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CELLS: UNITS OF LIFE. Chapter 4. Cells - basic units of life. Cell membrane separates living matter from the environment. Complex cells house specialized structures, called organelles. Interior of cells consists of cytoplasm.
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CELLS: UNITS OF LIFE Chapter 4
Cells- basic units of life. • Cell membrane separates living matter from the environment. • Complex cells house specialized structures, called organelles. • Interior of cells consists of cytoplasm. • Cell biologists use a variety of microscopes to magnify different types of images of cell contents.
Lens reveal the world of cell The study of cells (cell biology) – began in 1660, when Robert Hooke found out remnants of cells that were once alive in abark from a type of oak tree. Called these units “cells” as they looked like cubicles. In 1673, Antonie van Leeuwenhoek- used lens. “To my great surprise, I found that it contained many very small animalcules, the motions of which were very pleasing to behold. The motion of these little creatures, one among another, may be likened to that of a great number of flies disporting in the air”.
A. The Early Years • Robert Hooke (1660) • 1st person to see the outlines of cells • Antonie van Leeuwenhoek (1673) • developed high magnification lenses • 1st record of microorganisms • Matthias Schleiden & Theodore Schwann (1839) & Rudolph Virchow (1855) • contributed to the celltheory
Cell Theory • All living things are composed of cells. [Schleiden & Schwann]. Cells “elementary particles of organisms, the unit of structure and function” 2. All cells come from preexisting cells. [Virchow]
B. Cell Size • Most are 1-100m in diameter • Smallest? • Largest? • Why can’t cells grow to be as large as a car? • - surface area/volume ratio • - as cell grows, its volume increases more rapidly than its surfacearea
C. Types of Cells 3 basic types: • Bacterial • Archaean Prokaryotic • Eukaryotic
1. Bacterial cells • 1-10 m in diameter • NO membrane-bound organelles • 1 circular DNA molecule located in nucleoid region • plasma membrane, cytoplasm & ribosomes • most have a cell wall(peptidoglycan) • may have a polysaccharide capsule Ex. bacteria & cyanobacteria
Examples A. E. coli- inhabits the intestines of animal species, including humans. B. Streptococcus pyogenes C. Cyanobacteria
Bacteria – classified based on • Cell wall structure • Biochemical characteristics (metabolic pathways and shape) • Bacterial cells may be • Round (cocci) • Rod shaped (bacilli) • Spiral (spirilla) • Comm-shaped (vibrious) • Spindle-shaped (fusiform)
2. Archaean cells • 1-10 m in diameter • NO membrane-bound organelles • cell walls lack peptidoglycan • have characteristics of both bacteria & eukaryotic cells Ex. methanogens, extreme halophiles & extreme thermophiles
Archaea • transport ions within their cells like bacteria • Like eukaryotes histone proteins are associated with their genetic material. • Identified from environments that have extremes of temperature, pH or salinity.
3. Eukaryotic cells • 10-100 m in diameter • nucleus & other membrane-bound organelles • 2 or more linear DNA molecules located in nucleus • plasma membrane, cytoplasm & ribosomes • some have a cell wall (cellulose or chitin) Ex. plants, animals, fungi, protista
Three basic types of cells Bacteria do not contain organelles. Archaea – share features of both bacteria and eukaryotes and have unique biochemical featues. Eukaryotic cells use membranes to increase surface area to allow bigger cells Provide compartmentalization for unique chemical processes.
Generalized Generalized Animal Cell Plant Cell
D. Organellesof Eukaryotic Cells Organelles: • compartmentalize a cell’s activities • keep reactions isolated from one another • increase efficiency in the cell
Organellessynthesize and process proteins Genes- (instructions for building each protein) stored in the nucleus. Connected to nucleus- endomembrane system (series of compartments formed from highly folded membranes. In Rough endoplasmic reticulum (ER)- cell’s proteins are manufactured. Other compartments have unique enzymes which process the synthesized proteins.
Smooth endoplasmic reticulum-lipids are synthesized and modified, toxins – neutralized. Golgi apparatus- complete the processing and sorts proteis for export out of cell or into lysosomes (digestive enzymes). Other compartments within the cell provide energy, contain special enzymes for oxidation reactions, or store useful molecules.
1. Nucleus (exports RNA instructions) • surrounded by a double membrane (nuclear envelope), perforated with nuclear pores • contains DNA & nucleolus (stores RNA nucleotides) • functions to separate DNA from rest of cell
The Endomembrane System a series of compartments made from folded membrane and connected via vesicles • endoplasmic reticulum • rough • smooth • Golgi apparatus • lysosomes
2. Endoplasmic reticulum (ER) interconnected network of membranes extending from nucleus to plasma membrane
Rough ER - studded with ribosomes • site of protein synthesis (most will be exported out of the cell) Free ribosomes in the cytoplasm synthesize proteins that remain in cell. Smooth ER -lacks ribosomes • site of lipid synthesis • contains enzymes that detoxify drugs & poisons
3. Golgi apparatus • stacks of membrane-enclosed sacs
Functions: • links simple carbohydrates together to form starch • links simple carbohydrates to proteins (glycoprotein) or lipids (glycolipid) • completes folding of proteins • temporarily stores secretions (milk)
4. Lysosomes (suicide sacs) • vesicles containing > 40 types of digestive enzymes • function to recycle damaged organelles, break down cellular byproducts & destroy invading microbes
5.Peroxisomes (oxidative reactions) • vesicles containing several types of enzymes (produced in cytoplasm) • found in all eukaryotic cells • function to help cell use oxygen & metabolize potentially toxic compounds • hydrogen peroxide is produced as a by-product of peroxisome activity • the enzyme catalase converts hydrogen peroxide to water
6. Mitochondria • double-membrane • outer is smooth • inner is highly folded (cristae) • #/cell varies • contain DNA • inherited from female parent • site of cellular respiration (production of ATP)
7. Chloroplasts • possess 3 membranes • outer/inner membranes surround stroma • 3rd membrane system folded into flattened sacs (thylakoids) • #/cell varies • contain DNA • found in plants & protists • function in photosynthesis
E. The Endosymbiont Theory Proposes that chloroplasts and mitochondria evolved from once free-living bacteria engulfed by larger archaea. Based on fact that mitochondria & chloroplasts resemble certain bacteria (size, shape, membrane structure & method of making proteins).
Summary • Cell theory • Types of cells • Bacteria do not contain organelles • Archaea – unique cells • Eukaryotic cells- compartmentalization for unique chemical processes. • Organelles- synthesize and process proteins
Nucleus- exports RNA instructions • Nuclear pores- movement of RNA from the nucleus to the cytoplasm • Ribosomes- manufactured in the nucleolus and transported to the cytoplasm. • The endomembrane system- site for protein synthesis and provides mechanisms for protein processing and packaging. • Rough ER- involved in synthesis • Smooth ER and Golgi apparatus- process proteins • Vesicles- used to package and transport proteins
Lysosomes- packages of digestive enzymes- used to recycle cellular components and release nutrient molecules from ingested products. • Peroxisomes store oxidative enzymes – breakdown molecules and protect cell. • Mitochondria and chloroplasts- unique membrane structure • Manipulate energy by manufacturing nutrients or extracting energy from them. • Contain unique DNA
Questions 1.DNA is found in the ---------- of bacterial cells 2.The interior of the cell minus the nucleus is called ---- 3.Name the organelle essential for protein synthesis. 4.The site of synthesis of ribosomes in the nucleus is called ------ 5.Water storing organelle in plant cell is called --- 6.Which organelle contains the digestive enzymes? 7.Name the enzyme present in peroxisomes.