Deck 1: Cellular Biology

A) GTP
B) AMP
C) ATP
D) GMP

A) Paracrine
B) Autocrine
C) Neurohormonal
D) Hormonal

A) Peripheral membrane proteins
B) Integral membrane proteins
C) Glycoproteins
D) Cell adhesion molecules

A) small lipid-soluble molecules.
B) large protein molecules.
C) micronutrients used to produce ATP.
D) electrically charged molecules.

A) osmosis.
B) diffusion.
C) hydrostatic pressure.
D) active transport.

A) Metabolic absorption
B) Communication
C) Secretion
D) Respiration

A) 5
B) 10
C) 15
D) 20

A) oxygen.
B) ribosomes.
C) amphipathic lipids.
D) ligands.

A) Single circular chromosome
B) Nucleus
C) Freely floating nuclear material
D) No organelles

A) decreased fibronectin.
B) increased collagen.
C) decreased elastin.
D) increased glycoproteins.

A) Cholesterol decreases the membrane fluidity of the erythrocyte, which reduces its ability to carry oxygen.
B) Cholesterol decreases the membrane fluidity of erythrocytes, which reduces its ability to carry hemoglobin.
C) Cholesterol increases the membrane fluidity of erythrocytes, which allows binding of excess glucose.
D) Cholesterol increases the membrane fluidity of erythrocytes, which prolongs its life span beyond 120 days.

A) digestion, glycolysis and oxidation, and the citric acid cycle.
B) diffusion, osmosis, and mediated transport.
C) S phase, G phase, and M phase.
D) metabolic absorption, respiration, and excretion.

A) digestion.
B) glycolysis.
C) oxidation.
D) citric acid cycle.

A) osmolality.
B) osmolarity.
C) osmotic pressure.
D) effective osmolality.

A) Cell junction
B) Gap junction
C) Desmosomes
D) Tight junctions

A) concentration of sodium.
B) plasma proteins.
C) hydrostatic pressure.
D) availability of membrane transporter proteins.

A) Has a positive charge
B) Migrates toward the positive pole
C) Is sodium
D) Is potassium

A) solute.
B) substrate.
C) receptor.
D) ribosome.

A) Electron-transport chain
B) Aerobic glycolysis
C) Anaerobic glycolysis
D) Oxidative phosphorylation

A) Because potassium has a greater concentration in the intracellular fluid (ICF)
B) Because sodium has a greater concentration in the extracellular fluid (ECF)
C) Because the resting plasma membrane is more permeable to potassium
D) Because there is an excess of anions inside the cell

A) Active mediated transport
B) Uniport
C) Antiport
D) Symport

A) Cells will become hydrated.
B) Cells will swell or burst.
C) Cells will shrink.
D) Cells will divide.

A) anaphase.
B) telophase.
C) prophase.
D) metaphase.

A) K⁺ rushing into the cell
B) Na⁺ rushing into the cell
C) Na⁺ rushing out of the cell
D) K⁺ rushing out of the cell

A) platelets.
B) epidermal cells.
C) connective tissue cells.
D) fibroblast cells.

A) Potassium gates open, and potassium rushes into the cell changing the membrane potential from negative to positive.
B) Sodium gates open, and sodium rushes into the cell changing the membrane potential from negative to positive.
C) Sodium gates close, allowing potassium into the cell to change the membrane potential from positive to negative.
D) Potassium gates close, allowing sodium into the cell to change the membrane potential from positive to negative.

A) endocytosis.
B) pinocytosis.
C) phagocytosis.
D) exocytosis.

A) simple columnar epithelium.
B) ciliated simple columnar epithelium.
C) stratified columnar epithelium.
D) pseudostratified ciliated columnar epithelium.

A) active mediated transport.
B) the antiport system.
C) receptor-mediated endocytosis.
D) passive transport.

A) By passive electrolyte channels
B) By coupled channels
C) By adenosine triphosphate enzyme (ATPase)
D) By diffusion

A) By active-mediated transport (active transport)
B) By active diffusion
C) By passive osmosis
D) By passive-mediated transport (facilitated diffusion)

A) Hydrostatic pressure
B) Osmosis
C) Diffusion
D) Active transport

A) Provide growth factor for tissue growth and development
B) Block progress of cell reproduction through the cell cycle
C) Restrain cell growth and development
D) Provide nutrients for cell growth and development

A) G₁.
B) S.
C) M.
D) G₂.