Epithelial specializations and exocrine glands

Question 1

4 characteristics of epithelial tissue

Answer 1

1. Contiguous sheets of cells (more cells than ECM) joined by junctions 2. Polarity 3. Rest on/attached to basal lamina 4. Avascular (receive nutrients via blood vessels)

Question 2

2 components of tissues

Answer 2

1. Cells 2. Extracellular matrix (ECM)

Question 3

Extracellular matrix (ECM)

Answer 3

Region outside cells including complex of macromolecules produced by cells and exported into extracellular space (dissolved substances and fibers)

Question 4

4 functions of epithelial tissue

Answer 4

1. Covering/protection 2. Absorption/secretion (transcellular transport, absorb liquids and gas, secrete mucus, enzymes, hormones) 3. Barrier (compartmentalize) 4. Sensory

Question 5

2 ways to classify epithelia

Answer 5

1. Number of layers 2. Morphology of apical layer

Question 6

3 morphologies of epithelia

Answer 6

1. Squamous 2. Cuboidal 3. Columnar

Question 7

2 main categories of layers of epithelia

Answer 7

1. Simple (one layer) 2. Stratified (multiple layers) which are always classified by the apical cell layer

Question 8

Pseudostratified ciliated columnar epithelia

Answer 8

Specialized epithelia where all cells in contact with basal lamina, but not all reach the apical surface of the epithlium. Nuclei appear as 2-3 layers. Usually columnar and have ciliated cells.

Question 9

Transitional epithelia

Answer 9

Several layers (polyhedral shaped) with most cells in apical layer being dome shaped (relaxed) and some flattened (distended). Variable morphology throughout layers.

Question 10

Keratinized layers

Answer 10

Seen in stratified squamous epithelium (like skin). Should be classified as “stratified squamous, keratinized (or non-keratinized)”

Question 11

Which epithelial layer determines structural specializations and morphology?

Answer 11

Apical layer

Question 12

Microvilli

Answer 12

Small, finger like extensions of apical membrane that project into lumen and have actin filament core and fuzzy coat (glycocalyx). Anchored into the terminal web. Increase surface area and form a brush border.

Question 13

Glycocalyx

Answer 13

Fuzzy coat found on microvilli seen in cross-section

Question 14

Terminal web

Answer 14

Apical array of cytoskeletal filaments where microvilli or stereomicrovilli are anchored

Question 15

Stereocilia

Answer 15

Long, non-motile microvilli which may be branched. Anchored into the terminal web. Increase apical surface area and function in signal generation.

Question 16

Cilia

Answer 16

Hair-like motile projections of apical cell surface anchored via basal bodies and much larger than microvilli. Contain a microtubule core of tubulin dimers which make the axoneme (9+2 arrangement). Associate with dynein ATPase.

Question 17

Flagella

Answer 17

Same 9+2 microtubule core as cilia and only found in spermatozoa

Question 18

Basal bodies

Answer 18

Anchor cilia and contain 9 microtubular triplets (just like centrioles)

Question 19

Anoneme

Answer 19

9+2 microtubule core (9 peripheral doublets with dynein arms and 2 center singlets) made up of tubulin dimers found in cilia

Question 20

Tubulin

Answer 20

Dimerize to make microtubules which form axonemes in cilia

Question 21

Primary cilia dyskinesia

Answer 21

AKA mmotile cilia syndrome. Group of hereditary disorders including Kartagener’s syndrome and Young’s syndrome.

Question 22

Kartagener’s syndrome

Answer 22

Cilia lack dynein arms which cause chronic respiratory disease due to lack of mucus transport and male sterility

Question 23

Young’s syndrome

Answer 23

Cilia have malformed radial spokes and dynein arms which make very thick mucous secretions causing persistent sinusitis and reduced fertility/sterility

Question 24

Terminal bars

Answer 24

Junctional complexes (all 3 types of junctions together) that are visible at the light microscope level

Question 25

Zonula occludens

Answer 25

AKA tight junctions. Belt-like structures close to apical surface. Mediated by occludens and claudins in association with cadherins.

Question 26

Occludens

Answer 26

Mediate zonula occludens with claudens

Question 27

Claudens

Answer 27

Mediate zonula occludens with occludens

Question 28

Cadherins

Answer 28

Associate with occludens, claudins to mediate zonula occludens and associate with catenins to mediate zonula adherens

Question 29

Zonula adherens

Answer 29

AKA adhering junctions. Belt-junctions which are adjacent and below zonula occludens. Mediated by catenins which are linked to actin. Anchor actin filaments for cell adhesion.

Question 30

Catenins

Answer 30

Mediate zonula adherens and link to actin

Question 31

Macula adherens

Answer 31

AKA desmosomes. Below belt junctions and randomly distributed along lateral membrane. Have attachment plaques (contain desmoplakins and pakoglobins) and associate with cytokeratin. Spot welds between cells.

Question 32

Attachment plaques

Answer 32

Found in macula adherens and include desmoplakins and pakoglobins

Question 33

Desmoplakins

Answer 33

Attachment plaque protein in macula adherens

Question 34

Pakoglobins

Answer 34

Attachment plaque protein in macula adherens

Question 35

Cytokeratin

Answer 35

Intermediate filaments which associate with macula adherens and insert themselves at the cytoplasmic face

Question 36

Gap junctions

Answer 36

AKA communicating junctions. Rapid exchange of small molecules between adjacent epithelial cells. Located randomly along lateral membranes. Comprised of paired packed connexons which are formed by connexins) which form aqueous core. Regulated by intracellular levels of Ca2+ and pH.

Question 37

Connexons

Answer 37

Formed by connexins and make up gap junctions

Question 38

Connexins

Answer 38

Integral membrane proteins which form connexons

Question 39

Clostridium perfringens

Answer 39

Bacterial pathogen in gut which produces toxin that binds to claudin proteins and prevent their incorporation into tight junctions. Tight junctions break down. Diarrhea, abdominal pain.

Question 40

Heliobacter pylori

Answer 40

Binds to extracellular domain of zonula occludins and inserts its’ own protein into epithelial cells interfering with ZO function causing cytoskeleton rearrangements and junction failure. Gastric ulcers.

Question 41

Dust mites

Answer 41

Parasitic pathogen (fecal pellets) containing peptidases that cleave occluding ZO proteins. If inhaled cause respiratory epithelium breakdown and expose lungs to inhaled allergens. Asthma attacks.

Question 42

Hemidesmosomes

Answer 42

Junctions that attach basal cell membrane to basal lamina. Site of keratin tonofilament attachment. Linkage to basal lamina is through integrins which link cytoskeleton to ECM for adhesion, traction, and signaling.

Question 43

Keratin tonofilaments

Answer 43

Intermediate filaments which attach to hemidesmosome

Question 44

Integrins

Answer 44

In hemidesmosomes link cell cytoskeleton to ECM

Question 45

Basal membrane infoldings

Answer 45

Multiple invaginations of basal plasma membrane to increase surface area for transport. Many mitochondria are present.

Question 46

Basal lamina

Answer 46

Acellular structure produced by epithelia where epithelial sheets rest. 2 layers include lamina lucida and lamina densa. Can only be observed at electron microscopic level.

Question 47

2 functions of basal lamina

Answer 47

1. Support/attachment for epithelial sheet 2. Molecular sieve/filter

Question 48

Lamina lucida (rara)

Answer 48

Electron lucent layer directly below basal membrane

Question 49

Lamina densa

Answer 49

Electron dense layer directly beneath lamina lucida

Question 50

Basement membrane

Answer 50

Includes 2 layers of the basal lamina + a third layer called the lamina reticularis (produced by connective tissue cells)

Question 51

Exocrine glands

Answer 51

Retain connection to surface they originated from and secrete product via ducts or duct systems.

Question 52

Endocrine glands

Answer 52

Lose connection to epithelial surface of origin. Ductless and secrete products into blood or lymphatic vessels.

Question 53

2 main types of glands

Answer 53

1. Endocrine: secrete substances or hormones directly into blood/lymph 2. Exocrine: secrete substances via ducts Both develop from infoldings of epithelial sheets that penetrate into underlying connective tissue.

Question 54

Classification of exocrine glands

Answer 54

Unicellular (goblet cells in respiratory and digestive tracts) or multicellular (sweat glands, sebaceous glands in scalp, gastric glands in stomach, salivary gland)

Question 55

Further classification of multicellular exocrine glands

Answer 55

1. Complexity (simple or compound) 2. Morphology (tubular, acinar, tubuloacinar)

Question 56

Simple multicellular exocrine glands

Answer 56

Part of an organ or tissue. One duct (can be straight, branched, or coiled) which opens to surface of epithelial sheet. Sweat glands, sebaceous glands in scalp, gastric glands in stomach.

Question 57

How will compound exocrine glands ALWAYS be classified?

Answer 57

Compound tubuloacinar

Question 58

Compound multicellular exocrine glands

Answer 58

The organ themselves. Complex, branched, differentiated duct system (small ducts to larger and larger). Parotid salivary gland, mammory gland, pancreas.

Question 59

3 morphologies of secretory portions of glands

Answer 59

1. Tubular 2. Acinar or alveolar 3. Tubuloacinar

Question 60

Tubular

Answer 60

Can be straight, branched, or coiled (tangled ball of yarn cut)

Question 61

Acinar or alveolar

Answer 61

Ball of cells which can be solid or have space/lumen in the center

Question 62

Tubuloacinar

Answer 62

Branched with acini

Question 63

Acinus

Answer 63

Cluster of cells organized around central lumen

Question 64

Parenchyma

Answer 64

Secretory portions and ducts in compound glands

Question 65

Stroma

Answer 65

Connective tissue components which surround/support parenchyma in compound glands

Question 66

Intralobular ducts

Answer 66

Will be found surrounded by acini (dark areas)

Question 67

Interlobular ducts

Answer 67

Will be found in connective tissue (light areas)

Question 68

2 cell populations in secretory regions

Answer 68

1. Secretory cells 2. Myoepithelial cells

Question 69

2 main types of secretory cells

Answer 69

1. Mucous 2. Serous

Question 70

Mucous cells

Answer 70

Secrete mucinogens (large glycosylated proteins)

Question 71

Serous cells

Answer 71

Secrete solutions of proteins

Question 72

Myoepithelial cells

Answer 72

Located surrounding groups of secretory cells within the basal lamina. Characteristics of smooth muscle cells (contractile filaments) which aids in moving secretions out of secretory portion of glands (like a hand squeezing a stress ball).

Question 73

How is the type of secretion in exocrine glands determined?

Answer 73

By the kind of secretory cells which predominate (serous or mucous)

Question 74

Invasive (infiltrating) ductal carcinoma (2 changes to cells)

Answer 74

Mammory gland duct cells undergo 1. Uncontrolled proliferation 2. Invasion/colonization of stroma

Question 75

4 factors controlling normal epithelial cell proliferation

Answer 75

1. Rate of proliferation = rate of apoptosis 2. Presence of committed transit amplifying daughter cells (overall increase in #) 3. Regulation by signal pathways 4. Regulation of integrin signaling (through hemidesmosomes)

Question 76

How is mammory gland proliferation normally controlled vs in carcinoma?

Answer 76

Normal ways + hormones estrogen and progesterone during development. In carcinoma genetic mutations, gene duplications, incorrect signaling, and hormonal status affect proliferation.

Question 77

Invasive cancerous epithelial cells

Answer 77

Able to move through or destroy basal lamina and colonize in adjacent tissues