2.1.1 Cell Structure (Foundations in Biology) Flashcards Preview

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Flashcards in 2.1.1 Cell Structure (Foundations in Biology) Deck (38)
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1
Q

What are prokaryotic organisms?

A
  • prokaryotic cells
  • single-celled organisms
  • no nucleus present
  • e.g. bacteria
2
Q

What are eukaryotic organisms?

A
  • eukaryotic cells
  • all animal, plant, fungal and protoctist cells

They have:

  • a nucleus surrounded by a nuclear envelope, containing DNA organised and wound into linear chromosomes
  • contains nucleolus
  • cytoplasm
  • cytoskeleton
  • plasma membrane
  • membrane-bound organelles
  • small vesicles
  • ribosomes
3
Q

Draw and label a plant cell

A
4
Q

Draw and label an animal cell

A
5
Q

What are organelles?

A
  • within every cell there are various organelles
  • each with a specific function
6
Q

Describe the structure and function of plasma (cell surface membrane)

A

Structure:

  • membrane found on the surface of animal cells and just inside the cell wall of plant cells and prokaryotic cells
  • made of mainly lipids and protein

Function:

  • regulates the movement of substances into and out of the cell
  • also has receptor molecules, allowing it to respond to chemicals like hormones
7
Q

Describe the structure and function of the cell wall

A

Structure: - rigid structure that surrounds plant cells and fungi

  • mainly made of bundles of cellulose fibres in plant cells
  • made of chitin in fungi

Function:

  • supports plant cells
  • prevents cells from bursting when turgid
  • permeabke and allow solutions to pass through
8
Q

Describe the structure and function of the nucleus, nuclear envelope and nucleolus

A

Structure:

  • large organelle surrounded by a nuclear envelope, which contains many pores
  • nucleus contains chromatin (made from DNA and histone proteins)
  • there is the nucleolus containing RNA and does not have a membrane around it
  • chromatin is genetic material, consisting of DNA wound around histone proteins

Function:

  • nuclear envelope separates contents of nucleus from the rest of the cell
  • some regions of the outer and inner nuclear mebranes fuse together to allow some dissolved substances and ribsomes to pass through
  • pores enable larger substances, such as mRNA, to leave nucleus and some steroid hormones enter from cytoplasm
  • nucleolus is where ribosomes are made
  • nucleus controls the cell’s activities
  • stores the organism’s genome in DNA
  • transmits genetic information
  • provides instruction for protein synthesis
9
Q

Describe the structure and function of lysosomes

A

Structure:

  • a round organelle surrounded by a membrane, with no clear internal structure
  • formed from the Golgi apparatus
  • contains powerful hydrolytic (digestive) enzymes
  • abundant in phagocytic cells such as, neutrophils and macrophages

Function:

  • lysosomes keep the powerful hydrolytic enzymes separate from the rest of the cell
  • engulf old cell organelles and foreign matter, digest them and return the digested components to the cell for reuse.
10
Q

Describe the structure and function of ribosomes

A

Structure:

  • a very small organelle (20nm) that either floats free in the cytoplasm or is attached to the rough endoplasmic reticulum
  • made up of proteins and RNA
  • made in the nucleolus, as two separate subunits, which pass through nuclear envelope into the cytoplasm and then combine
  • not surrounded by a membrane
  • some remain free in cytiplasm and some attach to RER

Function:

  • ribosomes bound to the exterior of the RER are mainly for synthesising proteins that will be exported outside the cell
  • ribosomes free in the cytoplasm are primarily the site of assembly of proteins that will be used inside the cell
11
Q

Describe the structure and function of rough endoplasmic reticulum (RER)

A

Structure:

  • a system of membranes enclosing a fluid-filled space that are continuous wuth the nuclear membrane
  • surface is covered with ribosomes

Function:

  • the intracellular transport system: the cisternae form channels for transporting substances from one area of a cell to another
  • provides a large surface area for ribsomes, which assemble amino acids into proteins
  • these proteins then actively pass through the membrane into the cisternae and are transported to the Golgi apparatus for modification and packaging
12
Q

Describe the structure and function of the smooth endoplasmic reticulum (SER)

A

Structure:

  • system of membranes, containing fluid-filled cavities (cisternae) that are continuous with the nuclear membtane
  • similar to rough endoplasmic reticulum, but with no ribosomes

Function:

  • contains enzymes that catalyse reactions involved with lipid metabolism such as:
  • synthesis of cholesterol
  • synthesis of lipids/phospholipids needed by the cell
  • synthesis of steroid hormones
  • it is involved with absorption, synthesis and transport of lipids from the gut
13
Q

Describe the structure and function of the vesicle

A

Structure:

  • a small fluid-filled sac in the cytoplasm, surrounded by a membrane

Function:

  • transports substances in and out of the cell (via plasma membrane) and between organelles
14
Q

Describe the structure and function of the golgi apparatus

A

Structure:

  • a group of fluid-filled, membrane-bound, flattened sacs
  • vesicles are often seen at the edges of the sacs

Function:

  • proteins are modified by:
  • adding sugar moleculed to make glycoproteins
  • adding lipids molecules to make lipoproteins
  • being folded into their 3D shape
  • processes and packages new lipids and proteins into vesicles that are pinched off then are:
  • stored in the cell
  • moved to the plasma membrane, to be incorporated or exported
  • makes lysosomes
15
Q

Describe the structure and function of the mitochondrion

A

Structure:

  • usually oval shaped 2-5µm long
  • have a double membrane
  • inner membrane is folded to form structures called cristae
  • inside is the matrix, containing enzymes involved in respiration

Function:

  • site of aerobic respiration where ATP is produced
  • they are self-replicating, so more can be made if the cell’s energy needs to increase
  • found in very large numbers in cells that are very active and require a lot of energy
16
Q

Describe the structure and function of chloroplasts

A

Structure:

  • a small, flattened structure found in plant cells and in some protoctists, but a large organelle
  • 4-10µm long
  • surrounded by a double membrane and membranes inside called thylakoid membranes, which contain chlorophyll
  • stacked up in some parts of the chloroplast to form grana
  • grana are linked by lamellae
  • choloroplasts contain loops of DNA and starch grains
  • abundant in leaf cells, particularly palisade and mesophyll layer

Function:

  • site of photosynthesis
  • first stage of photosynthesis, where light energy is trappd by chlorophyll and used to make ATP, occurs in the grana
  • second stage occurs in stroma
17
Q

Describe the structure and function of the centriole

A

Structure:

  • small, hollow cylinders, made of microtubules , which are made of tubulin protein subunits
  • consists of two bundles of microtubules are right angles to each other
  • found in animal cells, but only some plant cells and maybe some unicellular green algae

Function:

  • involved with the separation of chromosomes during cell division:
  • before cell divides, the spindle, made of threads of tubulin, forms from the centrioles
  • chromosomes attach to the middle part of the spindle and motor proteins walk along the tubulin threads, pulling the chromosomes to opposite ends of the cell
  • involved in the formation of cilia and undulipodia (flagella):
  • before the cilia form, the centrioles multiply and line up beneath the cell surface membrane
  • microtubules then sprout outwards from each centriole, forming a cilium or flagella
18
Q

Describe the structure and function of cilia

A

Structure:

  • small, hair-like structures found on the surface membrane of some animal cells
  • formed from centrioles
  • they have an outer membrane and a ring of nine pairs of protein microtubules inside, with two microtubules in the middle

Function:

  • microtubules allow cilia to move
  • moves substances along the cell surface
19
Q

Describe the structure and function of the flagellum

A

Structure:

  • like cilia but longer
  • stick out from the cell surface and are surrounded by plasma membrane
  • same 9+2 formation as cilia

Function:

  • microtubules contract to make flagellum move
  • like outboard motors to propel cells forward
20
Q

Describe how organelles are involved in protein production

A
  1. gene has coded instructions for a protein is transcribed into mRNA
  2. Many mRNA are made and they pass out of the pores in the nuclear envelope to the ribosomes
  3. at the ribosomes, instructions are transplated and insulin molecules are assembled
  4. the molecules pass into the cisternae of the RER and along these hollow sacs
  5. vesicles with these protein molecules are pinched off from the RER and pass, via microtubules and motor proteins to the Golgi apparatus
  6. these vesicles fuse with the Golgi apparatus, where the molcules are modified for release
  7. inside vesicles pinched off from the Golgi apparatus, these molecules pass to plasma membrane
  8. the vesicles and plasma membrane fise and the insulin is released to the outside of the cell
21
Q

What is the cytoskeleton?

A

Structure:

  • a network of protein structures within the cytoplasm consisting of:
  • rod-like microfilaments made of subunits of the protein actin; they are polymers of actin and each microfilament is about 7nm in diameter
  • intermediates filaments about 10nm in diameter
  • straight, cyliner microtubules, made of protein subunits called tubulin, about 18-30 in diameter
  • the cytoskeletal motor proteins, myosins, kinesins and dyneins, are molecular motors
  • they are also enzymes and have a site that binds to and allows hydrolysis of ATP as their energy source

Function:

  • the protein microfilaments within the cytoplasm give support and mechanical strength, keep the cell’s shape stable and allow cell movement
  • microtubules also provide shape and support to cells and help substances and organelles to move through the cytoplasm within a cell
  • they form the track along which motor proteins (dynein and kinesin) walk and drag organelles from one part of the cell to another
  • they form the spindle before a cell divides. these spindle threads enable chromosomes to be moved within the cell
  • microtubules also make up the cilia, flagella and centrioles
  • intermediate filaments are made of a variety of proteins. they:
  • anchor the nucleus within the cytoplasm
  • extend between cella in some tissues, between special junctinos, enabling cell-cell signalling and allowing cells to adhere to a basement membrane, therefore stabilising tissues
22
Q

What are the four main functions of the cytoskeleton?

A
  • Mechanical Strength: the microtubules and microfilaments support the cell’s organelles, keeping them in position
  • Structure: They help to strengthen the cell and maintain its shape
  • Aiding transport: they’re responsible for the movement of materials within the cell. they help the cell to divide (cytokinesis)
  • Enabling movement: proteins of the cytoskeleton can also cause the cell to move. E.g. movement of cilia and flagella are caused by the cytoskeletal protein filaments that run through them
23
Q

Give the characteristics of prokaryotic cells

A
  • extremely small cells (less than 2 um)
  • DNA is circular
  • no nucleus, DNA free in cytoplasm
  • cell wall made of a peptidoglycan not cellulose
  • few organelles and no membrane-bound organelles
  • flagella made of protein flagellin
  • smaller ribosomes
  • have a much less well-developed cytoskeleton with no centrioles
  • e.g. E.coli bacterium

some also have:

  • protective waxy capsule surrounding cell wall
  • small loops of DNA, called plasmids, as well as the main large loop of DNA
  • flagella
  • pili
24
Q

Give the characteristics of eukaryotic cells

A
  • larger cells (10-100um)
  • DNA is linear
  • Nucleus present, DNA inside it
  • no cell wall in animals, cellulose cell wall in plants and chitin cell wall in fungi
  • many organelles
  • flagella made of microtubule proteins in 9+2 formation
  • larger ribosomes
25
Q

Draw a bacterial cell

A
26
Q

What is resolution?

A
  • the ability of an optical instrument to see or produce an image that shows fine detail clearly
  • how detailed the image is
  • how well a microscope distinguishes between two points that are close together
27
Q

How to calculate magnification

A
  • magnification = image size / object size
28
Q

What is magnification?

A
  • how much bigger the image appears compared to the specimen
29
Q

Describe the light (optical) microscope

A
  • light microscopes use light (between 400-700nm)
  • they have a lower resolution than electron microscopes - maximum resolution of about 0.2 um
  • used to look at whole cells or tissues
  • maximum useful magnification is around x 1500
  • relatively cheap
  • easy to use
  • able to study whole organisms
30
Q

Describer the laser scanning confocal microscope

A
  • Laser scanning confocal microscope use laser beams to scan a specimen, which is usually tagged with a fluorescent dye
  • causes the dye to fluoresce. light is then focused through a pinhole onto a detector. detector is hooked to a computer, generating an image, which can be 3D
  • produces a much clearer image than light microscope because the pinhole means out of focus light is blocked
  • can be used to look at objects at different depths in thick specimens
  • high resolution and high contrast images
31
Q

Describe electron microscopes

A
  • they use electrons to form an image
  • higher resolution than light microscopes

Transmission electron microscope (TEM):

  • use electromagnets to focus a beam of electrons, then transmitted through specimen
  • denser parts absorb more electrons, which make it darker in the image
  • provides high resolution images, but can only be used on thin specimens

- Scanning electron microscope (SEM):

  • scan a beam of electrons across the specimen
  • this knocks off electrons from the specimen, which are gathered in a cathode ray tube to form an image
  • show the surface of specimen and can be 3D
  • lower resolution image than TEM
32
Q

What are the maximum resolutions of the three microscopes?

A

Light: - 0.2 um

TEM: - 0.0002 um

SEM: -0.002 um

33
Q

What are the maximum magnifications of the three microscopes?

A

Light: - x 1500

TEM: - more than 1,000,000

SEM: - less than 500,000

34
Q

What is differential staining?

A
  • stains are coloured chemicals which bind to molecules in or on the specimen
  • some bind to specific cell structures, which stains each structure differently to allow easy identification with one preparation
35
Q

Give examples of different types of differential staining

A
  • acetic orcein binds to DNA and stains chromosomes dark red - eosin stains cytoplasm
  • Sudan red stains lipids
  • iodine in potassium iodide solution stains the cellulose in plant walls yellow and starch granules blue/black
36
Q

Why are organelles within eukaryotic cells membrane bound?

A
  • keeps each organelle separate from the rest of the cell, sot that it is a decrete compartment
  • only eukaryotic cells have them
37
Q

Describe the structure of function of the vacuole

A

Structure:

  • surrounded by a membrane called the tonoplast and contains fluid

Function:

  • only plant cells have a large permanent vacuole
  • filled with water and solutes and maintains cell stability because it pushes against the cell wall, making the cell turgid
  • this helps to support the plant if all cells are turgid
38
Q

How do prokaryotes cells divide?

A
  • binary fission
  • do not have linear chromosomes, so cannot carry out mitosis
  • however, before division, DNA is copied so that each new cells receives a large loop of DNA