Cell Structure

Consists of 2 bundles of microtubules at right angles to each other

Microtubules are made of tubulin protein subunits, arranged to form cylinder

Spindles of tubulin from from centrioles before cell divides - chromosomes attach to middle of spindle and motor proteins walk along tubulin threads pulling chromosomes either ends of cell

Centrioles involved formation cilia and undulipodia

System of membranes containing cisternae that are continuous with the nuclear membrane

No ribosomes on surface

Membrane bound flattened sacs

Made from cisternae

Bring materials to and from golgi apparatus

Contains hydrolytic enzymes

Engulfs and digests old organelles nad debris then returns to be reused

Hydrolytic enzymes

Proteins and lipids modified e.g adding sugar molecules to make glycolipids/proteins or folded into 3D shape

Packaged into vesicles then:

Stored in cell

Moved to plasma membrane

Contains enzymes that catalyse reactions involved with lipid metabolism:

Synthesis of cholesterol

Synthesis of lipids/phospholipids

Synthesis of steroid hormones

Involved with absorption, synthesis and transport of lipids

Lysosomes and centrioles

Bundles cellulose fibres

Network protein structures within cytoplasm

Consists of:

Microfilaments - polymers of actin, 7nm diameter

Intermediate filaments - 10nm diameter

Microtubules - made tubulin, straight and cylindrical

Cytoskeletal motor proteins, myosins, kinesins, dyneins

Enzymes - site to allow binding of ATP for hydrolysis as energy source

Give support and mechanical strength

Keep cell shape stable and allows cell movement

Provide shape and support to cells and help substances and organelles move through cytoplasm:

Form track which motor proteins walk and drag organelles along

Form spindle before cell divides

Make up cilia, undulipodia and centrioles

Anchor nucleus within cytoplasm

Stabalise tissues extending between cells

Made of bundles of cellulose fibres

Outside of cell membrane

Chitin

String and can prevent plant cells from bursting when turgid

Provides strength and support

Maintains cell shape

Contributes to shape and strength of whole plant

Permeable to allow solutions to pass through

1. Has coded instructions for a protein housed of chromatin. Gene is transcribed into length of mRNA in nucleus

2. Leaves nucleus through nuclear pore

3. To a ribosome on RER. mRNA is translated

4. Packaged into vesicles and move travel towards golgi body via microtubules and motor proteins

1. Fuse with golgi body

2. Modifies and processes proteins and repackages molecules into vesicles

3. From golgi body towards plasma membrane

4. With plasma membrane

5. Opens to release molecules outside of cell

Exocytosis

Active process to energy is needed

Within the membrane

Organelles

Where cellular functions and chemical reactions take place

Flagella

Made of tubulin

Protrusions from cell, surrounded by cell surface membrane

Contain microtubules

Formed from centrioles

Airway - push away mucus

1 Cilium - contains receptors and allows cells to detect signals about immediate environment

Small bags, formed from Golgi body

Each surrounded by single membrane

Contain hydrolytic enzymes

Golgi body

Hydrolytic enzymes

System of membranes, containing fluid filled cavities (cisternae) that are continuous with nuclear membrane

Coated with ribosomes

Intracellular transport system: transport substances around cell

Provides large S.A fro ribosomes which assemble AAs into proteins - proteins actively pass through membrane into cisternae and transported to golgi body

Site of ATP production during aerobic respiration

Self-replicating

Cells where much metabolic activity takes place

2-5 micrometers

Spherical, rod-shaped or branched

Surrounded by 2 membranes with fluid-filled space between them. Inner membran’s folded into cisternae

Inner part of mitochondria is fluid filled matrix

4-10 micrometers

Site of photosynthesis - light energy trapped inside chlorophyll and used to make ATP

Surrounded by double membrane - inner is continuous with stacks of membrane sacs (thylakoid) containing chlorophyll

Contains loops of DNA and starch grains

Surrounded by membrane called tonoplast

Contains cell sap/fluid

Maintains cell stability - when full, pushes on cell wall making it turgid. If all plant cells turgid, supports whole plant

Water and solutes

Plant cells

Plant and some protocists

Lysosomes and centrioles

Plasma membrane

Nucleus

Nucleolus

Nuclear envelope

SER

RER

Ribosomes

Mitochondria

Golgi body

Cytoskeleton

Vacuole

Cellulose cell wall

Plasma membrane

Nucleus

Nucleolus

Nuclear envelope

RER

SER

Cytoplasm

Golgi body

Ribosomes

Mitichondria

Cilia

Centrioles

Cytoskeleton

Lysosomes

Peroxisomes

Nucleus

Nucleolus

Nuclear envelope

SER

RER

Golgi body

Ribosomes

Mitochondria

Lysosomes

Plasma membrane

Chloroplasts

Centrioles

Flagella

Cilia

Cell wall

Seperate them from rest of cell

Eukaryotic (prokaryotic don’t)

Provides division of labour meaning every cell can carry out its functions efficiently

Seperates contents of nucleus from rest of cell

Where ribsomes are made

Enable larger substances to leave or enter nucleus

Organisms genes

Control centre of cell

Stores organisms genome

Transmits genetic material

Provides instructions for proteinsynthesis

Surrounded by double membrane - nuclear envelope with contains pores

Found inside nucleus

Doesn’t have a membrane

Contains RNA

The genetic material consisting of DNA wound around histone proteins

Spread out and extended when not dividing

Condenses and coils tightly into chromsomes when about to divide

Photograph of an image seen using an electron microscope

The number of times larger an image appears comapred with the size of the image

Small sturctures within cells, each of which has a specific function

Photograph of an image seen using an optical microscope

Measure of the microscopes ability to distinguish between two points which are close together. The clarity of the image

The clearer the image

Measuring device placed in eyepiece of microscope and acts as ruler when viewing objects under microscope

Measuring device placed on stage of microscope to calibrate value of eyepiece divisions at different magnifications

Microorganisms

Plasma membrane

Cytoplasm

Ribosomes

DNA and RNA

Eukaryotic - nucleus within membrane, nucleolus present, linear DNA, membrane-bound organelles, larger ribosomes, when present has cellulose cell wall, flagella have 9+2 microtubule arrangement

Prokaryotic - no nucleus, no nucleolus, circulaar DNA, no membrane bound organelles, smaller ribosomes, when present has peptidoglycan cell wall, simple flagella

Area within cytoplasm where DNA is positioned

Binary fission

Mitosis

Hvae circular DNA rather than linear chromosomes so can’t carry out mitosis

DNA copied so each new cell recieves large loop of DNA and smaller plasmids

Theory as how eukaryotic cells arose from proakryotic cells

Some prokaryotic cells with infolded membranes inavded or were engulfed by another prokaryotic but not digested. As invaded, plasma membrane folded inwards around invading cell, producing double membrane (what are now chloroplasts and mitochondria).

Small ribosomes

Loops of DNA

Contains RNA

Divide by binary fission

Membrane bound organelles

Smaller hair-like projections on prokaryotic cells that allow bacteria to adhere to host cells or each other to allow passage of plasmid DNA

x40

x100

x400

x1000

How much bigger an image appears compared with the origional object

Linear - is specimen seen at magnified x100, it appears to be 100 times wider and longer than it actually is

Light - lower mag, lower res, living and dead, staining, uses beam of light

Electron - higher mag, higher resolution, dead only, no staining, uses beam of electrons

200nm

x1500

x200,000

Cheap, easy to use, portable, study whole organisms

Resolution limited so can’t magnify any higher whilst giving clear image

Ribosomes

magnification of objective lense x magnification of eyepiece lense

1. Specimen on slide, placed on stage and clipped into plate

2. Rotate nosepiece so lowest powered objective lense over specimen

3. Adjust coarse adjustment knob while looking into eyepiece until image clear and in focus

4. Whilst viewing image, adjust iris diaphram for optimum light

5. Rotate nosepiece to x10 objective lense over specimen and use fine adjustment to focus

6. Repeat with x40 objective lense

Focal microscopes

Use laser light to scan specimen point by point and assemble on computer pixel info into one image

Focal

Medical profession

Chemically fixed by being dehydrated and stained

Beams of electrons pass through specimen, stained with metal salts. Some electrons pass through and are focused on screen

2D black and white

x2,000,000

Uses beam of electrons - electrons don’t pass through whole specimens but cause secondary electrons to bounce off specimens surface and focused onto screen

3D black and white

Dead and viewed while in a vaccum

Light

Thinly - allows more light to pass through specimen so structures can be seen in more detail

So can see in detail and distinguish features/organelles

Observing live specimens

Some microscopes use light differences rather than absorption - uses dark background which the illuminated specimen shows up

Coloured chemicals that bind to molecules in or on specimen, making it easy to see

DNA - dark red

Acetin orcein

Cytoplasm - pink

Eosin

Sudan red

Lipids - red

Iodine

Starch and cellulose - blue/black

Nucleus - blue

Nile blue

Differential staining

When different stains applied to same specimen to stain different structures

Observing bacteria - puts into categories, gram positive or gram negative

Thick peptidoglycan cell walls that retain stain

9+2

Protein syntheis of proteins exported out of cell

Proteins syntheisis of proteins used inside of cell

ribosomal RNA

Nucleus as 2 seperate subunits and pass out through nuclear envelope into cytoplasm and combine