Chapter 3

Question 1

cells

Answer 1

• basic functional unit of the body
• variety of shapes and sizes
• similar cells grouped together to form tissue

Question 2

phospholipid bilayer

Answer 2

• semi-permeable double sided membrane
• barrier seperating the intracellular from extracellular environment
• made up of phospholipids and proteins

Question 3

Plama Membrane

phospholipids

Answer 3

• arrangment based on affinity of polarity
• polar head groups: form the exterior (next to polar water)
• nonpolar fatty acids: form hydrophobic center

Question 4

Plasma Membrane

Hydrophobic center restricts the movement of:

Answer 4

polar molecules: water
hydrophilic: water soluble molecules
charged molecules: ions

steriods can pass through on their own

Question 5

integral proteins

Answer 5

span the entire plasma membrane (channels, carriers, transporters)

Question 6

peripheral proteins

Answer 6

found on either side of the plasma membrane (enzymes, receptors, structural support)

Question 7

fluid mosaic model

Answer 7

proteins and phospholipids are not trapped in the membrane but move laterally
(not static, they can change as needed)
(localized distribution of proteins aids in function)

Question 8

cilia

Answer 8

tiny, hair-like structures composed of microtubules that project from the plasma membrane
* found in respiratory tract and uterine tubes (eggs travel by using the cilia)
* found in almost every cell in the body

Question 9

cystic fibrosis

Answer 9

• hereditary disease in which cells make chloride pumps, but fail to install them in the plasma membrane
• thick mucus plugs pancreatic ducts and respiratory tract

Question 10

flagellum

Answer 10

• a single whip/tail like structure that can propel a cell forward
• composed of microtubules
• sperm is the only cell in the human body with a flegellum

Question 11

microvilli

Answer 11

folds in the plasma membrane that increase the surface area for rapid diffusion
* examples: intestines and kidney tubules

Question 12

phagocytosis

Answer 12

• process by which manipulation of the entire cell structure allows for cell to extend around large substances

Question 13

pseudopods

Answer 13

• pseudopods engluf bacteria and dead cells and then fuse together to form a food vacuole
• the food vacuole fuses with a lysosome and the bacteria is digested
• white blood cells can perform amoeboid movement by extending pseudopods (false feet) to pull the cell forward

Question 14

endocytosis

Answer 14

• another strategy for bringing large materials (extracellular fluid) into the cell
• a small part of the membrane surrounding the substances pinches off and is brought in as a vesicle

Question 15

pinocytosis vs receptor-mediated

Answer 15

pinocytosis: non specific endocytosis
receptor-mediated: specific endocytosis

Question 16

exocytosis

Answer 16

• large cellular products (proteins) are moved out of the cell
• the golgi apparatus packages proteins into vesicles that fuse to the plasma membrane and concents spill out of the cell

Question 17

exocytosis - nerve endings

Answer 17

synaptic transmission: neuronal communication
critical for our nervous system (used in signals)

Question 18

cell transport

what structure is selectively permable?

Answer 18

the plasma membrane is selectively permable, meaning that it allows some molecules to cross but not others

• nutrients in, harmful substances out
• keeps needed substances for cellular function inside

Question 19

passive transport

Answer 19

• does not require energy
• molecules move from higher to lower concentration
  (down the concentration gradient)

Question 20

active transport

Answer 20

• requires energy in the form of ATP
• molecules move from lower to higher concentration using ATP (against its concentration gradient)

Question 21

examples of passive transport

Answer 21

• simple diffusion
• lipid soluble molecules
• ions - channel mediated
• water - osmosis
• facilitated diffusion

Question 22

simple diffusion

Answer 22

• solution: consists of a solvent (water) and a solute (molecules dissolved in water)
• occurs when there is a concentration difference between 2 regions, random motion will establish equilibrium via diffusion
• move solute (molecules) down its concentration gradient from high to low
• net diffusion becomes zero, when the concentration of molecules becomes equal on both sides

Question 23

gated channels

Answer 23

• gated channels need a stimulus to open them, so ions can freely flow through
• from high to low
• example of passive transport

Question 24

Passive Transport

facilitated diffusion

Answer 24

• movement of large, polar substances across the plasma membrane by carrier proteins
• ineract with molecules that are too large to cross the membrane on their own.
  * conformational change in structure of carrier protein upon binding
• net movement from high to low concentration (down the gradient)

Question 25

Osmosis

Answer 25

• the diffusion of water across the plasma membrane
• diffusion of a solvent instead of a solute
  Requirements:
• there must be a solute concentration difference on either side of a membrane permable to water
• the membrane must be impermeable to the solute, or the concentration difference will not be maintained
  water moves from area of low solute to an area of high solute concentration

Question 26

osmotically active

Answer 26

solutes that cannot cross and permit osmosis are called osmotically active

Question 27

osmolality

Answer 27

• used to determine the direction of water movement during osmosis
• osmolality: total molality of a solution when you combine all the molecules within it
• no net movement of water

Question 28

tonicity

Answer 28

the effect of a solute concentration on the osmosis of water

Question 29

isotonic

Answer 29

a solution with the same osmolality as the inside of a cell

Question 30

hypotonic

Answer 30

a solution with a lower osmolality than the inside of a cell

Question 31

hypertonic

Answer 31

a solution with a higher osmolality than the inside of a cell

Question 32

active transport

Answer 32

• moves large polar molecules and ions using carriers (pumps)
• movement from an area of low to high concentration (against gradient)
• requires energy: ATP
• 2 forms: primary + secondary active transport

Question 33

primary active transport

Answer 33

• directly unitlizes the energy released by the hydrolysis of ATP
• pump is activated by phosphorylation using a phosphate (Pi) from ATP
• hydrolysis ATP -> ADP

Question 34

steps of primary active transport

Answer 34

1. Ca²⁺ binds
2. activates the ATPase function
3. Pi bonds and ADP is released causing a shape change and Ca²⁺ to be released extracellularly
4. Pi is removed and the carrier protein goes back to its orginal shape, ready for Ca²⁺ to bind again

Question 35

Na⁺/K⁺ Pump

Answer 35

• found in all body cells
• ATPase enzyme that pumps 3 Na⁺ out of the cell and 2 K⁺ into the cell, both moved against thier concentration gradients

Question 36

3 functions of Na⁺/K⁺ Pump

Answer 36

• provides energy for coupled transport of other molecules (used in secondary active transport)
• produces electrochemical impulses in neuron and muscule cells (keeps membrane potential negative)
• maintains osmolality (promotes water movement)

Question 37

steps of Na⁺/K⁺ Pump

Answer 37

1. 3 Na⁺ bind activate ATPase
2. Pi bonds ADP released causing a conformational change, 3 Na⁺ released extracellularly
3. 2 K⁺ bind, Pi released
4. Conformational change again and 2 K⁺ released intracellularly

Question 38

secondary active transport

Answer 38

• indirectly utilizes the energy released by the hydrolysis of ATP
• The Na/K pump maintains a high extracellular concentration
• as Na⁺ moves back into the cell other molecules are transported by the same carrier protein (cotransport)

Question 39

sccondary active transport

cotransport:

Answer 39

the other molecule is moved with sodium (moved in the same direction)
* common way to transport glucose

Question 40

sccondary active transport

countertransport

Answer 40

the other molecule is moved in the opposite direction from sodium

Question 41

carrier-mediated transport characteristics:

specificity

Answer 41

carrier proteins interact only with specific molecules

Question 42

carrier-mediated transport characteristics:

competition

Answer 42

2 different molecules can be transported by the same carrier, but they compete for the carrier protein

Question 43

carrier-mediated transport characteristics:

saturation

Answer 43

when all the carrier proteins in a cell are being utilized to move molecules, they are said to be saturated and have reached the Transport Maxium (Tm)
working as hard as possible, similar to enzymes (can only work so fast before they plateau

Question 44

cytoplasm

Answer 44

• cellular region between the nucleus and the plasma membrane
• has a combination of organelles and cytosol (fluid)

Question 45

cytosol

Answer 45

• fluid that suspends the organelles
• composed of water and many dissolved substances
• comprised of protein fibers - microfilaments and microtubules (which act as a cytoskeleton)

Question 46

cytoskeleton proteins

Answer 46

• support cells shape
• quick reorganization of intracellular environment (contraction of muscle cells)
• form the spindle apparatus that pulls
• serves as a “railroad system” for vesicles and organelles to move along

Question 47

lysosomes

Answer 47

• package of enzymes bond by a membrane
• tend to be acidic
• has lots of different enzymes so it can metabolize many different things

Question 48

autophagy

Answer 48

digestion of cell’s surplus organelles

Question 49

apoptosis

Answer 49

programmed cell death
(lysosomes burst, release all its acid to kill the cell

Question 50

peroxisomes

Answer 50

• resemble lysosomes but contain differnt enzymes and produced by ER
• rxns produce hydrogen peroxide
• catalase breaks down excess peroxide to H₂O and O₂
• neutralize free radicals, detoxify alcohol, other drugs
• break down fatty acids into acetyl groups for mitochondrial use in ATP synthesis

Question 51

mitochondria

Answer 51

• sites of energy production
• has an inner and outer membrane which is separated by an intermembranous space
• inner membrane is folded into cristae
• most cells have mitochondria

Question 52

ribosomes

Answer 52

• protein factories of the cell
• messenger RNA (mRNA) takes genetic info to the ribosome so a protein can be assembled (protein synthesis)
• found free in the cytoplasm or with the rough ER
• broken into 2 subunits composed of proteins and ribosomal RNA (rRNA) while not in use

Question 53

mRNA vs rRNA vs tRNA

Answer 53

mRNA: messanger RNA (takes genetic info form the nucles into the cytoplasm to be transcribed into protein (by the ribosome)
rRNA: ribosomal RNA (subunit of ribosome)
tRNA: transfer RNA (adds aa to the mRNA at the site of the ribosometo make protein strand)

Question 54

rough ER

Answer 54

• rough ER is also called the granular ER
• has ribosomes
• functions in protein modification

Question 55

smooth ER

Answer 55

• smooth ER also called agranular ER
• has many functions depending on the cell

Question 56

golgi apparatus

Answer 56

• consists of stacks of flattened sacs
• modifies proteins receieved from the ER
• these are packaged in vesicles and bud off to fuse with the plasma membrane for exocytosis

Question 57

cell nucleus

Answer 57

most cells have 1 nucleus, mucle cells have hundreds, RBC’s none
* the nucleus is enclosed by the nuclear envelope made of 2 membranes:
1. outer: continuous with rough ER
2. inner
* nuclear pores, join the 2 membranes together

Question 58

functions of nucleus

Answer 58

• control center of the cell
• transmits genetic information (cell division)
• DNA –> DNA (replication)
• initiation of protein synthesis
• DNA –> mRNA (protein synthesis)