the central portion. 16 Specialized Cells and Cell Structures in Animals Microvilli Function of Cilia Cilia and Stereocilia In the respiratory tract, cilia prevent Flagella mucus (from Basal Infoldings and Hemidesmosomes goblet cells), bacteria, and dirt Cell Junctions from entering the Cilia above the Blood Cells and lungs. pseudostratified Sex Cells epithelia of the trachea 17 Specialized Cells and Cell Structures in Animals Microvilli Function of Stereocilia Cilia and Stereocilia Flagella Basal Infoldings and Hemidesmosomes Cell Junctions Stereocilia in a frog’s inner ear allow it to detect sounds from its environment. Through these, frogs Blood Cells and Sex Cells have a mechanism to detect and escape from potential threats. 18 Specialized Cells and Cell Structures in Animals Microvilli Structure and Function of Flagella Cilia and Stereocilia Flagella are tail-like Flagella structures that Basal Infoldings and Hemidesmosomes provide Flagella motility to Cell Junctions cells. Blood Cells and Flagella of Euglena Sex Cells 19 How does the location of specialized structures in cells relate to their functions? 20 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Basal infoldings and Flagella hemidesmosomes are both found at Basal Infoldings and Hemidesmosomes the basement membrane of Cell Junctions epithelial cells. Blood Cells and Sex Cells 21 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Hemidesmosomes help the epithelial Flagella tissue provide protection and Basal Infoldings and Hemidesmosomes structural support to the underlying Cell Junctions cells. Blood Cells and Sex Cells 22 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Basal infoldings are responsible Flagella for increasing Basal Infoldings and surface area and Hemidesmosomes for ion and fluid Cell Junctions transport. Basal infoldings in an excretory duct Blood Cells and Sex Cells 23 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Basal Infoldings and Hemidesmosomes Cell Junctions Blood Cells and Sex Cells Cell junctions are found in epithelial cells and are mainly responsible for connecting adjacent cells. 24 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Tight junctions Flagella prevent leakage of substances. Basal Infoldings and Hemidesmosomes Cell Junctions Blood Cells and Sex Cells 25 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Adherens Basal Infoldings and junctions Hemidesmosomes connect Cell Junctions adjacent cells. Blood Cells and Sex Cells 26 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Desmosomes Basal Infoldings and Hemidesmosomes connect adjacent cells. Cell Junctions Blood Cells and Sex Cells 27 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Basal Infoldings and Gap junctions Hemidesmosomes serve as channels Cell Junctions of ions, water and Blood Cells and other essential Sex Cells substances. 28 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Basal Infoldings and Hemidesmosomes Cell Junctions Red blood cells are biconcave to aid in the diffusion of Blood Cells and Sex Cells gases from the air sacs of the lungs and into the oxygen-deprived tissues of the rest of the body. 29 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Basal Infoldings and Hemidesmosomes Cell Junctions The lack of nucleus in red blood cells gives more Blood Cells and Sex Cells space for hemoglobin. Thus, more oxygen molecules can be transported. 30 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Basal Infoldings and Hemidesmosomes Cell Junctions Blood Cells and Red blood cells also lack mitochondria. They generate Sex Cells their energy through anaerobic respiration. 31 Specialized Cells and Cell Structures in Animals Microvilli White blood Cilia and Stereocilia cells are responsible for Flagella the body’s defenses. Basal Infoldings and Hemidesmosomes They can either Cell Junctions be granulocytes Types of white blood cells Blood Cells and or agranulocytes. Sex Cells 32 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Egg cells are the largest cells in Flagella the human body and are Basal Infoldings and Hemidesmosomes necessary for sexual Cell Junctions Egg cells have two outer reproduction. membrane layers, namely, Blood Cells and zona pellucida and corona Sex Cells radiata. 33 Specialized Cells and Cell Structures in Animals Microvilli Cilia and Stereocilia Flagella Basal Infoldings and Hemidesmosomes Cell Junctions Sperm cells travel from the testes to the female’s Blood Cells and Sex Cells fallopian tube to facilitate an event called fertilization. 34 What are the specialized cells in plants? What makes them essential components of the plant? 35 Specialized Cells and Cell Structures in Plants Trichomes Root Hairs Mesophyll Cells Xylem and Phloem Trichomes on a sundew plant 36 Specialized Cells and Cell Structures in Plants Trichomes Structure and Function of Trichomes These are epidermal outgrowths Root Hairs responsible for ○ preventing insect attacks, Mesophyll Cells ○ shading leaves, and ○ trapping insects. Xylem and Phloem 37 How do trichomes differ from root hairs in terms of function? 38 Specialized Cells and Cell Structures in Plants Trichomes Root Hairs Mesophyll Cells Xylem and Phloem Lily plant’s root hairs 39 Specialized Cells and Cell Structures in Plants Trichomes Structure and Function of Root Hairs Root hairs are tiny hair-like structures Root Hairs that originated from the epidermis of plants. Mesophyll Cells Root hairs facilitate the absorption of Xylem and Phloem water from the substrate. 40 Specialized Cells and Cell Structures in Plants Trichomes Root Hairs Mesophyll Cells Xylem and Phloem Microscopic layers of a leaf 41 Specialized Cells and Cell Structures in Plants Trichomes Structure and Function of Mesophyll Mesophyll layer is primarily Root Hairs responsible for photosynthesis. Mesophyll Cells It is made up of palisade cells and spongy cells. Xylem and Phloem 42 How does the arrangement of cells in the mesophyll layer help in photosynthesis? 43 Specialized Cells and Cell Structures in Plants Trichomes Root Hairs Mesophyll Cells Xylem and Phloem Vascular bundle of Sparganium 44 Specialized Cells and Cell Structures in Plants Trichomes Function of Xylem and Phloem Xylem and phloem tissues consist of Root Hairs specialized cells that are responsible for transporting essential substances, Mesophyll Cells such as water, minerals, and food needed by the plants. Xylem and Phloem 45 Check Your Understanding Identify what is being described in each of the following items. 1. These are hairlike structures responsible for protecting plants from insect attacks. 2. It is the inner layer of leaves where photosynthesis happens. 3. The cells of this tissue transport water and minerals from the soil to different parts of the plant. 46 Check Your Understanding Determine the modified cells that need to function in the following situations and explain your answer. You may have more than one answer in each item. 1. Pathogenic bacteria enter the trachea of the respiratory tract. 2. An indoor plant starts to desiccate. 3. Insects start to feed on plants. 47 Let’s Sum It Up! Modified or specialized cells have developed structures that help them carry out their functions. Specialized cells in animals include the following: ○ Microvilli are responsible for increasing the surface area for absorption. ○ Cilia and stereocilia are responsible for movement and sensation, respectively. 48 Let’s Sum It Up! Specialized cells in animals include the following: ○ Flagella are responsible for locomotion or motility. ○ Basal infoldings and hemidesmosomes are responsible for fluid transport and attachment, respectively. ○ Cell junctions serve as connections between adjacent cells. 49 Let’s Sum It Up! Specialized cells in animals include the following: ○ Red and white blood cells are responsible for transporting oxygen and protecting the body from pathogens, respectively. ○ Sperm and egg cells aid in the reproduction process. 50 Let’s Sum It Up! Specialized cells in plants include the following: ○ Trichomes serve as protection of plants from extreme temperatures and insect or herbivore attacks. ○ Root hairs increase the surface area for the absorption of water. ○ Mesophyll cells serve as the sites of photosynthesis. 51 Let’s Sum It Up! Specialized cells in plants include the following: ○ Xylem and phloem consist of cells that are responsible for the transport of essential substances such as water and photosynthetic by-products. 52 Let’s Sum It Up! Animals and plants have specialized cells and cell structures that ultimately contribute to the growth, development, and survival of the organism. 53 Challenge Yourself Microvillus atrophy is a congenital disease characterized by a lack of microvilli in the intestines. What are the possible effects of this disease in newborn babies? 54 Photo Credits Slide 2: Wooden Tile Talent Image by Nick Youngson is licensed under CC BY-SA 3.0 via The Blue Diamond Gallery. Slide 3: Clownfish in Andaman Coral Reef by Ritiks is licensed under CC BY-SA 3.0 via Wikimedia Commons. Slide 15: Normal Small Intestine Mucosa by Ed Uthman is licensed under CC BY 2.0 via Flickr. Slide 19: Euglena gracilis by naturalismus is licensed under CC BY-SA 2.0 via Flickr. Slide 36: Trichomes by incidencematrix is licensed under CC BY 2.0 via Flickr. 55 Bibliography Campbell, Neil A. Biology. Frenchs Forest, N.S.W.: Pearson Benjamin Cummings, 2008. Cui, Dongmei. Atlas of Histology with Functional and Clinical Correlations. 351 West Camden Street, Baltimore. Lippincott Williams and Wilkins, 2011. Mader, Sylvia S., Michael Windelspecht, and Sylvia S. Mader. Introductory Biology. United States: McGraw-Hill Create, 2014. Miller, Kenneth R., and Joseph S. Levine. Prentice-Hall Biology. Upper Saddle River, NJ: Pearson Prentice Hall, 2006. Sabile, Mary Jane G., General Biology 1. Quezon City, Philippines: Phoenix Publishing House, Inc., 2018. 56 Lesson 2.1 Prokaryotes and Eukaryotes General Biology 11/2 Science, Technology, Engineering, and Mathematics What type of house would you prefer? How can you describe a “perfect” house? 2 Like the different types of houses, different organisms also have varying types of cells. 3 These cells also contain different structures that all contribute to the normal functions necessary for life, just like houses. 4 How can you differentiate a prokaryotic cell from a eukaryotic cell? 5 Prok The Two Types of Cell Prokaryotic Cell This can be compared to a studio-type of a condominium unit because of the lack of compartments. Overview of a prokaryotic cell 6 The Two Types of Cell Prokaryotic Cell Prokaryotic organisms are metabolically diverse because they can utilize different nutrients and energy sources and they can inhabit all types of Overview of a prokaryotic cell environment on Earth. 7 The Two Types of Cell Prokaryotic Cell All bacteria that include the organisms of domains Archaea and Bacteria are considered as prokaryotes. Overview of a prokaryotic cell 8 The Two Types of Cell Eukaryotic Cell This is comparable to a mansion which has several rooms or compartments. Overview of a eukaryotic cell 9 The Two Types of Cell Eukaryotic Cell Domain Eukarya, which includes protists, fungi, plants, and animals, is eukaryotic. Overview of a eukaryotic cell 10 Distinguishing Features of Prokaryotic and Eukaryotic Cells Presence of Cell wall and cell Nucleus membrane Distinguishing Features (cellular parts) Endomembrane and Ribosome other organelles 11 Distinguishing Features of Prokaryotic and Eukaryotic Cells Presence of Nucleus Cell wall and cell membrane Endomembrane and other organelles Ribosome The genetic material is enclosed in the nucleus of eukaryotes and in the nucleoid region of prokaryotes. 12 Distinguishing Features of Prokaryotic and Eukaryotic Cells Cell wall Cell wall Presence of Nucleus of eukaryotes of prokaryotes Cell wall and cell present in most membrane eukaryotic cells (these are present in almost all not found in animals and prokaryotic cells Endomembrane and most protists) other organelles Cell wall is either made up Cell wall is made up of of cellulose as in plants Ribosome peptidoglycan. and chitin in fungi. 13 Distinguishing Features of Prokaryotic and Eukaryotic Cells Cell membrane Cell membrane Presence of Nucleus of eukaryotes of prokaryotes Cell wall and cell The sterols that are They do not have membrane present in the cell sterols in the cell membrane are membrane but have a Endomembrane and cholesterol (animals), sterol-like lipid other organelles phytosterol (plants) and component called ergosterol (fungi). hopanoid. Ribosome 14 Distinguishing Features of Prokaryotic and Eukaryotic Cells Presence of Nucleus Endomembrane system Cell wall and cell It includes the rough and smooth membrane endoplasmic reticulum, Golgi apparatus, lysosome, endosome, and Endomembrane and vacuole. other organelles It is present in eukaryotic cells, but not Ribosome in prokaryotic cells. 15 Distinguishing Features of Prokaryotic and Eukaryotic Cells Ribosome Ribosome Presence of Nucleus of eukaryotes of prokaryotes Cell wall and cell Ribosomes can be membrane found in the cytoplasm, outer nuclear All ribosomes are found Endomembrane and membrane, rough in the cytoplasm. other organelles endoplasmic reticulum, mitochondrion, and Ribosome chloroplast. 16 Distinguishing Features of Prokaryotic and Eukaryotic Cells Ribosome Ribosome Presence of Nucleus of eukaryotes of prokaryotes Cell wall and cell Eukaryotes have 80S membrane ribosomes Prokaryotes have 70S (mitochondria, and ribosomes. Endomembrane and chloroplast contain 70S other organelles ribosomes) Ribosome 17 The DNA structure of prokaryotic and eukaryotic cell is different from one another. Will it affect the process of DNA replication, transcription, and translation? If so, how? If not, why did you say so? 18 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of Number of Cell Size DNA Chromosome Other Distinguishing Features Mode of DNA Transcription Reproduction Replication and Translation Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Number of chromosome Cell size Mode of reproduction DNA replication Transcription and Translation In eukaryotes, the DNA is wrapped around histones to form nucleosomes. 20 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Chromosome number Chromosome number Number of in eukaryotes in prokaryotes chromosome Eukaryotes have more Cell size than one chromosome so Most prokaryotes have Mode of histones are essential in only one chromosome reproduction packaging DNA into and an nucleosomes and helping extrachromosomal DNA replication it to condense into DNA called a plasmid. Transcription and chromatin. Translation 21 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Number of chromosome Cell size Mode of reproduction DNA replication Transcription and Translation Relative sizes of bacteria (prokaryote), plant cell (eukaryote), and animal cell (eukaryote) 22 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Number of Mode of reproduction Mode of reproduction chromosome in eukaryotes in prokaryotes Cell size Most prokaryotic cells In eukaryotic cells, reproduce through Mode of reproduction individual cells binary fission and reproduce through some reproduce DNA replication mitosis and meiosis. through spores. Transcription and Translation 23 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Number of chromosome Cell size Mode of reproduction DNA replication Transcription and Translation Eukaryotic cells undergoing mitosis 24 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Number of DNA replication DNA replication chromosome in eukaryotes in prokaryotes Cell size Eukaryotic cells have DNA replication occurs multiple points of origin Mode of in two opposing reproduction and use unidirectional directions at the same replication within the DNA replication time in the cytoplasm. nucleus. Transcription and Translation 25 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Number of DNA replication DNA replication chromosome in eukaryotes in prokaryotes Cell size Telomerase is involved Prokaryotic cells do not in the replication of have telomerase so Mode of reproduction telomeres of the telomerase is not eukaryotic present and involved in DNA replication chromosome. their DNA replication. Transcription and Translation 26 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Number of DNA replication DNA replication chromosome in eukaryotes in prokaryotes Cell size Eukaryotes only replicate their DNA Prokaryotes Mode of reproduction during the S-phase of continuously replicate interphase in cell their short DNA. DNA replication division. Transcription and Translation 27 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Number of Transcription and Transcription and chromosome translation translation in eukaryotes in prokaryotes Cell size The transcription occurs Transcription and Mode of reproduction in the nucleus and the translation can be done translation occurs in the at the same time in the DNA replication cytoplasm. cytoplasm. Transcription and Translation 28 Distinguishing Features of Prokaryotic and Eukaryotic Cells Shape of DNA Transcription and Transcription and Number of translation translation chromosome in eukaryotes in prokaryotes Cell size No post-transcriptional Post-transcriptional processing because the Mode of processing is done in reproduction DNA of prokaryotes eukaryotes to remove does not have a DNA replication introns and come up non-coding part called with the final RNA. Transcription and introns. Translation 29 An unknown cell is discovered in a sulfur-rich area. The cell is about 750 µm in size but there are no partitions or compartments inside the cell. What type of cell is the unknown cell? 30 Check Your Understanding Write P if the statement applies to prokaryotes, E if it describes a eukaryote, and B if the statement is applicable for both prokaryotes and eukaryotes. 1. It has a circular genetic material. 2. Sterols are embedded in the cell membrane. 3. The process of translation occurs in the cytoplasm. 4. The cell wall is made up of peptidoglycan. 5. It undergoes binary fission to produce new cells. 31 Check Your Understanding Answer the questions correctly in 2-3 sentences only. 1. Discuss the importance of histones in a skin cell. 2. Compare and contrast bacterial cell wall and plant cell wall. 3. Describe the genetic material of Lactobacillus casei. 32 Let’s Sum It Up! Cells are classified into two types: prokaryotic cell and eukaryotic cell. ○ Prokaryotic cells are found in prokaryotic organisms while eukaryotic cells are found in eukaryotic organisms. Examples of prokaryotes are Archaeans and Bacteria. Examples of eukaryotes are plants, animals, fungi, and protists. 33 Let’s Sum It Up! Prokaryotic and eukaryotic cells vary in terms of presence of nucleus, endomembrane system, cell wall and cell membrane, ribosome, shape of DNA and number of chromosome, cell size, DNA replication, transcription and translation, and mode of reproduction. 34 Challenge Yourself Why are mutations more common in prokaryotic cells than in eukaryotic cells? 35 Photo Credit Bibliography Blake, Leesa, and Donald I. Galbraith. McGraw-Hill Ryerson Biology 11. Toronto: McGraw-Hill Ryerson, 2002. Campbell, Neil A. Biology (8th Edition), 2009. Campbell, Neil A., Michael L. Cain, Peter V. Minorsky, Jane B. Mitosis_(261_13)_Pressed;_root_meristem_of_onion_(c Reece, Lisa A. Urry, and Steven Alexander ells_in_prophase,_metaphase,_anaphase,_telophase) Wasserman. Biology: a Global Approach. Harlow, Essex, by Josef Reischig is licensed under CC BY-SA 3.0 via England: Pearson Education Limited, 2018. Wikimedia Commons. Mader, Sylvia S. Concepts of Biology. New York: McGraw-Hill, 2011. Madigan, Michael T., Kelly S. Bender, Daniel H. Buckley, W. Matthew. Sattley, and David A. Stahl. Brock Biology of Microorganisms. Harlow, United Kingdom: Pearson Education Limited, 2017. Study.com. Study.com. Accessed February 4, 2020. https://study.com/academy/lesson/eukaryotic-and-prok aryotic-cells-similarities-and-differences.html. 36