Hematopathology wk 1-2

myelodysplasia
- maturation arrest
- long term tx - transplant, allogenic bone marrow graft
- Shh config with genetics as final dx?

- 50% hypercellular, 25% normacellular, 25% hypocellular
- increased reticulin

- primary - 70 y/s old elderly, typically present with fatigue
- secondary - chemo/radiation,
- can progress to AML (1/3 eventually -> AML)

- cytogenetics
- chromosome deletion
- 5q, 7q, or 20q, 12p

- types
- refractory anemia
- refractory anemia with ringed sideroblasts
- refractory anemia with excess blasts (RAEB)
- chronic myelomonocytic leukemia

myeloid maturation, R shifted, e.g. - infection

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myelofibrosis - a) myeloid dysplasia or b) acute myelofibrosis
apperance of extramedullary hematopoiesis or malignant myeloid cells in another organ, usually spleen, with fibrosis in the marrow

increased reticulin is present around clusters of megakaryocytes; megakaryocytes have aberrant N/C ratios and hyperchromatic, bulbous or irregularly folded nuclei

primarily adults - (mean age 60), younger when follows polycythemia vera or CML
marrow - three stages - hypercellular
















- patchy fibrosis

- obliterative myelosclerosis
indolent, prolonged course, median survival 10 yrs

myelofibrosis staging by reticulin
0-1 normal




normal bone marrow should have CD3 > CD20

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MALT (extranodal marginal zone lymphoma)
- common cause of MALT in stomach, H-pylori
- although classified as a cancer(and clonal), when the insult is removed, early MALT disappears (even when there's bone marrow involvement)
- however, late MALT will stay
- reactive follicles with germinal centers and plasma cells
- t(11;18)(q21;q21), predictive of poor response to eradication therapy.

AML
- gelatinous / myxoid

diffuse large b-cell lymphoma (DLBL) - CD3 <>

follicular lymphoma -> progress to DLBL
can present synchronous
progression of FL to DLBL may involve p53 mutation

if BM involved by FL, better prognosis at stage 4
if BM involved by DLBL, worse prognosis at stage 4

p53
anti-oncogene
a negative regulator of cell cycle
activates p13, which inactivates cyclins
normally present in low level with short half life loss of function mutants have an increased half-life; levels accumulate to 5-100 x normal
also seen in, colon, breast, lung, leukemia, sarcomas


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question: why stain for CD20 and Pax-5 when both stain for B cells?
treatment for follicular lymphoma is anti-CD20 antibodies (rituximab)
if pt treated it and there's still residual disease, then they will be CD20(-), so use Pax-5 to stain

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immunostains

CDX2
- intestine
- nuclear stain
CD34
- blast, progenitors, or block in maturation, vascular endothelium
CD117 - stains for mast cell or stem cell, stem cell has higher N/C ratio, less intense staining than mast
CD61 - megakaryocytes, platelets
CD30 - activated T, B, Reed-Sternberg cells
reticulin - around blood vessel don't count, also abundant in lymphoid aggregate
glycoporin - erythrocyte stain
PAX-5 - pan B-cell marker

TEAMLEAD 1

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LECTURE : STRUCTURE OF PROTEIN

Ramachandran plot

Glycine can adapt many more positions in the plot, and many positions in the backbone

Proline is much more restricted, Ramachandran plot very restricted.
It restricts amino acid on N-terminal residue of proline, the residue is also restricted due to proline.

On alpha helix, 3.6 amino acids (5.4Angstrom) between a turn of helix; hydrogen bonds between carboxyl oxygen and amide's proton, can be right or left handed

views of alpha helix
ribbon representation, (D) - representation of DNA by van der Waals surface

Beta pleated sheet
anti-parallel N->C, hydrogen bonding with C <- N terminus below
parallel - all peptides pointing to one direction,
these forms have different hydrogen bonding
In antiparallel, each amino acid bound to a single amino acid on an adjacent strand
In parallel, each amino acid on one strand with two different amino acids(two residues apart) on adjacent strand
Beta turns, tight turns with Gly or Pro
type I - larger residues than type II
type II ???
distance between amino acid in beta sheet 3.5 Angstrom, compared to 1.5 anstrom of alpha helix
Beta sheet, most commonly found in active sites??
Structure class of protein (tertiary structure)
Globular proteins - contain all secondary structure elements, high functional diversity
enzymes, recepters, etc.
Fibrous proteins - rather specialized for structural roles
all alpha-helix structures: e.g. collagen, vs. all beta-sheet
Collagen - proline helix: Gly-X-Pro(or OH-Pro); left handed structure(going toward viewer on clockwise rotation when viewed from top), 3 aa/turn; triple helices come together to form a collagen, proline on the exterior, Gly on the interior

Different amino acid show propensity for different secondary structure(alpha vs beta), so can predict secondary structure from primary structure, but tertiary structure still needs to be determined experimentally
Enormous diversity of protein globular structures, mixture of alpha helices and beta sheets

Rules of 3' structure
- Hydrophobic side chains mostly inside
- Multiple 2' strucutres may exist in a single protein
- Pro, Gly often located at turns , outside??
- Compact interiors (very little room even for H2O)
- Functional (active) sites involve conserved side chains often far apart in the 1' sequence - but can come together in 3' structure
- S-S bridges greatly stabilize 3' structures

Quarternary structure: symmetric dimers(e.g. Hb) to large complexes (RNA polymerase)

Structures determined by
1) X-ray crystallography
- atomic resolution images of macromolecules


protein crystal that is purified (1mg of protein sufficient), crystals diffract X-ray, plot electron density map from diffraction intensities(image of phases)

how to get phases diffraction data (determined by how much the structure is known already):
1) multiple isomorphous replacement (de novo strucutre determination)
2) molecular replacement (requires related structure)
3) differences fourier syntehsis (requires very related structure, same crystal packing, useful for drug-protein complex, rapid)
-> fit model -> refine structure based on known stereochemistry

protein crystals
- very large solvent channels, can be up to 75% solvent
- many enzymes crystalled in different solvent and form, but structure remain mostly identical
- enzymes in families with similar amino acid sequences have structures very similar
- In many enzymes, the crystal retains activity, the activity of enzyme in solution is same as in crystal, e.g. ribonuclease, chymotrypsin, DNA polymerase

2) NMR
- measure proton chemical shift that allow constrain positions of proton -> construct the most probable model



3) Ribbon representation : Alpha helix (as helix), beta sheet represented by arrow, N -> C

Protein misfolding disease
e.g. - beta-amyloid fibril misfold , Alzheimer, Transmissible spongiform encephalopathy, cancers associated with protein overproduction

Chymotrypsin
2 domain structure, active site residues can be far apart based on 1' sequence, (H57, S195, D102), come together to form active site

Pancreatic Ribonuclease A(digestive enzyme that cleaves RNA)
- location of bound protein determines active site, essential catalytic side chains adjacent to active site (H119, H12)

HIV-1 protease
- dimer - 99 a.a. flap opens up, wraps around a protein substrate, for cleavage
- HIV inhibitor drugs mimic a protein chian, binding to enzyme like protein chains do, but they are more stable than protein chain and thus HIV-1 protease cannot cleave them, and the inhibitor stays lodged to the active site.

DNA polymerase in action (structure can move around a lot)
4 crystal structures in different states

MutSalpha
heterodimer,
find mismatch paired DNA, recruit other proteins to repair
sites that hydrolyzes ATP, send signal down to specific piece of DNA, spheres represent mutation -> HNPCC

Importance of cofactors in protein? - able to execute chemical reactions that cannot be performed by standard amino acids; enzyme w/o its cofactor = apoenzyme, enzyme w/ its cofactor = holoenzyme
- can be metals or coenzymes(small organic molecules), tightly bound coenzyme are called prosthetic group

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LECTURE: CELLS AS UNITS OF STRUCTURE

Tenets of cell by Schleiden and Schwann
1) cells units of structure, physiology and organization of living things
2) cells retain a dual existence as a distinct entity and a building block in the construction of organism

Virchow
every animal as sum of vital units
Omnis cellula e cellula

Diversity of cell size, shape and function
sperm cell, neuron, photoreceptor cell, hair cell

Light microscope resolution limit 1/2 of light wavelength = 0.275 micron

Units of size - cell structure
cm - visible to eye
mm - very large cells
µm - cells, nucleus
nm - organelles
angstrom - molecules, atom

special stain for smaller structure, population of organelles/small structure

time lapse video microscopy - cells in action/migration/cell-cell interaction

Electron microscope
- resolution is 1/100000 wavelength of light
- common resolution limit is 10 angstrom
- advanced to single atom resolution, or sub-atomic resolution
- limitation: has to chemically fix the cell

How do we study cell function?
Cell fractionation - allows identify structure and function

Cell architecture
- metabolic compartmentalization - allows diversity of regulation that prokaryote cells can't do


1) nucleus
- segregate gene transcription and RNA translation
- outer and inner nuclear envelopes (double layer)
- nuclear pore core complex - regulate information access to chromatin
- heterochromatin(tightly compact, transcriptionally silent), euchromatin (dispersed, transcriptionally active)
- endoplasmic reticulum - physical continuation of outer nuclear envelope
- nucleolus - functional compartment(not membrane bound), site of ribosomal RNA synthesis and ribosome biogenesis
- altered nuclear morphology, multiple nucleoli, dispersed chromatin(euchromatin abundant, heterochromatin sparse) -> transcriptionally active

Nuclear pore complex
- gateway of information transfer
- ubiquitous structure present in all eukaryotic cells
- located at sites where inner and outer envelopes fuse
- two prominent structures: nuclear and cytoplasmic rings, central spokes
- 8 fold symmetry
- very complex/large: 100-200 proteins, 1200 A in diameter, 500 A in width
- cytoplasmic side has filaments for binding, nucleoplasmic side has basket for docking site for components that are exiting the nucleus
- proteins that line the nuclear pore complex - native unfolded proteins - very relaxed protein structures, very interactive, adhesive scaffold - to allow specific transport

NPC-mediated nuclear transport
- transport thorugh NPC by
- simple passive diffusion (20-40kDa)
- active transport (> 40 kDa, require ATP/GTP, require nuclear localization signal(NLS) - 8-10 amino acid long positive charged amino acid, can reside in any exposed part of protein)
- mediate bidirection transport and unidirectional mRNA transport

Nuclear import pathway
- paticular signal in protein that indicates that it be traffcked to certain location
- importin alpha binds to substrate, and bind to importin-beta, importin beta bind to filament, guide substrate cargo into the pore into nucleoplasm and then dissociate

Role of GTP binding protein
- different conformation based on nucleotide thats bound, allow different activity
- Ran-GAP(GTPase activating protein) -> GTP to GDP in cytoplasm
- in cytosol, Ran mostly in GDP bound state,
- in nucleus, Ran mostly in GTP bound state
- 1) Ran GTP binds to substrate, 2) converted to GDP+substrate-alpha+beta
- this complex 3) enters nucleoplasm, 4) where GDP -> GTP by guanine nucleotide exchange, 5) which releases alpha and substrate, while 6) GTP-beta transpored out to cytoplasm to find another substrate-alpha complex

two states - two conformations - two distinct activities in RanGTP binding protein
RanGDP in cytoplasm, RanGTP in nucleus

Nuclear Export pathway
- identify by cluster of leucine residues (hydrophobic signal), unlike import where its identified by cluster of positive charges
- exportin - binds GTP in nucleus, enhance the affinity for its cargo
- cargo-exportin-GTP compelx binds to FG(Phe-Gly) repeats, facilitate its diffusion across the pore
- RanGAP in cytoplasm cause GTP hydrolysis -> decrease affinity betwen cargo and exportin -> release cargo into cytoplasm

Nuclear lamina
- in inner nuclear side, dense fibrous network composed of three lamins A, B, C
- phosphorylation of lamin -> disassembly of lamin / nuclear envelope
- lamin B connected to inner membrane via p58; A and C are splicing products of the same gene
- laminopathy - disease due to mutation of lamin A/C gene
-e.g. Emery-Dreifuss muscular dystrophy type 2, familiar partial lipodystrophy, limb girdle muscular dystrophy type 1B, Charcot-Marie-Tooth disorder type 2B1, mandibuloacral dysplasia, Hutchinson-Gilford(childhood progeria syndrome)


2) endoplasmic reticulum
- continuous with outer nuclear envelope
- two types: rough and smooth
- RER - granular rough surface, ribosomes, syntesis of secretory and membrane proteins
- SER - highly rich in liver, function in detoxification
- serves as a Ca2+ storage site
- can comprise of 70% of surface area of cell ???
- on outer nuclear envelope with ER, nuclear pore complex excluded from endoplasmic reticulum

3) Golgi apparatus
- modification of secretory membrane proteins (particularly sugar/oligosaccharide modification)
- cis side - receiving side/ entrance side from ER
- trans side - shipping side

4) Lysosomes
- degradative function
- serves as terminal trafficking site for products of receptor-mediated endocytosis
- highly acidic compartment
- also degrade old organelles
- particularly abundant in antigen presenting cells

5) peroxisome
- single membrane organelle
- beta oxidation, primarily for lipid metabolism
- e.g. bile acid synthesis, cholesterol synthesis, plasmalogen synthesis, amino acid and purine metabolism
- many associated genetic defects

6) Mitochondria
- abundant organelles of cell,
- largest organelle
- primary source of ATP, functions in oxidative metabolism
- e.g. heme and iron sulfur center biosyntehsis and modulating Ca2+ levels
- associated with e.g. neurodegenerative, ischemia-perfusion injury, diabetes and aging

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LECTURE: MEMBRANES AND MITOCHONDRIA

ER can pinch off vesicle, to fuse with Golgi apparatus, which secretes secretory vesicle to fuse with cell membrane to exocytosis
Membrane fusion in exocytosis and endocytosis - material can enter the cell without crossing lipid bilayer
- gives rise to
- 2 spaces in cell: extracellular space around the cell(in continuity with space in secretory vesicle, golgi apparatus, RER) and cytoplasmic space(and nucleoplasm).

Membrane functions
- compartmentalize cell
- regulate flow of material in/out of cell
- excitable membranes = basis for nerve conductions, muscle contractions
- site for many enzyme rxn -if enzymes are membrane bound in a closed area, the rxn can be much more efficient than if the enzymes are not bound and just floating around
- regulate cell shape, motility through interactions with cytoskeleton
- tissue formation - rarely cells live alone; role of membrane junctions - cells join together by membrane junction
- interaction of cell with environment; sensor of external signals -> amplifed/transduced
- signal transduction

Membrane composition
- Lipid 20-40% - major component
- Proteins 30-50% - major component
- Carbohydrates 0-10%
- Water 10-20%
- work together as a functional unit



Three primary types of membrane lipid
1) phospholipids (PL)
- phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol, phosphatidylserine
2) glycolipids (G)
3) cholesterol (C)

Composition of different organelle membranes
inner mitochondrial membrane - almost all PL
RER -> Golgi -> plasma membrane (amount of cholesterol increases - rigidity)
Almost all G and majority of cell's C in plasma membrane

1) phospholipids (PL)
All the lipids are amphipathic (LOOK AT THE DIAGRAM)
Glycerol, phosphate, alcohols are polar part of the molecule
fatty acids - hydrophobic part of molecule

Most common type of PL in membrane has saturated FA on 1 position, and unsaturated FA on 2 position; huge diversity in hydrophobic chain composition and head composition

2) glycolipids (G)
Glycolipids(G) have different backbone, most of them have sphingosine backbone
backbone types; G is a type of sphingolipid
- sphingosine - acyl chain
- glycosphingolipids - sphingosine backbone with FA chain and sugar
- sphingomyelin - sphingosine backbone with FA chain and phosphate and alcohol(choline or ethanolamine); both a PL and a sphingolipid
- glycosphingolipids and sphingomyelin have more saturated fatty acid chain than membrane phospholipids

3) cholesterol (C)
amphipathic, but the hydrophilic part is just an OH group, hydrophobic part has rings
very rigid molecule, decrease fluidity of membrane

membrane rigidity decreased by double bond(unsat), and increases fluidity

Why these types of molecules to be in cell membrane?
- these three classes comprise 98-99% of lipids in membranes
- they naturally only form bilayers, b/c they are more cylindrical shaped
- detergents, they are inverted cone shape, so they form micelle - not useful for membrane

lipid bilayers are liquid crystals
- very rapid lateral diffusion (10^7 times per sec)
- very rare flip-flop (once per month? very crystal)

permeability barrier
- hydrophobic molecule, O2, N2 go through
- small molecules like H20, urea, glycerol and CO2 will cross
- ions and large uncharged molecules e.g. glucose will not

Roles of membrane lipid
1. structural - lipid bilayer is a core of all biological molecule
2. bilayer hydrocarbon core is thin only 3 nm, semi-permeability barrier
3. regulate membrane fluidity, flexibility (add cholesterol for toughness, plasma membrane has many, while internal organelle has little)
4. role in membrane fusion, different lipid fuse at different rates
5. function/location of membrane protein
- matrix for membrane bound enzymes (certain lipid type required for activity of specific enzyme)
- covalently anchor specific proteins to bilayer(phosphatidylinositol can attach via sugar linkage, protein to lipid bilayer)
- target peripheral proteins to proper membrane organelles (phosphatidylinositol)
- sequester specific proteins in membrane domains or rafts (
cholesterol likes to be next to saturated chains(namely sphingomyelin) -> create little patch in membrane(domain or raft) -> platform for signal transduction pathway
6. interaction with extracellular matrix and other cells (G)
7. specific lipids can be source of second messenger (phosphatidylinositol bisphosphate)




Membrane protein types

1) transporters
- passive
- active Na K ATPase
2) anchors
- e.g. spectrin in RBC
- cytoplasmic surface, form membrane cytoskeleton
3) receptor
4) enzyme



Mitochondria
- cristae - infolding
- intermembrane space
- matrix space

Flow of reactants in mitochondrion
- citric acid cycle -> CO2, NADH (-> electron to membrane proteins, -> pH gradient -> hydrogen ion move the pump to convert ADP -> ATP)

Electron transport system
- three complexes
- NADH dehydrogenase complex (complex I) - NADH donate e- to the complex, then to ubiquinone, then diffuse to
- b-c1 complex (complex III) -> cytochrome c, diffuses to
- cytochrome oxidase complex (IV)
- hydrogen ion move out as e- go through these complexes
- then Hydrogen ions move through ATP synthatase which produce ATP
- outer membrane has protein channels called porins, which allow
- all the ion/ATP/ADP, etc could go passively across outer membrane
- however ATP/ADP can get into inner mitochondrion only by active process, energy from H+ gradient


General features of membrane structure critical for functions of mitochondria
IMM
1. fluid lipid bilayer allows allosteric changes in protein and lateral diffusion of carriers in electron transport chain
2. e- transfer, both intrinsic (cytochrome oxidase) and extrinsic (cytochrome c) proteins play roles
3. specific lipids (cardiolipin) necessary for cytochrome c oxidase function
4. lipid bilayer forms permeability barrier to H+
5. transporter proteins provide for passage of ATP, ADP, other molecules across IMM

OMM
1. membrane channels(porins) allow ATP to passively diffuse
2. porins small enough pore to keep cytochrome c in intermembrane space;

formation of channels(Bak/Bax proteins bind to membrane) that allow cytochrome c to exit -> kep step in apoptosis

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LECTURE : SPECIAL CASE OF MEMBRANE PROTEINS

Two classes of membranes
Peripheral
- not embedded in the bilayer but stuck on the surface of bilayer
- 1/3 of the total membrane protein
- remove with treatment that doesn't disrupt bilayer, that uses polar interaction
e.g. salt, chelator, urea - bind to surface protein
- they don't have bound lipids
- no exposed hydrophobic surface
Integral
- 2/3 of total membrane protein
- can remove by destroying the bilayer (detergents, organic solvents)
detergents - have both hydrophobic and hydrophilic region, but they have rather large hydrophilic region(polar head group), relatively small hydrophobic tail(typically only one, not two) : e.g. octyl-glucoside (non-ionic), sodium dodecylsulfate (SDS, ionic)
- detergents incompatible with packing into bilayers
- form micelle - at crtically micelle concentration
- when adding detergent to bilayer, initially detergents integrate into bilayer, but it becomes unstable as more added, form mixed micelles - each micelle contains one membrane molecule, or one membrane protein
- membrane proteins can remain active if non-ionic detergent used
- protein hydrophobic -> can span the membrane
- have bound lipid - help contribute to proper folding and anchoring in the bilayer
- aggregate in hydrophilic environment

Purification of membrane proteins in non-detergents
- can use same methods as chromatography of soluble proteins, however the detergent should always be present, otherwise hydrophobic part of protein will fold itself and aggregate
- reconstitution - remove excess detergent in the presence of phospholipids, remove the protein from micelle into bilayer/membrane like structure

characterization of membrane protein
- crystallography most informative

Membrane protein functions
- enzymes
- lipid metabolism and glycosylation
- electron transport complexes
- ATP synthesis complex
- receptors
- signaling - G protein linked, kinase activating
- protein uptake - LDL, transferrin
- antigen presentation - MHC complex
- small molecules transporters -glucose, drug, CFTR
- channels - water(aquaporin), ions

Covalent modification of membrane proteins with lipids
- acylation (fatty acid attached to membrane protein)
built from 2 carbon units
can be attached to N, O, or S group
e.g. N-terminal myristate, palmitate (O, S)
- prenylation (15, 20 carbons attached to S of Cysteine)
built from 5 carbon units

PI(phosphatidylinositol)-glycan linked protein
- behave like integral protein but functionally they are peripheral
- structurally protein is actually peripheral on the outside, but has hydrophobic components that links it to the surface
- present in all eukaryotic cells
- e.g. defective in paroxysmal nocrutrnal hemoglobinuria(PNH), particularly abundant on malarial parasites

Integral membrane proteins often attached to membrane through hydrophobic transmembrane helices
- typically alpha helices (20-25 residues long)
- hydrophobic residues in transbilayer region
- often predicted from their 1' sequence(hydropathy analysis)
add up + for hydrophobic, - for hydrophilic side chains, add them up in segments of 25; if high number, more likely to be transmembrane segment

# of transmembrane helices in membrane protein
- one : LDL receptor, Golgi, glycosyl transferase
- seven: G protein linked receptors (-800 in humans)
- 10-12: transport protein (glucose transporter)

X-ray structure of membrane proteins
hydropathy prediction useful
- bovine rhodopsin
- beta adrenergic receptor
- bacteriorhodopsin
- human aquaporin - defective in nephrogenic diapbetic inspidius
- bacterial K+ channel
hydropathy prediction misleading
- prostaglandin H2 synthase
- E.coli membrane porin - transmembrane region is beta-sheet instead of alpha helix

membrane protein vs soluble protein
- membrane protein (integral) typically have hydrophobic outside in the middle, while soluble have hydrophobic on the inside
- membrane protein typically have channels(hydrophilic), while soluble proteins don't have channels
- peripheral protein more likely to be hydrophilic, and hydrophobic residue buried inside

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LECTURE : HEMOGLOBIN

Globin genes

In diploid cells, there will be 2 copies of alpha1, alpha2, and beta => 4 copies of alpha and 2 copies of beta

types of Hb
A2 - minor Hb, delta chain replaces beta chain ; 1.5-3.5%
F - fetal Hb, in adults usually a sign of something
S - sickle cell Hb, mutated beta chain

pathologic Hb

C - Hemoglobin C results from a mutation in the beta globin gene and is the predominant hemoglobin found in people with hemoglobin C disease (a₂b^C₂). Hemoglobin C disease is relatively benign, producing a mild hemolytic anemia and splenomegaly. Hemoglobin C trait is benign.
E - This variant results from a mutation in the hemoglobin beta chain. People with hemoglobin E disease have a mild hemolytic anemia and mild splenomegaly. Hemoglobin E trait is benign. Hemoglobin E is extremely common in S.E. Asia and in some areas equals hemoglobin A in frequency
H - Hemoglobin H is a tetramer composed of four beta globin chains. Lacks three alpha-globin genes. Hemoglobin H occurs only with extreme limitation of alpha chain availability. Hemoglobin H forms in people with three-gene alpha thalassemia as well as in people with the combination of two-gene deletion alpha thalassemia and hemoglobin Constant Spring.
Barts. Hemoglobin Barts develops in fetuses with four-gene deletion alpha thalassemia. These molecules transport oxygen poorly. Most individuals with four-gene deletion thalassemia and consequent hemoglobin Barts die in utero (hydrops fetalis).

thalassemia(deficiency of alpha or beta chain) AB+, beta-thalassemia heterozygote lacks a beta chain
- in alpha thalassemia, alpha globin chain is underproduced. No compensatory increase of any other chains

- beta thalassemia minor(heterozygote), beta chain underproduced
- beta thalassemia major(homozygote), beta chain absent
- compensatory increase of HbF, but not adequate

F - alpha2gamma2 dimer
A2 - alpha2delta2 dimer
A - alpha2beta2 dimer

myoglobin - monomeric protein
tissue = 20 mmHg - partial pressure of oxygen in tissues
Hb cooperativity - larger fraction of total bound Hb can be released than if dissociation was not sigmoid

T state vs R state
T state (deoxy-Hb)
- no oxygen, so attaching O group initially can be difficult, but if one O bound, it makes the rest better O binders (K2 > K1)
R state (Oxy-Hb)
- all four sites occupied by oxygen

active site of hemoglobin is heme cofactor - Fe-protoporphyrin IX
- rings part hydrophobic
- sits between helices in the middle of the protein
- carboxyl groups stick out on the surface
- Fe can bind to 6, among which it binds to N on heme cofactor, and remaining two are
- bound by His residue
- one binding site for O2
=> once Fe fully bound, Fe slightly moves into plane with the tetrapyrole ring, and His residue follows => His residue moves alpha helix a little bit => change interaction at the alpha beta interface (alpha1beta1-alpha2beta2)
- binding of O2 -> rotates alpha/beta dimer by 15 degrees

allosteric effector
- homotropic effector (effector is same thing as whose function/binding affected)
Oxygen
- heterotropic effector
2,3 -BPG (metabolite of glucose), equal amount of BPG in RBC as Hb
CO2
proton (pH)

2,3-BPG binds between beta subunits where they have basic residues as binding site
- stabilizes T state, favoring release of O2
- 2,3-BPG does not bind to R state
- HbF missing on Histidine residues(2 out of 4) of this site, thus it doesn't bind 2,3-BPG
-> thus it is on higher affinity binding state for O2 than maternal
-> O2 tends to flow from materal oxy-Hb to fetal deoxy-Hb; but this only works when 2,3-BPG is present, w/o 2,3-BPG HbF no different from HbA in binding affinity

low pH and increased CO2 shift ODC to the right, Bohr effect

CO2 directly interacts with Hb amino acid N terminal -> carbamate -> alters alpha/beta subunit interactions such that low affinity T state is favored

pH
- Three amino acid residues, Asp94, His146 (important H bond btwn Asp and His), Lys40 form hydrogen bonds, when these hydrogen bonds intact, Hb in T state, favors release of O2
- decreased pH makes His146 more positive, thus stronger hydrogen bond interaction with Asp94

SUMMARY
- 2,3-BPG, CO2, pH, key regulators, work at different sites
- increased 2,3-BPG, H+ and CO2 favor T state
- effects can be additive since different sites involved


CO bind 210 times more affinity than O2 on Hb

CN,
- does not bind to iron in 2+ state, instead
- bind to iron sites involved in respiration in mitochondria - a.k.a. cytochrome oxidases
- treatment
sodium nitrite/amyl nitrite
convert Hb to Met-Hb (Fe3+) - 10-15% => CN can bind to Met-Hb
better than have CN bound in mitochondria, give kidney time to excrete CN
thiosulfate - convert CN to SCN(inert) -> body can excrete

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LECTURE : SICKLE CELL

sickle cell disease
- an evolutionary response to malaria
- probably evolved 14,000 yrs ago when humans began to live settled life in tropics
- hx
- 1910 - first clinical description (Herrick) - sickle shaped cell in blood
- 1927 - Sickling phenomenon noted (Gillepsie and Hahn) - deprived of O2, cells sickle, did not distinguish homozygote and heterozygote
- 1949 - differences by electrophoresis noted - identification of HbS status by electrophoresis (AA vs. AS vs. SS), genetics unraveled (Itano and Neel)
- 1956 - single amino acid difference in beta chain (Ingram)
- advantage in fighting malaria, only in heterozygotes(AS), homozygote(SS) survival decreases due to sickle cell disease (Glu -> Val)
- different haplotypes of HbS arose from different parts of the world where malaria was prevalent

- molecular alteration
- sickle change occurs on part of beta chain that's facing outward
- as HbS molecule deoxygenated,
unpolymerized HbS -> nucleation(small group line up) -> random rods(elongation into long lines) -> parallel rods
=> due to Val in HbS able to interact with neighboring Hb's beta chains' Ala 70, Phe 85, Leu 88 ; if HbA is present, it will get into the chain and stop the chain from forming, however, if only HbS present, these chains will continue to form long paracrystals - basis for pathophys of sickle cell dz

- paracrystals
cause of shape change
Oxygen depleted then cells sickle; if O2 added back RBC returns to normal shape b/c oxy-Hb will have conformation where Val group contact point is covered
- however, if O2 depletion prolonged, RBC will retain sickle shape even if Hb no longer retains sickle form

- clinical consequence
1) effects of hemolysis
- anemia
- normal RBC lifespan 100(SD30 days), while sickle RBC only lasts 15-20 days
- diminished O2 supply, work capacity
- compensatory overwork of heart which can lead to failure
- compensatory overgrowth of bone marrow
- needs vitamin supplement (folic acid)
- affect bone strength
- hemolysis results from cell deformation
2) changes RBC membrane
- results in adhesion
with other RBC-> phagocytosis
with endothelium -> vascular obstruction
- as cells pass from arteriole -> capillary -> venule, O2 removed and cells sickle by the time they are in venous sytem
3) vascular obstruction
- cause pain in areas where oxygen low due to vascular obstruction
- once obstruction then pain, it resolves in 5-7 days
- loss of spleen
- due to sickle cell clotting and decreased O2 supply, becomes scar tissue
- spleen is an immune defense from bacteria, loss of spleen results in 25-30% of sickle cell pts die before 5 yrs age
- bleeding from kidney and diminution of kidney function
- changes in eyes
- small areas of loss of tissue and function
- increased intracellular viscosity, leads to increased blood viscosity

components of whole blood viscosity
- plasma viscosity - minor
- proportion of red cells - major
- intrinsic red cell viscosity - major

increased viscosity
- larger vessels may be affected, RBC need not be sickle shaped, but overall increase in intrinsic RBC viscosity may cause a group of these cells to sludge
- pain
- obstruction of larger vessels
- poor circulation to the lungs - may cause pneumonia or acute chest syndrome (the most common cause of death in sickle cell disease) - treatment is to replace the pt's blood with normal blood (transfusion)
- strokes - major blood vessel of brain can become obstructed
- loss of blood to bone/joint -> acute vascular necrosis, hip arthritis

toll of sickle cell dz
- loss of function of organs(brain, lung, liver, spleen, kidney, heart, etc)
- difficulty in social function
- 60% do not enter work force
- diffculty maintaining a job
- medical cost, $26,000/yr
- shortened lifespan (50-55 yrs)

treatment
- pain management
- drugs that reduce sickling (e.g. hydroxyurea)
- bone marrow transplantation
-

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LECTURE : IRON HOMEOSTASIS


ferritin - holds up to 4500 iron atoms, polymer of 24 polypeptide subunits, stores iron within cells

transferrin = Fe3+

DMT-1 requires proton for co-transport

iron uptake during erythropoiesis - endocytosis of transferrin-iron by RBC
- transferrin-iron complex binds to receptor on cell membrane
- endocytosis, and endosome becomes more acidic by pumping in more proton
- DMT1 releases iron, ferritin released by exocytosis, re-used for iron uptake

macrophage iron transport
- macrophage engulf RBC, iron released from macrophage via ferroportin, which is bound to transferrin

iron transport
duodenum - DMT1 - iron uptake, ferroportin - iron release to blood stream
erythroid precursor - DMT1, transferrin receptor(TFR) - for uptake of iron
liver - macrophage, phagocytosis of RBC - iron uptake, storage

iron regulatory element(IRE) - function depends on where it is found, forms stem loop structure
iron regulatory protein(IRP) - attach to IRE to keep other proteins away - block translation
5'-IRE if IRP bound to IRE before the coding region -> block translation / affect translation
3'-IRE if IRP boudn to IRE located behind the coding region -> prevent endonuclease from chopping it off(affect mRNA stability)

if high iron level, IRP-1 is bound by 4Fe-4S cluster and becomes aconitase, while IRP-2 is ubiquinated and degraded. -> ribosome can bind and translate the coding region

5'-IRE regulate production of ferritin, at low iron, ferritin expression is blocked
3'-IRE regulate transferrin receptor and DMT1 expression
- at low iron, TFR and DMT1 are needed so IRP is bound to 3'-IRE and prevents mRNA from endonuclease
- at high iron, TFR and DMT1 are no longer needed so IRP-2 is degraded, and mRNA is cut by endonuclease

hemochromatosis - bronze diabetes
- deposition
liver - cirrhosis, HCC
heart - cardiomyopathy
pancreas - diabetes
pituitary - dysfunction

Intestinal iron absorption controlled by regulation of iron transfer from epithelial cell to circulation
Iron cannot be excreted through liver or kidneys
- hepcidin controls iron homeostasis
- short lived, cleared from kidneys, detectable in urine
- binds to ferroportin, moves it to lysosome to have it degraded
- affects ferroportin on intestinal cells as well as macrophages

Three mutations that cause hemochromatosis
- mutation on hepcidin gene (direct)
- mutation on ferroportin (no longer responsive to hepcidin)
- mutation on HFE, TFR2, HJV - affect hepcidin expression, make it defective (indirect)


Iron-refractory iron deficiency anemia (IRIDA)
mutation on TMPRSS6

normally in iron deficiency, hepcidin should be little or none, ferroportin should be maximally expressed to increase iron load
however, in IRIDA, hepcidin is increased, decreasing iron uptake -> anemia

hepcidin expression
(+) - increased Fe, inflammation
(-) - decreased O2, increased erythropoiesis

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LECTURE GENE EXPRESSION - part I

First nucleotide on mRNA 5' has triphosphate, while other nucleotides use up their triphosphate to form phosphodiester bond
Unwinding(downstream of pol) and Re-winding(upstream) activities at both sides of transcription
regulation of transcription initiation
As a machine moves, it continues to have 8-10 DNA-RNA hybrid, upstream DNA-RNA melt, while new DNA-RNA are formed at downstream

Promoter is a cis-acting element- sequence element in the gene that is used to regulate the expression of that gene

Trans-acting element - not part of the gene, usually proteins but are attracted to the gene to affect the gene's expression

Cis-acting elements part of the RNA, not DNA

Initiation - from the point sigma factor binds, up to the point where first nucleotide nucleotide bond made

scaffold complex - temporary structure for holding workers and materials

sigma factor has to leave promoter for polymerase to enter elongation

at elongation, polymerase is tightly bound to the transcript while being able to move, w/o sigma factor

DNA dependent RNA polymerase
type I - makes rRNA
type II - mRNA
type III - tRNA and 5s rRNA

RNA polymerase II, subunit I
catalytic core between subunit 1 and 2
C-terminal domain (CTD)
repeat of YSPTSPS
function - initiation, elongation, capping, splicing, termination

differential phosphorylation of Serine residues on CTD of polymerase
- different CTD states recruit different factors

pre-initiation assembly
- trans-acting elements - transcription initiating factors
- general aspect of all transcription initiating factors are that:
they sit on the DNA, and they make it bend
- multiple proteins, one notable example is TFIID - has protein called TATA-binding protein
- recruit TFIIA, TFIIB, then recruit TFIIE, TFIIH => formation of pre-initiation complex, scaffold complex?

know the names of general transcription factors
TFIIA
TFIIB
TFIID (TBP, TAFs)
mediator
TFIIF
TFIIE
TFIIH
SAGA (TAFs, Spts, Adas, Sgfs, Gen5, Tra1, Ubp8)

promoters
- 4 types of elements: BRE, TATA, INR, DPE
- BRE - TFIIB
- TATA - TBP
- INR - TFIID
- DPE - TFIID
- need at least one to be a promoter
- having more than one will make it a stronger promoter

****
Majority of trans-acting factors read DNA major groove surface to detect its sequence information, in order to bind to specific sequence
- accessible
- provides rich information
- so trans-acting factors put an amino acid side chain into the major groove
- Hydrogen bonds used to detect, since its very linear bond, can be very specific


activators have DNA binding domain(for cis element on the gene), as well as protein-protein binding interaction domain
(e.g. estrogen receptor)
activators work through mediator complex

repressors inhibit activator by:
- competitive DNA binding(if activator binding site and repressor binding site overlap), or
- masking the activation site of activator(via physical interaction with activator), or
- direct interaction with the general transcription factors

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LECTURE : GENE EXPRESSION II

in transcription before initiation, RNA polymerase complex is bound to mediator, where mediator interacts with activator of cis-element(off-stream activating sequence) on a distant part of genome

how many nucleotides per turn? 10 (?????)

for steroids (e.g. estrogen receptor)
DNA binding domain where receptor binds is distant from ligand-binding domain
estrogen binding does not change DNA, but it changes estrogen receptor conformation
then the change allows binding of co-activator
then interaction between co-activator and mediator turns on the transcription
tamoxifen a competitive inhibitor of estrogen -> coactivator cannot bind

slide 6, sequence below is peptide, which is N terminus -> C terminus

positive and negative elongation factors (e.g. HIV-1 Tat and TAR recruit P-TEFb)
TFIIH phosophorylate 5' end of CTD, then promoters recruit negative elongation factor
and then recruits factors that counteract those factors; positive factors(P-TEFb) come and phosphorylate negative factors(NELF, DSIF), make them leave, which start elongation

TAR RNA at the 5’ end of newly synthesized mRNA strand forms an elaborate stem loop structure that recruits the small protein Tat. Tat ad TAR RNA together recruit the trans acting elements CycT1 and CDK9 (ie recruits P-TEFb)
The HIV-1 LTR promoter is weird in that it is not good at recruiting P-TEFb, and requires this stemloop TAR RNA to do so


most of our DNA wrapped up in nucleosome(histone+DNA), histones
- may obstruct transcription factor's access to DNA
- whereas traditionally histones were only thought to have structural function,
nowadays modifying histones is thought to change transcriptional capacity of many regions of DNA
- histone code read by specific binding proteins that in turn alter chromatin structure

If you recruit histone acetylase to the promoter region -> activate transcription by unwinding nucleosome
histone deacetylase - deactivate transcription by rewinding nucleosome

5' capping of mRNA
- capping enzyme recruited by RNA pol II and binds to its CTD region for activity
- RNA synthesized by RNA pol I and III (rRNA and tRNA) do not get capped
- snRNA, miRNA made by pol II
- cap structure
5' to 5' linkage, 7-methylguanosine
prevent 5' end from being chewed up by exonuclease
- 5' capping also serves as a recognition site for mRNA by ribosomes

3' end formation
- CPSF binds to RNA downstream of AAUAAA, there's a cleavage site
- Once RNA cleaved, poly-A tail added by poly A-polymerase (PAP)
- poly-A tail sequence bound by poly-A binding protein
- contribute to stability of mRNA and for tRNA recruitment
- every mRNA has poly-A tail, except for cell cycle dependent histones (which have conserved stem loop)

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LECTURE: GENE EXPRESSION - PART 3

upstream exon AG -------A--Py---G downstream exon
branch site A

exonic enhancers - found at the exons
intronic enhancer - usually near downstream 5' splice site

spliceosome
snRNP, know their roles
U1 - binds to 5' site(RNA recognizes) and then binds to 3' site; its RNA component complementary binding to splice site
U2 - binds to branch site(A) and forms part of catalytic center
U5
U4
U6 - catalyze splicing

So, once U1 bind to 5' and U2 bind to A, U5, U4, U6 come and bind to form catalytically competent spliceosome.

Mechanism of splicing - this happens alongside transcription

1) OH' group from branch point A nucleophilically attacks phosphodiester bond of 5' exon, leaving exon-1-OH floating while forming a lariat via phosphodiester bond with sequence next to 5' exon
2) exon1-OH attacks 3' exon's (exon 2) phosphodiester bond, joining with exon 2 while leaving intron site with OH. => exon1-P-exon2 => a continuous sequence

splicing of intron from RNA requires formation of 3-5 and 2-5 linkages

alternative splicing, look at a,b,c,d,e
- some introns become exons

average size of introns in the human genome is 100 bp to 2kb long

cis acting factors
- exonic intronic silencer enhancer
trans acting factors
- certain types of proteins expressed in certain cells, so alternative splicing can be conducted

splice sites are far away from consensus

exon enhancer or silencer within exon itself
intron enhancer or silencer within 200 nucleotides of the splice site

many of these are RNA binding proteins that bind to these enhancers or silencers, and they help the spliceosome recognize something as exon or prevent the spliceosome recognize something as exon

trans-acting factors, alternative splicing factors

alternative splicing human disease
- fronto-temporal dementia with parkisonism (FTDP-17)
- inclusion or exclusion of exon associated with multiple sclerosis


RNA interference
- stop the translation of mRNA
- downstream of transcription
- done by miRNA/siRNA
- siRNA (double strand) bind to mRNA and cause the strand to be cleaved by spliceosome
- miRNA (single strand that forms stem loop), binds to it and inhibits translation, which is eventually degraded

- miRNA does bind to 3' UTR
- miRNA do not perfecty complementarily bind to celular target
- siRNA perfect complemntarity to the target
- miRNA form stem-loop

gene splicing by double strand RNA




migration pattern (alkaline electrophoresis) vs migration pattern (acid electrophoresis)

TEAM LEAD 0

LECTURE: COMPOSITION

inorganic composition

molecular species

H, O, C, N, Ca - living organism

O, Si, Ca, Fe, Ca - earth crust

Da = 10^-24 g

virus

protein > DNA > water

bacterial cell

water >( protein > RNA > DNA; 30%)

human fibroblast

water > RNA > protein > DNA

30-50% of genome has no known function

15-20% are unique to each organism

complexity of genome by number of genes? not a good indicator of complexity

molecular weight of cell components

organelle(10^9), macromolecular complexes(10^6 - 10^9), individual macromolecules(10^4 - 10^9), monomeric subunits(10^2 - 10^3), inorganic subunits(< 10^2)

serum composition units and scale? (roughly, biggest component?)

Cations : Na+(135mM) > K+(5 mM) > Ca++(3 mM) > Mg++(1.2 mM)
Anions: Cl-(105mM) > HCO3-(30 mM) > phosphate (1.5mM)
Proteins: total = 80 g/l, albumin (60 g/l), most abundant protein in serum
fuels: glucose (6mM)
hormones (200pM)

BMI = 65 kg/1.73m = 35.8

pico 10^-12

what's the range of light microscope?

- chloroplast to fish eggs

electron microscope?

- small molecules to plant and animal cells

smallest bacteria 0.3 microns

smallest eukaryote 4 microns

largest virus

RNA most reliable for genome complexity

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LECTURE : STRUCTURE OF AMINO ACIDS AND PROTEINS

amino acid = amino group, carboxyl group and R and hydrogen

L vs D isomers - chirality of amino acid

peptide - strand of amino acid linked by peptide bond(formed by condensation)

cofactor - iron, copper, manganese, etc that facilitate enzyme binding, cofactors can be inorganic or organic

Aliphatic, non-polar

Glycine G (Gly)

Alanine A (Ala)

Proline P (Pro)

Valine V (Val)

Leucine L (Leu)

Isoleucine I (Ile)

Methionine M (Met)

Aromatic groups

Phenylalanine F (Phe)

Tyrosine Y (Tyr)

Tryptophan W (Trp)

Polar, uncharged

-OH, -S

Serine S (Ser)

Threonine T (Thr)

Cysteine C (Cys)

1. carboxamide

Asparagine N(Asn)

Glutamine Q (Gln)

Positively charged

Lysine K(Lys)

Arginine R (Arg)

Histidine H (His)

Negatively charged

Aspartate D (Asp)

Glutamate E (Glu)

Angles

peptide bond formed Merrifield synthesis

Almost all peptide bonds in protein are trans, except X-Pro linkage that is cis/trans

peptide bond planar, cannot rotate

C(α) – N => φ angle

C(α) – C => ψ angle

Free to rotate

Conformations of protein can be specified this way

Amino acids can be post-translationally modified

1. cross links (very common)

Cysteine, disulfide residues used to link two polypeptides together, stabilize protein

2. phosphorylation (common in signal transduction)

phosphate group added to Ser, Thr, Tyr, His

3. Glycosylation (targeting, cell-surface display)

4. Methylation (epigenetic code in nucleosome)

Lys have methyl groups attached to them

5. Hydroxylation

Hydroxyl added to proline structure, defect w/o hydroxylation in connective tissue

Common in various types of collagen structure, defect -> loose joints

6. lipidation (targeting, signal transduction)

dipeptide

oligopeptide

protein (~40 a.a.)

enzymes -> ~100 a.a.

primary structure a sequence of R groups

talk about peptide from N-terminus to C-terminus

Alanyl-Glycine (Ala-Gly)

Glycyl-Alanine (Gly-Ala)

N-terminus peptide is translated first and then ends in C-terminal peptide

alanine, glutamic acid, leucine, methionine are preferred in alpha helix, glycine and tyrosine and serine almostn ever found in alpha helix

proline is common beta turns

Sickle cell anemia

Molecular disease - Linus Pauling

Glu (6) – Val (6) in beta chain of Hb ; hydrophilic to hydrophobic; the hydrophobic amino acid may try to aggregate with other hydrophobic molecules around the subunit, causing polymerization -> sickle cell shape

Protein purification

1. Lyse cells

2. Centrifugation

3. Fractionation (salting out)

4. Column chromatography

1. difference in protein charge, size, binding characteristics (affinity, antibodies, tag (His residue at N terminus) bind to nickel, very powerful)

chromatography types - affinity based most commonly used

ion exchange, beads negative, proteins with negative charges elute faster

Gel electrophoresis to check purity

Electric field, protein migrate through gel as a function of molecular weight

SDS denatures protein - disulfide bond breaks?

Sequencing protein

direct sequencing of peptides by chemical methods, difficult, rarely used; N-terminal sequence (Edman degradation), C-terminal (enzyme carboxypeptidase)

DNA sequencing of genes Most common way of obtaining massive amounts of sequence

Mass spectrometry of peptides (powerful) common way to identify particular protein after gel electrophoresis in complex mixtures

Reverse genetics

Protein -> all possible DNA sequences -> isolation of the gene; looking for possible genetic phenotypes from known sequence

Protein structure / folding

Favored by hydrophobic effect, hydrogen bonds, electrostatics

Modulated by side chain/main chain steric interactions

Opposed by loss of entropy

Non-covalent bonds

H-bond

Ionic

Hydrophobic

Van der Waals

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LECTURE : STRUCTURE OF NUCLEIC ACIDS

Chemistry of bases

5. bases are flat rings

6. bases are stacking on each other; they are planar and pi-orbital reinforce the stack

o purine stack better than pyrimidines

7. bases can form hydrogen bonds

o hydrogen bonds essential in maintaining tertiary structures

8. Chargaff’s rule (same amount of G/A and C/T)

9. Bases undergo tautomerism and resonance e.g. cytosine, then it can bind to thymine??

Nucleic acids are negatively charged (phosphate groups)

10. Proteins that bind to them tend to be positively charged

2’ OH group (DNA has H in 2’) makes the RNA more unstable, RNA can be hydrolyzed very easily by base

5' of carbon of sugar is where the phosphate is attached, and 3' is where is the hydroxyl group, 1' is where the base is

nucleoside - no phosphate group

NMP, NDP, NTP

RNA structure and function

11. mRNA(messenger) is one function

12. cellular RNA single stranded

13. many RNA form complex structures

14. many RNAs associated with proteins (RNP), e.g. telomerase, ribozyme

15. RNAs catalytic activity (ribozyme)

16. miRNA play regulatory roles
17. non-coding RNAs, mRNA, tRNA, miRNA present in both prokaryote and eukaryote
    

Enzymatic heart of ribosome is ribozyme (PT catalytic site no green); ribosomes are mainly composed of RNA and little protein

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LECTURE: pH

important properties of water

Kw = 1.0 * 10^-14 = [H+] [OH-], (mol/dm^3)^2

pH = -log[H+]

[H+]=10^-7; pH = 7

[HA] = [H+][A-]

Ka = ([H+][A-])/[HA]

-logKa = pKa

[H+] = Ka*[HA]/[A-]

-Log[H+] = -log(Ka) – log([HA]/[A-])

pH = pKa + log[A-]/[HA]

blood pH slightly alkaline

bigger Ka, stronger acid, lower pKa, stronger acid

when pH = pKa, max buffering capacity

Henderson Hasselbalch equation remember???

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DNA REPLICATION

General properties of DNA replication

17. semi-conservative

18. nucleotide added at 3’ end; DNA polymerase moves from 5’ to 3’ direction

19. requires an RNA primer; primase synthesizes short RNA primer
    

20. semi-discontinuous

o strand that is continuously synthesized in the direction of fork movement referred as leading strand; the other strand is lagging strand template, synthesized in short fragments Okazaki fragment

o asymmetric process: one continuous, one discontinuous

Okazaki fragments are joined by DNA ligase

21. initiation occurs at defined origin of replication

22. replication forks are bidirectional

DNA polymerase

23. cannot start de novo

24. requires an RNA primer, made by primase

Ligase joins Okazaki fragments

25. RNA primer removed, then the nick sealed by DNA ligase

DNA replication enzymology

26. DNA polymerase for leading and lagging strand

27. DNA helicase – separate strands

28. Gap in lagging strand template between Okazaki fragments; single stranded DNA is stabilized by single-stranded binding protein (SSB in prokaryote, RPA-replication protein/factor A, in eukaryote)

29. Sliding clamp: encircles duplex (newly synthesized) DNA, slides along DNA, helps tether DNA polymerase to the template

o Beta-clamp in prokaryote (dimer)

o PCNA in eukaryote (homotrimer), PCNA also serves as landing pad for many DNA repair and checkpoint proteins

30. Clamp loader loads sliding clamp to DNA

31. Topoisomerases break DNA strands, move them around and rejoin them

o Splits a DNA strand and pass the intact strand and then put the split DNA back together

o Also important in transcription(as well as replication)

o Type I breaks one strand(passes the other of sample duplex), type II breaks both strands of duplex

Replisome

- two polymerases interact with each other in some way: DNA polymerases of leading and lagging strands both move together in the same direction; therefore DNA is looped.

- in lagging strand, finish Okazaki fragment, easier to jump to next site of Okazaki fragments

- strand separation by helicase creates supercoiling

Replication from each origin is bidirectional

32. two forks of one double stranded DNA, lagging and leading reversed opposite side

eukaryotic chromosome has multiple origins

33. early origin fires early, late origin fires later

End replication problem

34. lagging strand’s RNA primer removed, then DNA polymerase can’t normally fill this gap; each replication results in lagging strand shorter => replicative senescence
35. leading strand 3'

35. telomeres = specialized structure/sequence at chromosome ends

o highly repetitive (GGGTTG)

36. telomerase – RNA-dependent DNA polymerase that extends lagging strand template

o adds more repeats enough to allow another Okazaki fragment to be added

37. somatic cells don’t use telomerase so they undergo senescence

38. tumor cells have telomerase that immortalizes them

Replication fidelity

39. DNA polymerase 5’ -> 3’: error rate 1/10^5

40. 3’ -> 5’ exonucleolytic proofreading increases fidelity by order of 10^2

41. Strand-directed mismatch repair increases fidelity by order of 10^2

42. => 1 / 10^9 nucleotides polymerized error rate

43. Price of high fidelity is a very slow enzyme

Proofreading - during replication

44. DNA polymerase won’t add to a 3’ end of a nucleotide that is not base-paired with template (RNA polymerase doesn’t have this function)

45. A – C mis-pair not properly base-paired

46. If 3’ end is not properly base-paired, that end will be sent to editing site of DNA polymerase, the false nucleotide clipped off

47. The clipped end goes back to polymerization site to attempt replication again
50. Mismatch repair (MutS and MutL proteins involved) - after replication, but part of proofreading function
    

o Recognize distortion in DNA, usually bound by some protein

o Complex finds a nick(differentiates new from old DNA strand) in new DNA strand, when nick found, the segment cut off and DNA synthesis in that segment is repeated

e.g. hereditary nonpolyposis colorectal cancer(HNPCC) results from defective mismatch repair

Positive and negative supercoil

why do we not have DNA primer in replication?

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DNA repair and recombination

Damage = chemical alteration in DNA

Mutation = permanent change in DNA

Change in a single nucleotide A/T -> G/C

Insertion/deletion of small number of nucleotide => homopolymer runs, same nucleotide over and over e.g. AAAAAA

Chromosome rearrangements

Insertions/deletion, duplication, inversion, translocation(exchange of pieces between non-homologous chromosomes)

Changes in chromosome number (aneuploides)

3 -> trisomy e.g. Down syndrome (trisomy 21)

Two classes of genes that maintain genome stability

Caretakers – repair genes, act directly on DNA

Gatekeeper – control cell cycle e.g. checkpoint proteins

Major sources of mutation

DNA replication errors – e.g by polymerase, correct by proof-reading and post replicative mismatch repair

DNA damage

49. spontaneous: as a result of normal metabolism in cells e.g. oxidative damage

50. induced: come from environment, chemical found in tobacco smoke, UV, ionizing radiation

If there’s damage in DNA,

1. damage pre-replication repair

a. direct reversal, DNA is directly repaired

b. excision repair, damage is excised from DNA

2. replication

c. translesion synthesis – specialized DNA polymerase, large pocket site for repair, downside is that it’s a very sloppy polymerase

d. homologous recombination

3. post-replication

e. mismatch repair

DNA damage

Altering base pairing properties, or destroys ability to base-pair

Common miscoding DNA lesions

1. Cytosine deanimated to uracil; CG -> T(U)A mutations

2. Guanine oxidated by ROS(reactive oxygen species) to 8-oxo guanine which pairs with A or C

Common lesions that block DNA polymerase

1. abasic sites (bond between base and sugar breaks)

2. UV-induced photoproducts (between pyrimidines)

a. Cyclobutyl dimer formed between covalent Ts, prevents DNA from getting into active site of polymerase

b. 6-4 photoproduct, linkage between pyrimidines, also block DNA polymerases

DNA if not repaired, can be bypassed/tolerated

1. homologous recombination

a. undamaged strand of DNA is used as a template to replicate and bypass the lesion; high fidelity

2. translesion synthesis, specialized DNA polymerases that come and fill in directly over the lesion; low fidelity

b. normal T, 75 nucleotide, but if thymine dimer present, stops at 44

c. if polymerase eta used, it is able to go right through the damage => bypass is error free

Repair of damaged DNA

51. direct reversal: e.g. thymine-thymine(pyrimidine) dimer caused by UV can be broken by photolyase + white light, also enzyme alkyl transferase removes alkyl group from base

52. base-excision repair – single base excised

o Glycosylase – each highly specific, recognize specific type of lesion; e.g. UNG – removes uracil, OGG – removes 8-oxoG

§ Cleaves sugar-base linkage, sugar phosphate backbone remains intact

o AP endonuclease(and phosphodiesterase) removes sugar phosphate, change abasic site to single nucleotide gap

o DNA polymerase adds new nucleotides, DNA ligase seals nick

53. nucleotide excision repair – oligonucleotide excised

o e.g. pyrimidine dimer removal

o recognizes any gross/bulky type of helix distorting lesion

o binds to the lesion, makes nicks on the strand that contains lesion on both sides, by nuclease

o DNA helicase removes the nicked strand

o DNA polymerase and ligase fill the gap

o Defective nucleotide excision repair -> e.g. xeroderma pigmentosum; XP can also result from absence of translesion synthesis DNA polymerase pol eta

54. Homologous recombination/Repair of double strand breaks

55. Double strand breaks very detrimental compared to single strand break

56. usually accidental e.g. x-ray UV

57. physiological, intentional – meiosis

o => meiosis (2n -> 1n): homologous chromosomes segregate, programmed double strand break for cross-over

58. loss of nucleotide from degradation from break ends

o ends ligated back together -> non-homologous end-joining

o copying from a homologous duplex molecule -> homologous recombination

59. homologous recombination may result in cross-over event

o important in mitotic cells as repair mechanism => may result in loss of heterozygosity during mitotic division by cross-over between sister chromatids => one cell homozygous for normal gene and one cell homozygous for mutant gene

60. Mismatch repair (part of replication proofreading function)

o Recognize distortion in DNA, usually bound by some protein

o Complex finds a nick(differentiates new from old DNA strand) in new DNA strand, when nick found, the segment cut off and DNA synthesis in that segment is repeated

Cell cycle checkpoints – allows time for repair of DNA damage

G1 -> G1 checkpoint -> S(Intra S check point) -> G2 -> G2 checkpoint (is all DNA replicated?) -> M -> G1

If damage present, cell cycle arrests

Intra S check point – check for problem during DNA replication

Rad52 mutant -> required for repair of double strand break

Irradiate Rad52 mutant, cell does not divide and dies

Irradiate Rad9 mutant -> cell does not arrest, result microcolony but all dies

RPA(same as SSB) can sense damage in DNA

Send signals to cause response to cells

1. can recruit DNA repair pathway

2. global transcriptional response

3. DNA damage checkpoint, cell arrest to repair DNA

4. Too much damage -> apoptosis triggered

remember the syndromes and functions?????????

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LECTURE : GENE AS INFORMATION

e.g. of RNA replicating themselves Dengue, HepD

Ribosomal RNA, tRNA DNA -> RNA and stop

more universal view of information flow??

Linearity of gene

Aminoacyl tRNA synthetase – recognize shape of a.a. side chain, sense the shape of tRNA that has correct anti-codon, and charge the tRNA with a.a. => particular tRNA bound to particular amino acid

Introns – intervening sequences, not found in mature product of mRNA

Exon – anything in mature mRNA

Edges between exon and intron are well defined

300 n exon, while 3,400 n introns

Average protein coding human gene will have 8/9 exons, while 7/8 introns

Sometimes exons may be large

Can intron of one gene can be exon of another?

there's no difference in genetic code between eukaryote and prokaryote, however there maybe code usage bias between types of organisms

Globin gene/ anatomy of small gene

Promoter

Open reading frame – define something that starts with AUG and codes for x number of amino acid

Untranslated regions in mRNA -> part of first and last exons respectively

Definition of 5’ end of exon is made by where the RNA polymerase makes first copy to RNA

5’ UTR - untranslated region -> open reading frame (product begins to be made)

Splice site(SS) – edges between exons and introns

5’ SS – donor, 3’ SS - acceptor

Exons made in capital letters, introns in small letters

3’ UTR – untranslated region of last exon before its 3’ cleavage site

3’ cleavage site that defines end of last exon

Pseudogenes – unknown function

Far distant elements(locus control region, LCR)

Repeated elements in gene cluster

Long interspersed elements (LINE)

Short interspersed elements (SINE)

Most of these belong to Alu family

Very abundant throughout genome

only codon not degenerate -> AUG

what causes thalassemia? deletion of LCR that prevents synthesis of any of Beta cluster

biosynthesis of vitamin

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TEAM SESSION

watson and crick pairing vs base excision repair vs mismiatch repair vs proofreading - high fidelity

what part of DNA helix is outward? sugar-phosphate backbone

RNA used in bacterial cell wall assembly(UDP, glycan synthesis)
vitamin biosynthesis(nucleotides can be cofactors in the synthesis of vitamin)

cytosine deamination, nitric oxide vs methylation, methylation is more common common

change the transcription factor(DNA binding protein), change the of fate cell -> differentiation cascade
pluripotent - cells that are able to differentiate into many cell types
totipotent - cells that are able to differentiate into all cell types

cell type defined by switch from one pattern of regulated gene expression to another -> different transcription factors that lead to different
asymmetric cell division/distribution of content of cells -> differentiation

DNA major groove and minor groove
One groove, the major groove, is 22 Å wide and the other, the minor groove, is 12 Å wide.
The narrowness of the minor groove means that the edges of the bases are more accessible in the major groove. As a result, proteins like transcription factors that can bind to specific sequences in double-stranded DNA usually make contacts to the sides of the bases exposed in the major groove

double strand break repair

Deactivate a specific residue and see if it affects biochemical activity
- introduce wildtype and mutant type to compare function
- causation than correlation

cancer cells avoid repair pathways

ion exchange chromatography, if pH low to high, elutes negative charged particles first and then gradually toward positive charged particles; positively charged protein bound to beads of column can be eluted by increasing the concentration of sodium chloride or another salt in the buffer, sodium ion will compete with positive charged particles for the bead. Low density positive charged particle will elute first, followed by high density.