Cell Physio

Question 1

Contains DNA, Histones & Chromosomes; has nucleolus

Answer 1

Nucleus

Question 2

Powerhouse of the cell

Answer 2

Mitochondria

Question 3

Involve in detoxification, lipid synthesis, lipid soluble substances; water-soluble substances

Answer 3

Agranular or smooth endoplasmic reticulum (SER)

Question 4

For synthesis of proteins bound for the cell membrane, lysosomes, outside of the cell

Answer 4

Ribosomes of the rough endoplasmic reticulum (RER)

Question 5

For synthesis of proteins bound for the cytoplasm and mitochondria

Answer 5

Free-floating Ribosomes

Question 6

For packaging, molecular tagging, and synthesis of hyaluronic acid & chondroitin sulfate

Answer 6

Golgi Apparatus

Question 7

Replenishes the cell membrane; may contain proenzymes, NT’s

Answer 7

Secretory Vesicles

Question 8

For regression of tissues and Autolysis; Suicide bags of the cells

Answer 8

Lysosomes

Question 9

Degrade membrane-associated proteins; not membrane-bound

Answer 9

Proteosome

Question 10

Contains oxidases, catalases; for detoxification

Answer 10

Peroxisome

Question 11

Site of transcription and processing of rRNA

Answer 11

Nucleolus

Question 12

Location of Electron Transport Chain

Answer 12

Inner Mitochondrial Membrane (Oxidative Phosphorylation)

Question 13

Unique about the mitochondria

Answer 13

Contains mitochondrial DNA that is maternally-derived and does not follow genetic code

Question 14

RER & SER are abundant in which organ?

Answer 14

Liver

Question 15

Subunits of Ribosomes

Answer 15

Prokaryotes: 30s, 50sEukaryotes: 40s, 60s

Question 16

Specialized SER in skeletal muscle

Answer 16

Sarcoplasmic Reticulum

Question 17

Specialized SER in Neurons

Answer 17

Nissl Substance

Question 18

Only substance modified in the RER and not in Golgi Apparatus

Answer 18

Collagen

Question 19

Added to lysosome-bound proteins by the golgi apparatus

Answer 19

Mannose-6-phosphate

Question 20

Lysosomes come from what organelle?

Answer 20

Golgi apparatus

Question 21

Peroxisomes come from what organelle?

Answer 21

Smooth Endoplasmic Reticulum

Question 22

Wear-and-tear pigment that accumulates in lysosomes?

Answer 22

Lipofuscin

Question 23

Motor protein causing transport from center of the cell to the periphery

Answer 23

Kinesin

Question 24

Motor protein causing transport from periphery of the cell to the center

Answer 24

Dynein

Question 25

Which anti-tumor drugs target the microtubules during mitosis?

Answer 25

Vincristine, Taxol

Question 26

Disease with Dynein missing in cilia and flagella

Answer 26

Kartagener’s Syndrome (Situs Inversus, Bronchiectasis, Infertility)

Question 27

What is the explanation for Situs Inversus in Kartagener’s Syndrome?

Answer 27

Defective primary cilia

Question 28

Disk-shaped; for firm intercellular adhesions

Answer 28

Macula densa (Desmosomes)

Question 29

Ring-shaped; increases surface area for contact

Answer 29

Zonula adherens (Fascia adherens)

Question 30

Reticular pattern; divides cell into apical and basolateral side

Answer 30

Zonula occludens (Tight junctions)

Question 31

For intercellular communication

Answer 31

Gap junctions

Question 32

Functional unit of Gap junctions

Answer 32

Connexon

Question 33

Movement of substances in both the apical and basolateral side

Answer 33

Transcellular Transport

Question 34

Movement of substances between cells through tight junctions

Answer 34

Paracellular Transport

Question 35

Guardian of the cell that divides the body into ECF and ICF compartments

Answer 35

Cell membrane

Question 36

Mainly determines membrane fluidity and permeability to water soluble structure

Answer 36

Cholesterol

Question 37

Anchors protein to outer leaflet

Answer 37

Glycolipid: Glycosylphosphatidylinositol (GPI)

Question 38

Which disease involves a mutation in a gene of Chromosome 7 that encodes for an ABC transporter called CFTR?

Answer 38

Cystic Fibrosis

Question 39

Endocytosis: For proteins; requires ATP and extracellular calcium

Answer 39

Pinocytosis

Question 40

Endocytosis: usually receptor-mediated; usually by WBC’s and macrophages; for larger substances like bacteria, cell debris, dead cell

Answer 40

Phagocytosis

Question 41

Secretion of Hormones, Neurotransmitters from intracellular vesicles (mediated by SNARE proteins); results in excretion of Residual Body

Answer 41

Exocytosis

Question 42

Predominant Cation in ECF

Answer 42

Na+ (Sodium)

Question 43

Predominant Anion in ECF

Answer 43

Cl- (Chloride)

Question 44

Predominant Cation in ICF

Answer 44

K+ (Potassium)

Question 45

Predominant Anion in ICF

Answer 45

PO4- (Phosphate)

Question 46

In each compartment, total number of Cations should EQUAL total number of Anions

Answer 46

Principle of Macroscopic Electroneutrality

Question 47

“Where Sodium goes, Water follows…”

Answer 47

90% of the solutes in the ECF is Na+ (Sodium) making it a reasonable indicator for osmolarity

Question 48

Indicator molecule for TBW

Answer 48

Deuterium Oxide, Antipyrine

Question 49

Indicator molecule for ECF

Answer 49

Inulin, Mannitol

Question 50

Indicator molecule for Plasma

Answer 50

124I-Labeled Albumin

Question 51

Osmoles per kilogram of water; Independent of Temperature

Answer 51

Osmolality

Question 52

Osmoles per liter of water; varies with Temperature

Answer 52

Osmolarity

Question 53

Clinical estimate of plasma osmolality can be obtained using:

Answer 53

Sodium concentrationGlucose concentrationUrea concentration

Question 54

Poisoning that increases Osmolar Gap

Answer 54

Alcohol intoxication and Ethylene Glycol poisoning

Question 55

Diffusion of water from a solution of low solute concentration to a solution of high solute concentration

Answer 55

Osmosis

Question 56

Driving force of Osmosis that is dependent on number of molecules

Answer 56

Osmotic Pressure

Question 57

Uses impermeate solutes; can change cell volume

Answer 57

Isotonic, Hypertonic, Hypotonic

Question 58

Uses permeate solutes; can change cell volume only transiently

Answer 58

Isoosmotic, Hyperosmotic, Hypoosmotic

Question 59

Will attract water to itself

Answer 59

Hypertonic solution

Question 60

Will donate water to opposite compartment

Answer 60

Hypotonic solution

Question 61

Example of impermeate solute

Answer 61

Glucose (effective osmole)

Question 62

Example of permeate solute

Answer 62

Urea (ineffective osmole)

Question 63

Effective osmole used in the treatment of brain edema

Answer 63

Mannitol

Question 64

Effect of permeate solutes on osmotic gradient

Answer 64

Decreases osmotic gradient

Question 65

Osmotic pressure from large molecules

Answer 65

Oncotic Pressure

Question 66

Weight of the volume of a solution divided by weight of equal volume of distilled (pure) water

Answer 66

Specific gravity

Question 67

Number between zero and one that describes the ease with which a solute permeates a membrane

Answer 67

Reflection Coefficient / Osmotic Coefficient

Question 68

Solute is impermeable

Answer 68

Reflection Coefficient = 1

Question 69

Solute is neither permeable nor impermeable

Answer 69

Reflection Coefficient = between 0 to 1

Question 70

Solute is permeable

Answer 70

Reflection Coefficient = 0

Question 71

Isotonic NaCl infusion; Gain of H2O and Na; Increase in ECF volume

Answer 71

Isoosmotic volume expansion

Question 72

Diarrhea; Loss of H2O and Na; Decrease in ECF volume

Answer 72

Isoosmotic volume contraction

Question 73

High NaCl intake, Conn’s syndrome; Gain of Na; Increase in ECF osmolarity and volume; Decrease ICF volume

Answer 73

Hyperosmotic volume expansion

Question 74

Sweating, Fever, Diabetes Insipidus; Loss of H2O; Increase in ECF osmolarity; Decrease in ECF and ICF volume

Answer 74

Hyperosmotic volume contraction

Question 75

SIADH; Gain of H2O; Decrease in ECF osmolarity; Increase in ECF and ICF volume

Answer 75

Hypoosmotic volume expansion

Question 76

Adrenal insufficiency, Diuretics overuse; Loss of Na; Decrease in ECF osmolarity and volume; Increase in ICF volume

Answer 76

Hypoosmotic volume contraction

Question 77

0.9% NaCl (PNSS) or Lactated Ringers (LR); Increases ECF volume exclusively

Answer 77

Isotonic Solution

Question 78

0.45% NaCl or 5% Dextrose in water (D5W); Increases both ECF and ICF volume

Answer 78

Hypotonic Solution

Question 79

3% NaCl or 5% NaCl; Increases ECF volume and Decreases ICF volume

Answer 79

Hypertonic Solution

Question 80

Passive, Downhill transport; Not carrier-mediated, No metabolic energy used, Not dependent on Na+ gradient

Answer 80

Simple Diffusion

Question 81

Passive, Downhill transport; Carrier-mediated, No metabolic energy used, Not dependent on Na+ gradient

Answer 81

Facilitated Diffusion

Question 82

Active, Uphill transport; Carrier-mediated, With metabolic energy used (direct), Not dependent on Na+ gradient

Answer 82

Primary Active Transport

Question 83

Secondary Active; Carrier-mediated, With metabolic energy used (indirect), Dependent on Na+ gradient (solutes move in same direction as Na+ across cell membrane)

Answer 83

Co-transport

Question 84

Secondary Active; Carrier-mediated, With metabolic energy used (indirect), Dependent on Na+ gradient (solutes move in opposite direction as Na+ across cell membrane)

Answer 84

Counter-transport

Question 85

Secondary Active Transport indirectly relies on:

Answer 85

Na-K-ATPase pump

Question 86

Saturation of Active Transport

Answer 86

Tm occurs once all transporters are used

Question 87

Stereospecificity of Active Transport

Answer 87

Recognizes “D” or “L” forms

Question 88

Competition of Active Transport

Answer 88

Chemically-related solutes may compete

Question 89

Which is faster at low solute concentration: Facilitated or Simple?

Answer 89

Facilitated

Question 90

Which is faster at high solute concentration: Facilitated or Simple?

Answer 90

Simple

Question 91

In Na-K-ATPase pump, how many Na+ goes out?

Answer 91

3

Question 92

In Na-K-ATPase pump, how many K+ goes in?

Answer 92

2

Question 93

Transport Mechanism of Oxygen, Nitrogen, CO2, Alcohol, Lipid Hormones, Anesthetic drugs

Answer 93

Simple Diffusion

Question 94

Transport Mechanism of D-glucose transport to the muscles and adipose, Amino Acid transport

Answer 94

Facilitated Diffusion

Question 95

Transport Mechanism of Na-K-ATPase pump, Ca-ATPase pump in cell membrane and SR, H-K ATPase pump in stomach, H- ATPase pump in intercalated cell of kidney, Multi-drug resistance transporters

Answer 95

Primary Active Transport

Question 96

Transport Mechanism of SGLT-1 in small intestine, SGLT-2 in the PCT, Na-K-2Cl in ascending tubule, Na-Ca exchange in almost all cells, Na-H exchange in PCT

Answer 96

Secondary Active Transport

Question 97

Ca-ATPase pump in the cell membrane

Answer 97

Plasma membrane associated Ca ATPase (PMCA)

Question 98

Ca-ATPase pump in sarcoplasmic reticulum an endoplasmic reticulum

Answer 98

Sarcoplasmic and ER Ca-ATPase (SERCA)

Question 99

Functions of Na-K-ATPase pump

Answer 99

Prevents cellular swelling; contributes to RMP

Question 100

Functional subunit by Na-K-ATPase pump inhibited by Cardiac Glycosides

Answer 100

Alpha subunit

Question 101

In all epithelial cells, Na-K-ATPase pump is found in the basolateral side EXCEPT:

Answer 101

Choroid Plexus

Question 102

Why do RBC’s swell when chilled?

Answer 102

Decrease ATP synthesis (Decrease activity of Na-K-ATPase pump)

Question 103

Receptors for Fat-soluble substances; Binding to nuclear or cytoplasmic receptors that causes transcription of genes

Answer 103

Intracellular Receptors

Question 104

Membrane Receptor: Transduces chemical signal into electrical signal

Answer 104

Ion-channel linked Receptor

Question 105

Membrane Receptor: Activates cGMP phosphodiesterase; Decreases cGMP; Closes cGMP-dependent ion channels

Answer 105

G-Protein Coupled Receptor with Alpha-t subunit (Transducin)

Question 106

Membrane Receptor: Activated by Guanine Nucleotide Exchange Factors (GEFs); Inactivated by GTPase-accelerating proteins (GAPS), RGS proteins (regulation of G Protein signaling)

Answer 106

G-Protein Coupled Receptor (GTP-activated)

Question 107

Membrane Receptor: Activates Adenylyl cyclase (converts ATP to cAMP); Activates Protein Kinase A (PKA)

Answer 107

G-Protein Coupled Receptor with Alpha-s and Alpha-i subunit

Question 108

Membrane Receptor: Phospholipase C (PLC) ➡️ PIP2 ➡️ PIP2 splits into InsP3 or IP3 (releases Calcium from ER) and DAG (activates Protein Kinase C)

Answer 108

G-Protein Coupled Receptor with Alpha-q subunit

Question 109

Catalytic Receptor: Converts GTP to cGMP; Activates Protein Kinase G; Phosphorylates Proteins (eg: ANP, NO)

Answer 109

Receptor Guanylyl Cyclases

Question 110

Catalytic Receptor: Attaches to Type 1 subunit; Phosphorylates Serine/Threonine residues on Type 2 subunit; Activates Effectors (eg: THF-Beta)

Answer 110

Receptor Serine/Threonine Kinases

Question 111

Catalytic Receptor: eg: NGF, EGF, PDGF, IGF-1, Insulin

Answer 111

Receptor Tyrosine Kinase

Question 112

Catalytic Receptor: No intrinsic Tyrosine Kinase Activity; Associated with proteins that have Tyrosine Kinase Activity, including Tyrosine Kinases of Src Family and Janus Family (JAK) (eg: EPO)

Answer 112

Tyrosine-associated Kinase Receptors

Question 113

Cytosolic fragment released to the nucleus which causes transcription of genes (eg: Sterol Regulatory Element-Binding Protein (SREB) of the ER - promotes Cholesterol Synthesis)

Answer 113

Regulated Intramembrane Proteolysis

Question 114

Regulated Intramembrane Proteolysis (RIP) of amyloid B-protein precursor causes accumulation of amyloid B-protein in which disease?

Answer 114

Alzeimer’s Disease