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Cell biology

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MahrukhShehzadi1
MahrukhShehzadi1

Introduction to Cell Biology

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Cell Biology Presented By: Mahrukh Shehzadi
Course Content • Introduction to prokaryotic and eukaryotic cell differences including cell wall, membrane structure and chemical constituents of the cell. Composition and functions of lipid bilayer, transport across cell membrane and role of glycolipids and glycoproteins as receptors in cellular signaling. The functions, isolation and molecular organization of cellular organelles specifically the endoplasmic reticulum, golgi bodies, ribosomes, lysosome, micro-bodies, mitochondria. The structure and function of chromosomes and role of nucleus in regulation of metabolism. The concept of cell cycle, mitosis and meiosis and cell death. Structure and function of cytoskeleton, centriole and function of cilia and flagella in cell movement. • Practicals: Microscopy and staining techniques; Study of prokaryotic, eukaryotic cells; cellular reproduction; Mitosis: smear/squash preparation of onion roots.
Introduction to Cell Biology • Discovery of cell • In 1665, Robert Hooke used an early compound microscope to look at a nonliving thin slice of cork, a plant material; termed them as cells in his publication called Micrographia. In Holland, Anton van Leeuwenhoek used a single-lens microscope to observe pond water and other things; termed them as animalcules • Felix Dujardin termed all substances found inside the cell as sarcode. Later, Jan Evangelista Purkinje, called it as protoplasm. Robert Brown discovered the nucleus.
Cell Theory By the late 1830s, botanist Matthias Schleiden and zoologist Theodor Schwann were studying tissues and proposed the cell theory. Schleiden and Schwann proposed spontaneous generation as the method for cell origination, but spontaneous generation (also called abiogenesis) was later disproven. Rudolf Virchow famously stated “Omnis cellula e cellula”… “All cells only arise from pre-existing cells”. The unified cell theory states that: All living things are composed of one or more cells; the cell is the basic unit of life; and new cells arise from existing cells.
Fundamentals of Cell Theory • The cell is the fundamental unit of structure and function in living things. • All organisms are made up of one or more cells. • Cells arise from other cells through cellular division.
The expanded version of the cell theory can also include: • Cells carry genetic material passed to daughter cells during cellular division • All cells are essentially the same in chemical composition • Energy flow (metabolism and biochemistry) occurs within cells • Adenosine tri phosphate (ATP)
Basic Cell Types • Prokaryotes • Eukaryotes ‘Cells’ are considered as the structural and functional unit of life, whether it’s a single cell organism like bacteria, protozoa, or multicellular organisms like plants and animals.
Prokaryotic Cells Pro means ‘old,’ and karyon means ‘nucleus,’ So as the name suggest the history of the evolution of prokaryotic cells is at least 3.5 billion years old, but they are still important to us in many aspects like they are used in industries for fermentation (Lactobacillus, Streptococcus), for research work, etc. In comparison to eukaryotic cells, they lack few organelles and are not advanced as eukaryotes.
Generalized Structure of Prokaryotes Glycocalyx: This layer function as a receptor, the adhesive also provide protection to the cell wall. Nucleoid: It is the location of the genetic material (DNA), large DNA molecule is condensed into the small packet. Pilus: Hair like hollow attachment present on the surface of bacteria, and is used to transfers of DNA to other cells during cell-cell adhesion. Mesosomes: It is the extension of the cell membrane, unfolded into the cytoplasm their role is during the cellular respiration. Flagellum: Helps in movement, attached to the basal body of the cell. (different types of bacterial cells based on the flagella)
EXAMPLES
Cell Wall: It provides rigidity and support for the cell. Fimbriae: Helps in attachment to the surface and other bacteria while mating. These are small hair-like structure. Inclusion/Granules: It helps in storage of carbohydrates, glycogen, phosphate, fats in the form of particles which can be used when needed. Ribosomes: Tiny particles which help in protein synthesis. Cell membrane: Thin layer of protein and lipids, surrounds cytoplasm and regulate the flow of materials inside and outside the cells. Endospore: It helps cell in surviving during harsh conditions. Permeability: Impermeable Selectively permeable Completely permeable
CELL WALL CELL MEMBRANE
Eukaryotic Cells Eu means ‘new,’ and karyon means ‘nucleus,’ so these are the advanced type of cells found in plant, animals, and fungi. Eukaryotic cells have a well-defined nucleus and different organelles to perform different functions within the cell, though working is complex to understand.
Generalized Structure of Eukaryotes
Key Difference Between Prokaryotic Cells and Eukaryotic Cells Prokaryotic cells are the primitive kind of cell, whose size varies from 0.5-3µm, they are generally found in single-cell organisms Eukaryotic cells are the modified cell structure containing different components in it, their size varies from 2-100µm, they are found in multicellular organisms. Organelles like mitochondria, ribosomes, Golgi body, endoplasmic reticulum, cell wall, chloroplast, etc. are absent in prokaryotic cells, while these organelles are found in eukaryotic organisms. Though cell wall and chloroplast are not found in the animal cell, it is present in the green plant cell, few bacteria, and algae. The main difference between Prokaryotic cells and the Eukaryotic cell is the nucleus, which is not well defined in prokaryotes whereas it is well structured, compartmentalized and functional in eukaryotes.
Cell organelles are present which are membrane-bound and have individual functions in eukaryotic cells; many organelles are absent in prokaryotic cells. In prokaryotes, the cell division takes place through conjugation, transformation, transduction but in eukaryotes, it is through the process of cell division. The process of transcription and translation occurs together, and there is a single origin of replication in the prokaryotic cell. On the other hand, there are multiple origins of replication and transcription occurs in nucleus and translation in the cytosol. Genetic Material (DNA) is circular and double-stranded in Prokaryotes, but in Eukaryotes, it is linear and double-stranded. Prokaryotes reproduce asexually; commonly Eukaryotes have a sexual mode of reproduction. Prokaryotes are the simplest, smallest and most abundantly found cells on earth; Eukaryotes are larger and complex cells.
Characteristics of All Cells (Summary) • A surrounding membrane • Protoplasm – cell contents in thick fluid • Organelles – structures for cell function • Control center with DNA
Representative Animal Cell
Representative Plant Cell
Chemical Composition of Cells Cells consist of a collection of simple and complex organic molecules, inorganic molecules, and ions. There are also organized clusters of these called supramolecular complexes. The majority of biomolecules are composed of only 6 chemical elements - C, H, O, N, S and P. Cells are mostly water by weight. Prokaryotes - Small, single cell organisms lacking a membrane-bound nucleus and other subcellular compartments. Bacteria and blue-green algae are examples. Eukaryotes - Cell or organism with membrane-bound nucleus and other well-developed subcellular compartments (organelles). Yeast, fungi, protozoans, plants and animals are eukaryotes.
Basic Components • Biochemical Functional Groups (alcohol, ketones, aldehydes, phosphoester, amine etc) • Proteins • Amino Acids • Peptides --- small linear polymers of amino acids (<=50) • Proteins --- large linear polymers of amino acids • Primary, secondary, tertiary, quaternary structure • Structural, globular and membrane proteins • Nucleic Acids • Carbohydrates • Lipids https://www4.uwsp.edu/chemistry/tzamis/ch260/cellmolecsintro26005.pdf
PROKARYOTE STRUCTURE
The Capsule • Sticky outermost layer called the capsule • Made of polysaccharides (sugar polymers). • The capsule helps prokaryotes cling to each other and to various surfaces in their environment, and also helps prevent the cell from drying out. • In the case of disease-causing prokaryotes that have colonized the body of a host organism, the capsule or slime layer may also protect against the host’s immune system. • Griffith’s Experiment
The Cell Wall • Cell wall, located underneath the capsule (if there is one). • Maintains the cell’s shape, protects the cell interior, and prevents the cell from bursting when it takes up water. • The cell wall of most bacteria contains peptidoglycan, a polymer of linked sugars and polypeptides. • Antibiotics used to treat bacterial infections in humans and other animals act by targeting the bacterial cell wall. • Archea have pseudo-peptidoglycan.
Gram Positive or Gram Negative • Bacteria are classified according to the change in peptidoglycan concentration. • Process of gram staining: • Slide preparation (de-greasing, smear preparation and heat fixing) • Crystal violet for 1 minute (Primary stain) • Gram’s Iodine for 30 seconds (mordant  forming complex with crystal violet) • Ethanol for washing (till the droplets from the slides are colorless) • Safranin for 45seconds (counter stain)
The Plasma Membrane • Underneath the cell wall. • The basic building block phospholipid. • A lipid composed of a glycerol molecule attached a hydrophilic (water- attracting) phosphate head and to two hydrophobic (water-repelling) fatty acid tails. • Plasma membranes of archaea differ from bacteria and eukaryotes. • Opposing phospholipid tails are joined into a single tail, forming a monolayer instead of a bilayer (as in bacteria and prokaryotes). • Stabilize the archeal membrane at high temperatures, allowing them to survive in boiling hot springs.
The Appendages • Prokaryotic cells often have appendages (protrusions from the cell surface) that allow the cell to stick to surfaces, move around, or transfer DNA to other cells. • Thin filaments called fimbriae (singular: fimbria) used for adhesion— help cells stick to objects and surfaces in their environment. • Longer appendages, called pili (singular: pilus). For instance, a sex pilus allows DNA to be transferred between bacterial cells via conjugation. • Type IV pili, help the bacterium move around its environment.
• The most common appendages used for getting around, however, are flagella (singular: flagellum). • These tail-like structures whip around like propellers to move cells through watery environments.
Chromosomes and Plasmids • Prokaryotes have single circular chromosome. • Genome size is much smaller than eukaryotic genome. • Nuclear material dispersed in the cytoplasm, called as the nucleoid. • Plasmids, small rings of double-stranded extra-chromosomal ("outside the chromosome") DNA. • Plasmids carry a small number of non-essential genes and are copied independently of the chromosome inside the cell. • Can be transferred to bacteria and can have special genes for survival. (antibiotic resistance genes  R genes)
EUKARYOTE STRUCTURE
The plant cell has a cell wall, chloroplasts, plastids, and a central vacuole—structures not found in animal cells. Plant cells do not have lysosomes or centrosomes.
The Plasma Membrane • Phospholipid bilayer with embedded proteins that separates the internal contents of the cell from its surrounding environment. • Controls the passage of organic molecules, ions, water, and oxygen into and out of the cell. • Wastes (such as carbon dioxide and ammonia) also leave the cell by passing through the plasma membrane, usually with some help of protein transporters.
The Cytoplasm • Entire region of a cell between the plasma membrane and the nuclear envelope. • Composed of organelles suspended in the gel-like cytosol, the cytoskeleton, and various chemicals. • 70 to 80 percent water. • Proteins, simple sugars, polysaccharides, amino acids, nucleic acids, fatty acids, ions and many other water-soluble molecules are all competing for space and water.
The Nucleus • Stores chromatin (DNA plus proteins) in a gel-like substance called the nucleoplasm. • Nuclear membrane is continuous with the endoplasmic reticulum. • Nuclear pores allow substances to enter and exit the nucleus.
The Nuclear Envelope • Boundary is called as the nuclear envelope. • Boundary is composed of two phospholipid bilayers: inner and outer. • Protein-based pores that control the passage of ions, molecules, and RNA between the nucleoplasm and cytoplasm. • Nucleolus  where the ribosome synthesis occurs.
Chromatin and Chromosomes • Chromosomes are structures within the nucleus that are made up of DNA, the hereditary material. • Eukaryotes have linear chromosomes. • Clearly visible during the dividing stage. • Chromatin is used to describe chromosomes (the protein-DNA complexes) when they are both condensed and de-condensed.
The Nucleolus • Some chromosomes have sections of DNA that encode ribosomal RNA. • A darkly staining area within the nucleus called the nucleolus (plural = nucleoli) • aggregates the ribosomal RNA with associated proteins to assemble the ribosomal subunits • Transported out to the cytoplasm through the pores in the nuclear envelope.
The Ribosomes • Responsible for protein synthesis • Appear as (polyribosomes) clusters called bind form. • Or can also appear as single dots called free form. • May be attached to the cytoplasmic side of the plasma membrane or the cytoplasmic side of the endoplasmic reticulum and the outer membrane of the nuclear envelope
• Large complexes of protein and RNA, consist of two subunits, called large and small subunits. • At the nucleus, the DNA is transcribed into messenger RNA (mRNA). • mRNA travels to the ribosomes, which translate the code provided by the sequence of the nitrogenous bases in the mRNA into a specific order of amino acids in a protein.
The Mitochondria • Power house or energy factories of the cell. • Primary site for the metabolic respiration in eukaryotes. • Number of mitochondria depends on the energy need. • Inner and outer membranes are phospholipid bilayers embedded with proteins that mediate transport across them and catalyze various other biochemical reactions. • The inner membrane layer has folds called cristae increase the surface area into which respiratory chain proteins can be embedded. • The region within the cristae, called the mitochondrial matrix—having enzymes of the metabolic cycle.
The Peroxisomes • Small, round organelles enclosed by single membranes • Carry out redox reactions that oxidize and break down fatty acids and amino acids. • Detoxify many toxins that may enter the body. • Many of these redox reactions release hydrogen peroxide, H2O2, which would be damaging to cells; however, enzymes safely break down into oxygen and water. • Glyoxysomes, which are specialized peroxisomes in plants, are responsible for converting stored fats into sugars.
Vesicles and Vacuoles • Membrane-bound sacs that function in storage and transport. • Vacuoles are larger than vesicles. • Membranes of vesicles can fuse with either the plasma membrane or other membrane systems within the cell. • Enzymes within plant vacuoles break down macromolecules. • The membrane of a vacuole does not fuse with the membranes of other cellular components.
The Centrosome • Microtubule-organizing center found near the nuclei of animal cells. • A pair of centrioles, two structures that lie perpendicular to each other. • Each centriole is a cylinder of nine triplets of microtubules. • Replicates before cell division • Play a role in pulling chromosomes during cell division but role remains still unclear. • Animal cells without centrioles and plant cells lacking centrioles still are able to divide.
The Lysosomes • In animal cells and not in plant cells • Aid the breakdown of proteins, polysaccharides, lipids, nucleic acids, and even "worn-out" organelles.
The Cell Wall • Present in plant cells only. • Rigid  provides protection, structural support and gives shape. • Made of cellulose. • Fungal cell wall made of chitin.
The Chloroplasts • Plant cell organelles carry out photosynthesis. • Have their own DNA and ribosomes. • Chloroplasts have outer and inner membranes, but within the space enclosed by a chloroplast’s inner membrane is a set of interconnected and stacked fluid-filled membrane sacs called thylakoids. • Each stack of thylakoids is called a granum (plural = grana). The fluid enclosed by the inner membrane that surrounds the grana is called the stroma. • Contains chlorophyll.
The Central Plant Vacuole • Plays a key role in regulating the cell’s concentration of water in changing environmental conditions.
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Cell biology

  • 1. Cell Biology Presented By: Mahrukh Shehzadi
  • 2. Course Content • Introduction to prokaryotic and eukaryotic cell differences including cell wall, membrane structure and chemical constituents of the cell. Composition and functions of lipid bilayer, transport across cell membrane and role of glycolipids and glycoproteins as receptors in cellular signaling. The functions, isolation and molecular organization of cellular organelles specifically the endoplasmic reticulum, golgi bodies, ribosomes, lysosome, micro-bodies, mitochondria. The structure and function of chromosomes and role of nucleus in regulation of metabolism. The concept of cell cycle, mitosis and meiosis and cell death. Structure and function of cytoskeleton, centriole and function of cilia and flagella in cell movement. • Practicals: Microscopy and staining techniques; Study of prokaryotic, eukaryotic cells; cellular reproduction; Mitosis: smear/squash preparation of onion roots.
  • 3. Introduction to Cell Biology • Discovery of cell • In 1665, Robert Hooke used an early compound microscope to look at a nonliving thin slice of cork, a plant material; termed them as cells in his publication called Micrographia. In Holland, Anton van Leeuwenhoek used a single-lens microscope to observe pond water and other things; termed them as animalcules • Felix Dujardin termed all substances found inside the cell as sarcode. Later, Jan Evangelista Purkinje, called it as protoplasm. Robert Brown discovered the nucleus.
  • 4. Cell Theory By the late 1830s, botanist Matthias Schleiden and zoologist Theodor Schwann were studying tissues and proposed the cell theory. Schleiden and Schwann proposed spontaneous generation as the method for cell origination, but spontaneous generation (also called abiogenesis) was later disproven. Rudolf Virchow famously stated “Omnis cellula e cellula”… “All cells only arise from pre-existing cells”. The unified cell theory states that: All living things are composed of one or more cells; the cell is the basic unit of life; and new cells arise from existing cells.
  • 5. Fundamentals of Cell Theory • The cell is the fundamental unit of structure and function in living things. • All organisms are made up of one or more cells. • Cells arise from other cells through cellular division.
  • 6. The expanded version of the cell theory can also include: • Cells carry genetic material passed to daughter cells during cellular division • All cells are essentially the same in chemical composition • Energy flow (metabolism and biochemistry) occurs within cells • Adenosine tri phosphate (ATP)
  • 7. Basic Cell Types • Prokaryotes • Eukaryotes ‘Cells’ are considered as the structural and functional unit of life, whether it’s a single cell organism like bacteria, protozoa, or multicellular organisms like plants and animals.
  • 8. Prokaryotic Cells Pro means ‘old,’ and karyon means ‘nucleus,’ So as the name suggest the history of the evolution of prokaryotic cells is at least 3.5 billion years old, but they are still important to us in many aspects like they are used in industries for fermentation (Lactobacillus, Streptococcus), for research work, etc. In comparison to eukaryotic cells, they lack few organelles and are not advanced as eukaryotes.
  • 9. Generalized Structure of Prokaryotes Glycocalyx: This layer function as a receptor, the adhesive also provide protection to the cell wall. Nucleoid: It is the location of the genetic material (DNA), large DNA molecule is condensed into the small packet. Pilus: Hair like hollow attachment present on the surface of bacteria, and is used to transfers of DNA to other cells during cell-cell adhesion. Mesosomes: It is the extension of the cell membrane, unfolded into the cytoplasm their role is during the cellular respiration. Flagellum: Helps in movement, attached to the basal body of the cell. (different types of bacterial cells based on the flagella)
  • 11. Cell Wall: It provides rigidity and support for the cell. Fimbriae: Helps in attachment to the surface and other bacteria while mating. These are small hair-like structure. Inclusion/Granules: It helps in storage of carbohydrates, glycogen, phosphate, fats in the form of particles which can be used when needed. Ribosomes: Tiny particles which help in protein synthesis. Cell membrane: Thin layer of protein and lipids, surrounds cytoplasm and regulate the flow of materials inside and outside the cells. Endospore: It helps cell in surviving during harsh conditions. Permeability: Impermeable Selectively permeable Completely permeable
  • 13. Eukaryotic Cells Eu means ‘new,’ and karyon means ‘nucleus,’ so these are the advanced type of cells found in plant, animals, and fungi. Eukaryotic cells have a well-defined nucleus and different organelles to perform different functions within the cell, though working is complex to understand.
  • 15. Key Difference Between Prokaryotic Cells and Eukaryotic Cells Prokaryotic cells are the primitive kind of cell, whose size varies from 0.5-3µm, they are generally found in single-cell organisms Eukaryotic cells are the modified cell structure containing different components in it, their size varies from 2-100µm, they are found in multicellular organisms. Organelles like mitochondria, ribosomes, Golgi body, endoplasmic reticulum, cell wall, chloroplast, etc. are absent in prokaryotic cells, while these organelles are found in eukaryotic organisms. Though cell wall and chloroplast are not found in the animal cell, it is present in the green plant cell, few bacteria, and algae. The main difference between Prokaryotic cells and the Eukaryotic cell is the nucleus, which is not well defined in prokaryotes whereas it is well structured, compartmentalized and functional in eukaryotes.
  • 16. Cell organelles are present which are membrane-bound and have individual functions in eukaryotic cells; many organelles are absent in prokaryotic cells. In prokaryotes, the cell division takes place through conjugation, transformation, transduction but in eukaryotes, it is through the process of cell division. The process of transcription and translation occurs together, and there is a single origin of replication in the prokaryotic cell. On the other hand, there are multiple origins of replication and transcription occurs in nucleus and translation in the cytosol. Genetic Material (DNA) is circular and double-stranded in Prokaryotes, but in Eukaryotes, it is linear and double-stranded. Prokaryotes reproduce asexually; commonly Eukaryotes have a sexual mode of reproduction. Prokaryotes are the simplest, smallest and most abundantly found cells on earth; Eukaryotes are larger and complex cells.
  • 17.
  • 18. Characteristics of All Cells (Summary) • A surrounding membrane • Protoplasm – cell contents in thick fluid • Organelles – structures for cell function • Control center with DNA
  • 21. Chemical Composition of Cells Cells consist of a collection of simple and complex organic molecules, inorganic molecules, and ions. There are also organized clusters of these called supramolecular complexes. The majority of biomolecules are composed of only 6 chemical elements - C, H, O, N, S and P. Cells are mostly water by weight. Prokaryotes - Small, single cell organisms lacking a membrane-bound nucleus and other subcellular compartments. Bacteria and blue-green algae are examples. Eukaryotes - Cell or organism with membrane-bound nucleus and other well-developed subcellular compartments (organelles). Yeast, fungi, protozoans, plants and animals are eukaryotes.
  • 22. Basic Components • Biochemical Functional Groups (alcohol, ketones, aldehydes, phosphoester, amine etc) • Proteins • Amino Acids • Peptides --- small linear polymers of amino acids (<=50) • Proteins --- large linear polymers of amino acids • Primary, secondary, tertiary, quaternary structure • Structural, globular and membrane proteins • Nucleic Acids • Carbohydrates • Lipids https://www4.uwsp.edu/chemistry/tzamis/ch260/cellmolecsintro26005.pdf
  • 24. The Capsule • Sticky outermost layer called the capsule • Made of polysaccharides (sugar polymers). • The capsule helps prokaryotes cling to each other and to various surfaces in their environment, and also helps prevent the cell from drying out. • In the case of disease-causing prokaryotes that have colonized the body of a host organism, the capsule or slime layer may also protect against the host’s immune system. • Griffith’s Experiment
  • 25. The Cell Wall • Cell wall, located underneath the capsule (if there is one). • Maintains the cell’s shape, protects the cell interior, and prevents the cell from bursting when it takes up water. • The cell wall of most bacteria contains peptidoglycan, a polymer of linked sugars and polypeptides. • Antibiotics used to treat bacterial infections in humans and other animals act by targeting the bacterial cell wall. • Archea have pseudo-peptidoglycan.
  • 26.
  • 27. Gram Positive or Gram Negative • Bacteria are classified according to the change in peptidoglycan concentration. • Process of gram staining: • Slide preparation (de-greasing, smear preparation and heat fixing) • Crystal violet for 1 minute (Primary stain) • Gram’s Iodine for 30 seconds (mordant  forming complex with crystal violet) • Ethanol for washing (till the droplets from the slides are colorless) • Safranin for 45seconds (counter stain)
  • 28.
  • 29. The Plasma Membrane • Underneath the cell wall. • The basic building block phospholipid. • A lipid composed of a glycerol molecule attached a hydrophilic (water- attracting) phosphate head and to two hydrophobic (water-repelling) fatty acid tails. • Plasma membranes of archaea differ from bacteria and eukaryotes. • Opposing phospholipid tails are joined into a single tail, forming a monolayer instead of a bilayer (as in bacteria and prokaryotes). • Stabilize the archeal membrane at high temperatures, allowing them to survive in boiling hot springs.
  • 30.
  • 31.
  • 32. The Appendages • Prokaryotic cells often have appendages (protrusions from the cell surface) that allow the cell to stick to surfaces, move around, or transfer DNA to other cells. • Thin filaments called fimbriae (singular: fimbria) used for adhesion— help cells stick to objects and surfaces in their environment. • Longer appendages, called pili (singular: pilus). For instance, a sex pilus allows DNA to be transferred between bacterial cells via conjugation. • Type IV pili, help the bacterium move around its environment.
  • 33. • The most common appendages used for getting around, however, are flagella (singular: flagellum). • These tail-like structures whip around like propellers to move cells through watery environments.
  • 34. Chromosomes and Plasmids • Prokaryotes have single circular chromosome. • Genome size is much smaller than eukaryotic genome. • Nuclear material dispersed in the cytoplasm, called as the nucleoid. • Plasmids, small rings of double-stranded extra-chromosomal ("outside the chromosome") DNA. • Plasmids carry a small number of non-essential genes and are copied independently of the chromosome inside the cell. • Can be transferred to bacteria and can have special genes for survival. (antibiotic resistance genes  R genes)
  • 35.
  • 37. The plant cell has a cell wall, chloroplasts, plastids, and a central vacuole—structures not found in animal cells. Plant cells do not have lysosomes or centrosomes.
  • 38. The Plasma Membrane • Phospholipid bilayer with embedded proteins that separates the internal contents of the cell from its surrounding environment. • Controls the passage of organic molecules, ions, water, and oxygen into and out of the cell. • Wastes (such as carbon dioxide and ammonia) also leave the cell by passing through the plasma membrane, usually with some help of protein transporters.
  • 39.
  • 40. The Cytoplasm • Entire region of a cell between the plasma membrane and the nuclear envelope. • Composed of organelles suspended in the gel-like cytosol, the cytoskeleton, and various chemicals. • 70 to 80 percent water. • Proteins, simple sugars, polysaccharides, amino acids, nucleic acids, fatty acids, ions and many other water-soluble molecules are all competing for space and water.
  • 41. The Nucleus • Stores chromatin (DNA plus proteins) in a gel-like substance called the nucleoplasm. • Nuclear membrane is continuous with the endoplasmic reticulum. • Nuclear pores allow substances to enter and exit the nucleus.
  • 42. The Nuclear Envelope • Boundary is called as the nuclear envelope. • Boundary is composed of two phospholipid bilayers: inner and outer. • Protein-based pores that control the passage of ions, molecules, and RNA between the nucleoplasm and cytoplasm. • Nucleolus  where the ribosome synthesis occurs.
  • 43.
  • 44. Chromatin and Chromosomes • Chromosomes are structures within the nucleus that are made up of DNA, the hereditary material. • Eukaryotes have linear chromosomes. • Clearly visible during the dividing stage. • Chromatin is used to describe chromosomes (the protein-DNA complexes) when they are both condensed and de-condensed.
  • 45.
  • 46. The Nucleolus • Some chromosomes have sections of DNA that encode ribosomal RNA. • A darkly staining area within the nucleus called the nucleolus (plural = nucleoli) • aggregates the ribosomal RNA with associated proteins to assemble the ribosomal subunits • Transported out to the cytoplasm through the pores in the nuclear envelope.
  • 47.
  • 48. The Ribosomes • Responsible for protein synthesis • Appear as (polyribosomes) clusters called bind form. • Or can also appear as single dots called free form. • May be attached to the cytoplasmic side of the plasma membrane or the cytoplasmic side of the endoplasmic reticulum and the outer membrane of the nuclear envelope
  • 49. • Large complexes of protein and RNA, consist of two subunits, called large and small subunits. • At the nucleus, the DNA is transcribed into messenger RNA (mRNA). • mRNA travels to the ribosomes, which translate the code provided by the sequence of the nitrogenous bases in the mRNA into a specific order of amino acids in a protein.
  • 50. The Mitochondria • Power house or energy factories of the cell. • Primary site for the metabolic respiration in eukaryotes. • Number of mitochondria depends on the energy need. • Inner and outer membranes are phospholipid bilayers embedded with proteins that mediate transport across them and catalyze various other biochemical reactions. • The inner membrane layer has folds called cristae increase the surface area into which respiratory chain proteins can be embedded. • The region within the cristae, called the mitochondrial matrix—having enzymes of the metabolic cycle.
  • 51.
  • 52. The Peroxisomes • Small, round organelles enclosed by single membranes • Carry out redox reactions that oxidize and break down fatty acids and amino acids. • Detoxify many toxins that may enter the body. • Many of these redox reactions release hydrogen peroxide, H2O2, which would be damaging to cells; however, enzymes safely break down into oxygen and water. • Glyoxysomes, which are specialized peroxisomes in plants, are responsible for converting stored fats into sugars.
  • 53. Vesicles and Vacuoles • Membrane-bound sacs that function in storage and transport. • Vacuoles are larger than vesicles. • Membranes of vesicles can fuse with either the plasma membrane or other membrane systems within the cell. • Enzymes within plant vacuoles break down macromolecules. • The membrane of a vacuole does not fuse with the membranes of other cellular components.
  • 54. The Centrosome • Microtubule-organizing center found near the nuclei of animal cells. • A pair of centrioles, two structures that lie perpendicular to each other. • Each centriole is a cylinder of nine triplets of microtubules. • Replicates before cell division • Play a role in pulling chromosomes during cell division but role remains still unclear. • Animal cells without centrioles and plant cells lacking centrioles still are able to divide.
  • 55.
  • 56. The Lysosomes • In animal cells and not in plant cells • Aid the breakdown of proteins, polysaccharides, lipids, nucleic acids, and even "worn-out" organelles.
  • 57. The Cell Wall • Present in plant cells only. • Rigid  provides protection, structural support and gives shape. • Made of cellulose. • Fungal cell wall made of chitin.
  • 58. The Chloroplasts • Plant cell organelles carry out photosynthesis. • Have their own DNA and ribosomes. • Chloroplasts have outer and inner membranes, but within the space enclosed by a chloroplast’s inner membrane is a set of interconnected and stacked fluid-filled membrane sacs called thylakoids. • Each stack of thylakoids is called a granum (plural = grana). The fluid enclosed by the inner membrane that surrounds the grana is called the stroma. • Contains chlorophyll.
  • 59.
  • 60. The Central Plant Vacuole • Plays a key role in regulating the cell’s concentration of water in changing environmental conditions.