IC8 Recombinant protein

Question 1

Protein pharmaceuticals
Advantages

Answer 1

High specificity & activity ⇒ high potency
Relatively low concentrations ⇒ lesser SE

Question 2

Protein pharmaceuticals
challenges

Answer 2

1. antigenicity
2. stability (biological, chemical, physical)
3. drug delivery

Question 3

Protein pharmaceuticals
challenges: antigenicity reasons

Answer 3

Foreign proteins may induce immunogenic response from human host

Question 4

Protein pharmaceuticals
challenges: antigenicity LT effects

Answer 4

Loss of efficacy due to development of Ab in the patient’s body against an exogenous protein

Can counter by increasing dose, but might cause SE

Question 5

Protein pharmaceuticals
challenges: stability - how methods of destabilising

Answer 5

(1) denaturation, (2) covalently modifying protein, (3) partially degrading it

loss of proper 3D confirmation ⇒ loss of biological activity

Question 6

Protein pharmaceuticals
challenges: stability - when destabilisation occurs

Answer 6

1. Protein recovery from its source (extraction procedures)
2. Protein purification process
3. Post-protein purification (protein storage)

Question 7

Protein pharmaceuticals
challenges: stability - when destabilisation occurs
post-protein purification problems

Answer 7

1. Proteolysis due to enzymes associated with bacterial contamination; bacteria produces proteases that hydrolyses protein
2. Storage of proteins in solution → protein degradation (specific amino acids contribute to destabilisation) ⇒ hence protein products usually stored in freeze-dried form (solid)

Question 8

Protein pharmaceuticals
challenges: stability - shelf-life

Answer 8

before reconstitution ~2-3 years
after reconstitution ~7 days to 1 month

storage temperature @ 2-8℃

Question 9

Protein pharmaceuticals
challenges: stability - changes in potency

Answer 9

generally decreases over time due to unfolding of protein ⇒ reduced clinical effects

Question 10

Mechanisms causing instability of protein pharmaceuticals

Answer 10

physical & chemical

Question 11

Mechanisms causing instability of protein pharmaceuticals:
physical - Protein aggregation

progression

Answer 11

native <-> unfolded -> aggregated

Question 12

Mechanisms causing instability of protein pharmaceuticals:
physical - Protein aggregation

Expression of protein physical stability

Answer 12

difference in free energy ∆G between N & U states

Question 13

Mechanisms causing instability of protein pharmaceuticals:
physical - Protein aggregation

Unfolding reversibility conditions

Answer 13

reversible: If remove unfavourable conditions
irreversible: Continuous exposure to unfavourable conditions

Question 14

Mechanisms causing instability of protein pharmaceuticals:
physical - Protein aggregation

Aggregated proteins: how it occurs

Answer 14

Subsequent aggregation of denatured molecules

Question 15

Mechanisms causing instability of protein pharmaceuticals:
physical - Protein aggregation

Aggregated proteins: impact

Answer 15

irreversible denaturation
Aggregated proteins have altered immunity & may arouse immunogenicity

Question 16

Mechanisms causing instability of protein pharmaceuticals:
physical - Protein aggregation

Aggregated proteins: Hydrophobic force

Answer 16

major force for protein unfolding & aggregation

*Due to exposure of hydrophobic surfaces → result of chemical degradation/ modifications
Might also be due to unfavourable physical & chemical factors occurring simultaneously

Question 17

Physical factors affecting protein stability

T, P, A, SS, NA, FT, P

Answer 17

1. Temperature
2. pH
3. Adsorption
4. Shaking & shearing (agitation)
5. Non-aqueous solvents
6. Repeated freeze-thaw
7. Photodegradation

Question 18

Physical factors affecting protein stability (T)

Answer 18

Increased temp promotes protein unfolding by disrupting non-covalent forces that stabilise protein’s conformation ⇒ encourages denaturation
Denatured proteins aggregate → irreversible denaturation.

Question 19

Physical factors affecting protein stability (P)

Answer 19

Proteins unfold at extreme pHs due to changes in ionisation status of side chains of amino acid residues
Causes confirmation changes → protein starts unfolding ⇒ aggregation

Disruption of distribution of ionic attractive & repulsive forces that stabilise protein’s conformation

Question 20

Physical factors affecting protein stability (A)

Answer 20

Proteins can be adsorbed to many surfaces & interfaces → especially plastic
Significant change in secondary structure & tertiary structure → change in 3D conformation
Loss of proteins or destabilisation of proteins (due to aggregation)

Question 21

Physical factors affecting protein stability (SS)

Answer 21

Incorporation of air into protein solution, creates air/liquid interface
Alignment of proteins along such interfaces → unfolding of protein to maximise exposure of hydrophobic residues to air ⇒ partial or complete protein denaturation

Question 22

Physical factors affecting protein stability (NA)

Answer 22

Protein hydration shell may be disrupted
Protein hydrophobic core exposed when polarity of aqueous solvent decrease → Protein unfolds ⇒ LR: protein degradation

Question 23

Physical factors affecting protein stability (FT)

Answer 23

Formation of sharp ice crystals → can pierce through 3D conformation of protein
Polypeptide chain encouraged to unfold ⇒ protein degradation

Question 24

Physical factors affecting protein stability (P)

Answer 24

Risk of protein aggregation upon exposure to light ⇒ important to store in amber bottle

Question 25

Mechanisms causing instability of protein pharmaceuticals:
chemical instability

Answer 25

1. Deamination
2. Oxidation
3. Disulfide bond breakage & formation
4. Hydrolysis

Question 26

susceptible amino acids of deamination

Answer 26

Asn & Gln

Question 27

susceptible amino acids of Oxidation

Answer 27

His, Met, Cys, Trp, Tyr

Question 28

susceptible amino acids of Disulfide bond breakage & formation

Answer 28

Cys

Question 29

susceptible amino acids of Hydrolysis

Answer 29

Asp-Gly & Asp-Pro

Question 30

Oxidation: how it works

Answer 30

Catalysed by transition metal ions at/ near metal binding sites of proteins
Reactive oxygen species generated → drives oxidation

Question 31

Disulfide bond breakage & formation: how it works

Answer 31

Occurs between 2 cysteine residues → sulfhydryl groups between cysteine molecule joined together to form S-S

Question 32

Disulfide bond breakage & formation: effects on stability

Answer 32

Sometimes needed to favour stability in some proteins

sometimes detrimental to protein stability:
Destroys activity of proteins; more so if cysteine residue in reduced form is required for activity

Question 33

Methods for stabilisation & formulation of protein pharmaceuticals (liquid)

Answer 33

1. Substitution & chemical modifications (Internal)
2. Changing properties of solvent & additives (external)

Question 34

Methods for stabilisation & formulation of protein pharmaceuticals (liquid)
1. Substitution & chemical modifications (Internal): methods

Answer 34

a. Amino acid substitution/ modification
b. Introduction of disulfide bonds
c. PEGylation (conjugation)
d. Acylation (conjugation)

Question 35

Methods for stabilisation & formulation of protein pharmaceuticals (liquid)
1. Substitution & chemical modifications (Internal): requirements

Answer 35

Internal changing of structural characteristics without compromising activity ⇒ improves protein stability

Question 36

Methods for stabilisation & formulation of protein pharmaceuticals (liquid)
1. Substitution & chemical modifications (Internal): Introduction of disulfide bonds - how it works

Answer 36

Stabilise folded form of proteins

Question 37

Methods for stabilisation & formulation of protein pharmaceuticals (liquid)
1. Substitution & chemical modifications (Internal): PEGylation (conjugation) - how it works

Answer 37

Chemical attachment of polyethylene glycol (PEG)
Can keep in native form for longer periods
Increase circulation time in blood

Question 38

Methods for stabilisation & formulation of protein pharmaceuticals (liquid)
1. Substitution & chemical modifications (Internal): acylation (conjugation) - how it works

Answer 38

Chemical attachment of fatty acids to residues on protein surface
FA:
Lipophilic; makes overall complex more lipophilic ⇒ expels water
Maintains protein stability

Increase circulation time in blood

Question 39

Methods for stabilisation & formulation of protein pharmaceuticals (liquid)
2. Changing properties of solvent & additives (external) - methods

S, SE, AA, B, PA

Answer 39

Stabilisers: sugars, polyols
Solubility enhancers: Lysine, arginine, surfactants
Anti-adsorption & anti-aggregation agents: Albumin, surfactants
Buffer components: Phosphate salts (Na2HPO4, NaH2PO4)
[Prevents extreme acidic/ alkaline conditions]
Preservatives & antioxidants: Inert gas, thimerosal, phenol, benzyl alcohol
[Prevents oxidation]

Question 40

Process of making recombinant protein

Answer 40

Upstream & downstream

Question 41

Upstream process of making recombinant protein

Answer 41

1. Host cells transfected with recombinant DNA (carrying desired gene)
2. Each transfected cell is different from each other in terms of number of copies of plasmids transfected
   (Higher number of copies of plasmids = higher amount of protein expressed)
3. ONLY 1 transfected cell with best cell growth properties & highest protein yield ⇒ development of master cell line

Question 42

Upstream process of making recombinant protein
requirements of host cell

Answer 42

ensure purity & no trace of host cell components in final product ⇒ safety & quality ensured

Question 43

Upstream process of making recombinant protein
cells to use

Answer 43

1. E.coli
2. CHO

Question 44

Upstream process of making recombinant protein
1. E.coli indication for use

Answer 44

for small proteins production & to obtain high yield @ low cost
(Large protein production → might cause formation of inclusion bodies)

Question 45

Upstream process of making recombinant protein
1. E.coli advantages

Answer 45

1. facilitates genetic manipulation (high success rate)
2. High expression levels of recombinant protein (up to 30% of total cellular protein)
3. Grows rapidly on simple & inexpensive media → doubles every 20 mins

Question 46

Upstream process of making recombinant protein
1. E.coli disadvantages

Answer 46

Recombinant protein accumulates intracellularly

Lack the ability to perform post-translational modifications (ie. glycosylation) –> Cannot use E.coli if glycosylation required by human protein for therapeutic fx

Presence of lipopolysaccharides (LPS) on its surface → act as pyrogens
- Have both lipophilic & polar ends → difficult to remove in downstream processes
- Fever inducing; when introduced into bloodstream → may lead to inflammatory response, shock or multi-organ failure ⇒ death

Question 47

Upstream process of making recombinant protein
1. E.coli: solubility of proteins

Answer 47

Soluble proteins = in native conformation
insoluble proteins = incorrect conformation

Question 48

Upstream process of making recombinant protein
1. E.coli: why formation of inclusion body occurs

Answer 48

proteins are synthesised rapidly & in high levels

Question 49

Upstream process of making recombinant protein
1. E.coli: processing of inclusion body

Answer 49

Isolation of inclusion bodies
Insoluble products; if protein in native formation → will be soluble

Solubilisation of protein with denaturant
Breaks up non-covalent interactions in unfolded polypeptide chain → protein unfolds to primary polypeptide chain ⇒ soluble

Refolding of protein outside cell
Native conformation → soluble
Incorrectly folded protein → insoluble, will form aggregate

Question 50

Upstream process of making recombinant protein
2. CHO indications

Answer 50

Large protein production
Post-translational modification required
Crucial for solubility & native folding

Question 51

Upstream process of making recombinant protein
2. CHO advantages

Answer 51

• Capable of adapting & growing in suspension culture → ideal for large scale culture
• Pose less risk → few human viruses can propagate in them ⇒ less likely to have cross infections
• Can grow in serum-free media → ensures reproducibility between different batches of cell culture [independent of human component]
• Allow post-translational modifications to recombinant proteins
• Can be manipulated by genetic engineering techniques to produce a higher yield of recombinant proteins

Question 52

Downstream process of making recombinant protein

Answer 52

Purification: protein isolation, concentration & purification steps, viral inactivation steps

Question 53

Downstream process of making recombinant protein
purpose

Answer 53

To obtain protein of interest that is purified
To remove other CHO/ E.coli proteins → trace amount in final product results in immunogenicity

Question 54

Testing of product: 2 methods

Answer 54

Quality control
safety testing

Question 55

QC: purpose

Answer 55

confirm conformance of final product to predetermined specifications
Must be done for every batch of products

Question 56

QC: methods

Answer 56

1. Bioassays/ potency testing
2. Immunoassays
3. Mass spectrometry
4. Peptide mapping
5. Amino acid analysis
6. N-terminal sequencing
7. Isoelectric focusing

Question 57

QC: bioassay purpose

Answer 57

assess activity of product in a biological system; whether the product can work on the substrate

Question 58

QC: bioassay - how it works

Answer 58

Activity of product → “units of activity” per vial/dose of the product
* Chosen at random
* Quantitative measure against a “standard” preparation of known activity

Question 59

QC: bioassay Drawbacks

Answer 59

Time consuming
High cost
Do not reveal purity of final product → no information about contaminant (safety profile not considered)

Question 60

QC: Immunoassays - how it works

Answer 60

Use of antibodies to quantify product → ELISA, agglutination

Question 61

QC: Immunoassays advantage

Answer 61

straightforward, fast, less costly

Question 62

QC: Immunoassays disadvantage

Answer 62

Quantity of product ≠ biological activity of product
do not reveal purity of final product (cannot detect presence of contaminants)

Question 63

QC: mass spectrometry - how it works

Answer 63

Each protein made have unique mass spectrum

Comparing mass spectrum of each batch of final product (against a highly pure “standard”) will allow identification of possible contaminants in the samples

Presence of extra peaks in results → likely additional ingredients that do not belong to human recombinant

Question 64

QC: peptide mapping purpose

Answer 64

product identification & detection of protein contaminants

Question 65

QC: peptide mapping - how it works

Answer 65

Protein product hydrolysed using reagents specific in cleaving specific peptide bonds (e.g. cyanogen bromide, trypsin) → gives unique peptide fingerprint (by mass spec, 2D gel electrophoresis, RP-HPLC)
* Predictable location of cleavage & what kind of peptides will be produced

Question 66

QC: peptide mapping disadvantage

Answer 66

Does not tell activity of product

Question 67

QC: Amino acid analysis - how it works

Answer 67

Protein hydrolysed into amino acids → separated by ion exchange chromatography & quantified.

Question 68

QC: Amino acid analysis indication

Answer 68

characterising peptide or small polypeptide product of < 10kDa

Question 68

QC: N-terminus sequencing purpose

Answer 68

identification of protein product

Question 69

QC: N-terminal sequencing - how it works

Answer 69

Sequencing of the first 20-30 amino acids of the protein at the N-terminus

Question 70

QC: Isoelectric focusing purpose

Answer 70

determine sialic acid content in glycoproteins

Question 71

Safety testing: purpose

Answer 71

Assessment of presence of impurities; prevention of immunogenicity issues

Question 72

Safety testing: methods

Answer 72

1. SDS-PAGE
2. Isoelectric focusing dye binding methods (colorimetric assays)
3. DNA hybridisation
4. Rabbit pyrogen test
5. Litmus amoebocyte lysate (LAL) test
6. Viral assays
7. In vivo bioassays

Question 73

ST: SDS-PAGE - how it works

Answer 73

High resolution electrophoretic separation of proteins based on molar mass (for SDS-PAGE) or protein folding (for native PAGE)
Visualisation of separated proteins by protein stains

Question 73

ST: SDS-PAGE detection

Answer 73

Detection of product variants possible using product-specific Ab in Western blot

Question 74

ST: isoelectric focusing - how it works

Answer 74

Separation of proteins by isoelectric point (pI)
Can be used with SDS-PAGE in 2D electrophoresis → provide added dimension of separation to detect contaminants

Question 75

ST: isoelectric focusing (secondary purpose)

Answer 75

monitor homogeneity of glycoproteins’ sialic acid content
* sialic acid on glycan charged → affects pI of glycoprotein

Question 76

ST: DNA hybridisation purpose

Answer 76

For detection of DNA contaminants in ng range

Question 77

ST: rabbit pyrogen test - how it works

Answer 77

Detection of pyrogen by injecting product into healthy rabbits
Increased temperature = presence of pyrogen

Question 78

ST: LAL test - how it works

Answer 78

Endotoxin stimulated coagulation of amoebocyte fraction in blood of horseshoe crabs (Limulus)

Question 79

ST: LAL test advantages

Answer 79

less variable, more sensitive, faster, cheaper

Question 80

ST: LAL test disadvantages

Answer 80

only detects endotoxin-based pyrogens

Question 81

ST: viral assays - purpose

Answer 81

TEST FOR:
specific viruses capable of contaminating source materials AND
unknown/uncharacterised viruses not widely available or employed

Question 82

ST: viral assays - how it works

Answer 82

Use of Immunoassays using Ab specific for panel of viruses (to do as a panel)

incubation of product with cell lines sensitive to range of virus (ie: Vero cells) OR
injection of product into animals for stimulation of antibody production & subsequent testing of specificities of Ab raised in the animals against a panel of viruses

Question 83

ST: In vivo bioassays purpose

Answer 83

general safety testing → ie injection into healthy mice

Question 84

Biosimilars definition

Answer 84

Biologic that is almost an identical (ideally identical) alternative version of original biologic (innovator/ reference biologic) manufactured by different country

Question 85

Biosimilars - variability (how it occurs)

Answer 85

occurs even within batches of same product

1. variability of biological expression system & manufacturing process
2. Process of manufacturing (upstream & downstream) influences nature of final product

Question 86

Biosimilars: chemical drugs (pdn of generic drugs)

Answer 86

No issue with production of generic drugs → analytical criteria based on chemical compositions

Question 87

Biosimilars: biologics with low MW

Answer 87

More straightforward development of biosimilars ⇒ approval of several biosimilars

Question 88

Biosimilars: mABs with post-translational modification
problem of biosimilarity

Answer 88

impossible to engineer a biosimilar 100% identical to innovator biologic ⇒ ONLY CAN produce a highly similar biosimilar

Question 89

Biosimilars: mABs with post-translational modification
reasons for variability

Answer 89

Pattern of glycosylation & amount of glycosylation dependent on cell production system (i.e. type of host cells used for culture)

For the same monoclonal Ab for innovator & biosimilar biologic produced in same host cells, glycosylation may be different → other factors like cell culture conditions can influence glycosylation.

Question 90

Biosimilars: requirements for approval

Answer 90

1. Extensive in vitro studies demonstrating similarity to a reference biologic.
2. Non-clinical & clinical studies demonstrating comparable pharmacokinetics (PK), clinical efficacy, safety & immunogenicity