exam 1, week 2

Question 1

fertilization occurs in

Answer 1

ampulla

Question 2

general timeline

Answer 2

Day 1- zygote
Day 2- 2 blastomeres
Day 3- about 8 cells, end of synchronous division
Day 4- Morula
Day 5-6- blastocyte,
then hatching of zona pellucida-> late blastocyte, where every it is, it will attach
Day 6-8- implantation
Day 10: embryonic cells fill in the layer between trophoblast and yolk sak/amniotic cavity
Day12: chorionic cavity develops within extraembryonic mesoderm
Day 13: yolk sak divides into primary and seonddary umbilical vesicle
Day 14- chorionic cavity isolate embryo, connecting stalk formed

review pictures

Question 3

blastomeres

Answer 3

First 2 cells after first cleavage

Question 4

Morula

Answer 4

ball of 16 cells, made after 4 consecutive sets of division, still in zona pellucida (day 3-4)

Question 5

blastocyst

Answer 5

cells in morula shrink leaving spaces due to getting rid of excess storage in the cytoplasm. Cell migrate to the edge allowing morula to shrink (day 4-5)

Question 6

Trophoblast layer

Answer 6

outer edge of cells, become placenta

Question 7

Embryooblast

Answer 7

inner cell becomes embryo

Question 8

Blastocyst cavity

Answer 8

open space

Question 9

further development

Answer 9

o Early hypoblast forms, otherwise undifferentiated embryoblast
o Blastocystic cavity-> exocelomic cavity
o Embryoblast-> epiblast
o Hypoblast-> exocelomic membrane
o Amniotic cavity is formed (later becomes yolk sak)
o Cytotrophoblast (cellular layer), synctyiotriphoblast (contacts maternal blood stream for nutrients and immunoresponse)
o Bilaminar disc embryo- epiblast and hypoblast
Day 10- embryonic cells fill in the layer between trophoblast and yolk sak/amniotic cavity, extra-embryonic mesoderm forms
o Chorionic cavity develops by cavitation within extraembryonic mesoderm (chroionic membrane (somatropleuric layer) and exocoelomic (splanchnopleuric or Heuser’s) Membrane)
o Yolk sak divides to primary umbilical vesicle and secondondary umbilical
o Chorionic cavity isolates embryo, connecting stalk formed

Question 10

Parthenogenesis

Answer 10

development of zygote without fertilization, oocytes will divide

Question 11

Cloning-

Answer 11

for stem cell research, for reproductive and therapeutic purposes

Question 12

CNS

Answer 12

brain and spinal cord

Question 13

white matter

Answer 13

myelinated axon tracts, relays info

on the outside of spinal cord and inside of brain

Question 14

gray matter

Answer 14

cell bodies, dendrites, unmyelinated, neurolgia, blood

inside of spinal, inside brain

Question 15

myelin made in CNS

Answer 15

oligodendrocytes

Question 16

myeline made in PNS

Answer 16

schwann cells

Question 17

PNS

Answer 17

peripheral nerves, cranial nerves (12 pairs), spinal nerves (31 pairs)
Collection of PNS cell bodies is a ganglion

Question 18

peripheral nerves

Answer 18

bundles of axons and supporting neuroglia

Question 19

dorsal rami

Answer 19

supply veretabral joints, deep back muscles, skin of back

Question 20

ventral rami

Answer 20

supply the rest of the muscles, many plexuses

Question 21

SNS

Answer 21

somatic, voluntary

2 branches
general motor (efferent)
general sensory (afferent)

Question 22

motor pathway

Answer 22

2-3 neurons

upper motor neuron
interneuron (sometimes)
lower motor neuron

Question 23

sensory pathway

Answer 23

cell bodies are in dorsal root ganglion

3 neurons

1st order- to spinal cord or brain
2nd order to thalamus
3rd order to cerebral cortex

Question 24

ANS

Answer 24

2 branches
1. visceral motor efferent (sympathetic/parasympathetic)
goes to smooth muscle
2. visceral sensory (afferent),
cell bodies in doral root

Question 25

how many nerves at each level

Answer 25

cervical 8 nerves, 7 vertebrate over until C8

T12
L5
S5
coccylgeal

Question 26

ANS

Answer 26

motor
sympathetic vs parsympatetic

2 neuron systems
preganglonic
postganglionic

Question 27

sympathetic neuron

Answer 27

short, long

synapse in ganglion root

Question 28

parasympathetic

Answer 28

long, short

synapse in wall of target

Question 29

Sympathetic nerves

Answer 29

Lateral nerves only exist at T1-L2, only place with sympathetic cell bodies
Sympathetic nerves must travel up or down sympathetic chain

Question 30

Rami communicans

Answer 30

White- on to ventral rami (only on T1-L2)

Gray- off to ventral rami (along entire spinal cord) superior to white

Question 31

sympathetic to head

Answer 31

Sympathetic to head: up the chain, synapse in closest cervical ganglia

To throax- chain off gray rami communicans to closet ganglia to organ

To abdomen- 3 neurons greater, lesser, and least thoracic splanchnic nerves to preaortic ganglia (in front of aorta), also lumbar splanchnics

To pelvis- sacral splanchnics

Question 32

3 options for sympathetic pathways

Answer 32

1. Synapse at same level and exit into ventral rami
2. Travel in chain, synapse at another level, exit into ventral rami,
3. Travel through chain without synapsing, exit on splanchnic to preaortic ganglia, synapse and go to organ (splanchnic nerve)

Question 33

Parasympathetic (cranial sacral)

Answer 33

Only derive from cranial serves 3,7,9,10 and from sacral spinal cord S2-4
Ex vagus nerve
Pelvic splanchnic nerves- carry parasympathetic fibers

Question 34

Dermatomes

Answer 34

spinal level of sensation, area of skin where all cutaneous fibers track back to the same spinal level
Can’t be dissected

Question 35

Cutaneous nerves

Answer 35

sensory nerves, carry axon, can be multiple spinal levels and contribute to multiple dermatomes

Question 36

derm vs cutaneous nerve

Answer 36

Derm, cutaneous- have different patterns
Derm- trace back to 1 level, fuzzy borders
Cutaneous- trace back to a nerve, ex entrapments

Question 37

myotome

Answer 37

muscles that spinal nerves innervate

Question 38

Isomers

Answer 38

same chemical formula, different congiburation

Question 39

epimer

Answer 39

molecules that differ in arrange at a single carbon

example
galatose and glucose at C4
glucose and mannose at C2

Question 40

enantiomers

Answer 40

mirror images

example D-glucose and L-glucose

Question 41

cyclization

Answer 41

linear to cyclic, a new asymmetric carbon is made

ex: D-glucose to alpha D glucopyranose (6 C ring)

D-fructose to alpha D fructofuranose (5 C ring)

Question 42

cylicization creates

alpha vs beta

Answer 42

anomers

alpha OH below
beta OH above

interconvert by mutaroation, determines bonding

Question 43

lactose

Answer 43

galactose beta 1-4 glucose

Question 44

sucrose

Answer 44

glucose alpha 1-2 fructose

Question 45

maltose

Answer 45

glucose alpha 1-4 glucose

Question 46

isomaltose

Answer 46

glucose alpha 1-6 glucose

Question 47

glycogen

Answer 47

D glucose polymer

alpha 1,4 linear change
alpha 1,6 branch points

Question 48

starch

Answer 48

D glucose polymer

amylose: unbranched alpha 1,4 glucose bonds
amylopectin: alpha 1,4 and alpha 1,6 glucose bonds

Question 49

cellulose

Answer 49

D glucose polymer
beta 1,4 bonds

non digestible fibers

Question 50

what is the significance of isomers

Answer 50

Isomers dictate the type of bonding and physical processing

Enzymes create or digest bonds that are specific for a type of bond

Question 51

define 
specificity
affinity
capacity
hormonal regulation 

in terms of transporters

Answer 51

Specificity- what does it transport
Affinity- high affinity- active at low fasting and high fed, low affinity active at high fed
Capacity- low capacity- easily saturated
Hormonal regulation- ex insulin dependent transporters

Question 52

Basal glucose uptake

Answer 52

constant supply of glucose

Question 53

Glut 1 and 3

Answer 53

high affinity, low capacity, red blood cells and brain, constant glu supply, uptake is independent of concentration

Question 54

Glut 2

Answer 54

low affinity, high capacity, liver and pancreas, equilibrium of intracellular glu with blood glu concentrations

Question 55

Glut 4

Answer 55

GLUT 4- insulin dependent uptake after meal, high affinity, important for lowering blood glu levels, insulin increases the number of receptor on cell surface, in muscle or adipose tissue

Question 56

sources of glucose for glycolysis

Answer 56

Sources from glycogenolysis in exercising muscle
Dietary intake of carbs
Glycogenolysis and gluconeogenesis in liver

Question 57

glucokinase vs hexokinase

Answer 57

Glucose to glucose-6-phosphate by hexokinase or glucokinase, uses 1 ATP, irreversible

Glucokinase- in liver and pancreas, high Km (low affinity), high Vmax, more active in fed state, inducible by insulin

Hexokinase- everywhere else, low Km (high affinity for glucose), low Vmax, more active in fasting state, allosterically inhibited by glucose-6P

Question 58

know all of glycolysis

Answer 58

AHHHHHH

Question 59

aerobic glycolysis

Answer 59

glucose -> 2 pyruvate, 2 ATP and 2 NADH (NADH to ECT, pyruvate to AcCoA to TCA)

Question 60

anaerobic glycolysis

Answer 60

glucose-> 2 lactate, 2 ATP NO NADH, lactate cannot be converted to AcCoA, cannot enter TCA cycle

Question 61

pyruvate kinase regulators

allosteric and hormonal

Answer 61

Pyruvate kinase allosteric regulators:
Inhibited by ATP
Activated by fructose 1,6-BP

Pyruvate kinase hormonal regulators:
ONLY occurs in LIVER
Glucagon inactivates pyruvate kinase via phosphorylation (directs PEP to gluconeogenesis)

Question 62

PFK-1 inhibtors

allosteric
hormonal
how it relates to PFK 2

Answer 62

PFK-1:
Inhibited by ATP and citrate
Activated by AMP and fructose 2,6 BP

PFK 1 vs 2 pathway (2 goes to fructose 2,6 BP)

Hormonal regulation:
Insulin activates PFK-2
Glucagon activates f-2,6-Bpase
Looks at pics

Question 63

Describe how pyruvate kinase deficiency results in hemolytic anemia.

Answer 63

Low pyruvate kinase leads to decreased ATP production
This impairs stability of RBCs-> change in cell shape -> echinocytes (Burr cells)-> cell lysis -> nonspherocytic hemolytic anemia

Question 64

malate-apspartate shuttles vs glyceral 3-phosphate

Answer 64

NAD/NADH
vs
FAD/FADH2
recycling

Question 65

GLUT 5

Answer 65

transports fructose from blood into cells

Question 66

3 types of artifacts

Answer 66

• reverberation artifact (A lines)
• Mirror-image
• Acoustic shadowing artifact

Question 67

anechoic

Answer 67

dark (no gray),

ex blood vessel

Question 68

hypoechoic

Answer 68

dark gray

Question 69

hyperechoic

Answer 69

bright white

Question 70

linear probe

Answer 70

high frequency (5-12)
good for arteries, veins, thyroid, lymph, skin, nerves)

Question 71

Phased Array (ECHO) probe

Answer 71

rectangular, low frequency

good for heart, lungs, thorax

Question 72

curvilinear

Answer 72

low frequency

good for gallbladder, liver, kidney, spleen, bladder, abdomen, uterus/ovaries

Question 73

intracavitary

Answer 73

low or high frequency

good for uterus/ovaries, pharynx, oral, rectal

Question 74

2 axis

Answer 74

long axis- longitudinal, sagittal plane

short- transverse axis

Question 75

RNA polymerase in Euks vs Ecoli

Answer 75

E coli- has 1 type of RNA
s unit binds directly to promotor

Euks
pol 1- rRNA
pol 2- mRNA
pol 3- tRNA

brought to RNA via transcription factors

Question 76

2 RNA inhibitors

Answer 76

Rifampin- bacteria

alpha- amanitin- euk

Question 77

Rifampin

Answer 77

antibiotic

bacterial RNA polymerase inhibitor, binds b subunit and blocks the path of nascent RNA. Mutations in b subunit prevent rifampin binding

Question 78

alpha amanitin

Answer 78

poisonous mushroom

a-amanitin binds to the largest subunit of eucaryotic RNA polymerase

Question 79

The presence of nucleus in eucaryotic cells uncouples

Answer 79

translation from transcription

Question 80

mRNA editing

Answer 80

Euk mRNAs are modified by addition of a 7-methyl guanosine cap at the 5’-end and a polyA tail at the 3’-end. Following their modifications, these mRNAs are subjected to splicing.

Question 81

mRNA splicing

Answer 81

Splicing involves spliceosomes (ribonucleoproteins), conserved 5’-splice (donor), branch and 3’-splice (acceptor) sites that facilitate transesterification

Question 82

alternative splicing example

Answer 82

calcitonin and CGRP synthesis

Question 83

tRNA processing

Answer 83

tRNAs are processed by ribozyme RNAse P, endonuclease and ligase

Question 84

rRNA processing

Answer 84

on the other hand, are processed by chemical modifications and cleavage of a large precursor RNA

Question 85

RNA editing examples

Answer 85

Same pre-mRNA leads to two apolipoprotein B100 and B48. Apolipoprotein B48 arises due to editing of CAA to UAA, a stop codon

Question 86

transcription factors

Answer 86

bind to promoter for basal transcription

Question 87

Pit 1 and Prop 1

Answer 87

Pit 1- regulates growth hormone
Prop 1- regulates Pit 1
Both are transcription factors. When mutated it leads to GH deficiency

Question 88

Huntington protein

Answer 88

Brain dervived neurotrophic factor (BDNT)
Normal huntingon gene- REST is bound, can make NRSE-> BDNT occurs
Mutant huntington- REST is loose -> represses NRSE-> no BDNF- death or neurols