Biologics B - mAbs recycling

Question 1

What receptor mediates recycling of albumin and IgG.?

Answer 1

Neonatal Fc Receptor (FcRn)

Question 2

Steps in mAbs recycling:

Answer 2

• Fc region binds to FcRn (FcRn is one of the critical quality attributes)
• IgG binds at at acidic pH (endosomal, pH 6), low affinity at pH 7-7.4.
• IgG taken up by monocytes or endothelial cells through endocytic mechanisms
• IgG not bound will be sorted to lysosomes for degradation
- Fv region may also bind to FcRn and alter interactions
- Antibody and antigen complexes are also recycled through FcRn pathway

Question 3

How can you modify FcRn binding affinity?

Answer 3

by changing AA sequence

Question 4

Different types of IgG’s and their half lives:

Answer 4

IgG types 1, 2 and 4 have an average 21days half life

IgG type 3 has an average 7 days half life.

Question 5

Glycosylation impact on mAbs PK:

Answer 5

• All IgGs (natural and recombinant) are glycosylated. Need to ensure that this is characterised
• Glycosylation is not required for an IgG antibody’s long half- life
• However for Fc fusion proteins, The shorter half-life of an Fc-fusion molecule in comparison to the whole IgG has been attributed to the lower binding affinity to FcRn, the glycan mediated disposition and the receptor (of fusion partner) mediated disposition

Question 6

Charge and PI (isoelectric point) impact on mAbs PK?

Answer 6

• The charge is important as often the surface of a cell/receptors are negatively charged so it is something that you may modulate. I.e. something that is positively charged may bind more easily.
• Changing the pI of mAbs is powerful way to improve KP.
• Charges variation can arise from manufacturing processes
• Charges differences may impact on both PK and PD

Question 7

Administration of therapeutic mAb may result in the formation of:

Answer 7

anti-drug antibodies (ADA)

Question 8

What do ADA’s do?

Answer 8

• ADA bind to the mAb, form immune complexes impacting on PK, PD, safety and efficacy of mAbs.
  • May cause hypersensitivity responses such as anaphylaxis and infusion reactions, and accelerated clearance of drug
  • ADA can be neutralizing or non-neutralizing (bind to the epitopes not needed for activity)
  • Immunogenicity of mAb varies across species
  • Drop of mAb concentration in blood: ensure to provide sufficiently high dose levels to achieve the desired exposure.

Question 9

Summarise the attributes and their effect on mAB characteristics:

Answer 9

1) Binding - binding very specific for target antigen. Binding to FcRn and recycling contributes to half life.
2) PK/PD - PK usually dependent on biology of target antigen and PD
3) Dose proportionality - non linear PK at low doses. Linear PK at high doses after saturation of target
4) Distribution - distribution usually limited to blood and interstitial spaced
5) Metabolism - catabolism by proteolytic degradation into amino acids
6) Excretion - no renal clearance of intact antibody

7) immunogenicity - formation of ADA against mAb could occur. ADA will impact on PK, PD, efficacy and safety.
Immunogenicity in animals not predictive of humans

Question 10

Novel antibody formats can be clustered in:

Answer 10

▫ Antibody fragments,
▫ Fusion protein – different parts and try to create something that works
▫ Antibody drug conjugates – antibody, cytotoxic, mab???
▫ Bispecific – modified igg’s to which a second variable region has been attached therefore two targets making them much more specific. However, complex to produce.
▫ Multispecific antibodies possessing multiple antigen binding sites

Question 11

Novel format are more complex than mAbs e.g.:

Answer 11

▫ Different antigen-binding domain in the same molecule,
▫ Different molecular domains linked through flexible linkers – pick and choose what you want in structure and discard what you don’t want
▫ Heterogeneous product through conjugation, synthesis, physical chemical attributes.
▫ Overall decrease of conformational stability (form aggregates which are likely to result in loss of dose), decreased solubility

Question 12

What are antibody fragments:

Answer 12

▫ Skip the Fc part of the mAb
▫ Most prominent is the fragment antibody binding part (Fab)
▫ Others scFv, single domain antibodies (sdAbs)
▫ ScFv made of VH flexibly linked to VL

Question 13

What are fusion proteins?

Answer 13

▫ Major class of new products
▫ Comprise a protein, peptide or receptor exodomain fused to the Fc region of the mAb
▫ Fc portion typically contains the hinge region usually along with the conserved N-glycosylation site in the CH2 domain
▫ Half-life extended

Question 14

What are ADC’s?

Answer 14

▫ mAb employed as drug delivery agents with chemotherapeutic drugs, immunotoxins, radioisotopes or cytokines.
▫ Cleavable linker in either Lys or Cys residues allowing release of payload

Question 15

What are multifunctional antibodies?

Answer 15

▫ Bispecific or multispecific antibodies contain two or more variable domains with specific affinity to bind to different antigens
▫ Bispecific formats comprise IgG like and Fab fragment based constructs.

Question 16

Structure of recombinant human insulin:

Answer 16

• Monomer (51 AA) little protein structure
• Exists naturally in hexameric structure of 6 insulin monomers
• Hexamer adopts structure of globular protein
• Two axial Zn ions (purple overlaid) coordinated by
• 6 Histidine side chains (white overlaid)
• Engineering of structure and formulation to achieve fast acting and long acting insulins

Question 17

Fast acting prandial insulin engineering of Zn hexamer affecting dimer assembly:

Answer 17

• Mutation of one or more amino acids in protein sequence disrupt assembly
• Conversion to dimeric and monomeric
• Faster acting on sub-cut admin
• Rapid absorption at epithelia barriers
• Rapid response from insulin pumps

Question 18

Modification and mechanism Lispro (Humalog)?

Answer 18

Pro 828 –> Lys

Impairs dimerisation

Question 19

Modification and mechanism of Aspart (Novolog)

Answer 19

Lys –> Pro

Charge repulsion at dimer interface

Question 20

Modification and mechanism of Glulisine (Apidira)

Answer 20

Asn83 –> Lys

Decreased zinc self association

Question 21

Explain the changes in size of the 3 pH controls, and the RHI & BIOD products:

Answer 21

Monomeric at pH2 ~ 2 nm size, shift  hexameric ~5nm when diluted at pH7
Hexamers pH 7 ~5nm decline on dilution with appearance of monomers/dimers
RHI initial size ~3.5nm (underestimation artefact), but hexameric on dilution
BIOD size above hexameric, suggesting chelators binding Zn ions had only loosened its structure & increased size.
However, upon dilution, mean size declined towards monomeric insulin, possibly with some dimers, indicating chelation of Zn ions disrupting hexamers on dilution

Question 22

Compare and explain the PK and PD upon sub-cut admin of the different insulin products & identify the product(s) best suited to mealtime glycemic control with least risk of post-prandial hypoglycemia:

Answer 22

• RHI hexamers slower dissociation into monomers/dimers & absorption into blood, delaying control –> hyper’, extended action risking hypoglycemia.
• BIOD & Lispro monomer formulations most rapid rise and also most rapid decline in serum insulin, more effective hyperglycemic control.
  BIOD Zn chelation-weakened hexamer, so dilution on admin results in faster dissociation & transport to capillaries to absorb into blood.
  Lispro structural modified to weaken dimer formation, with faster monomer formation in equilibrium with hexamers, facilitating more rapid absorption
• Rapid decline in blood glucose halts after 2h, small rise in glucose as insulin declines, rapid & short-acting glycemic control with low hypo’ risk

Question 23

Mouse to human antibody development:

Answer 23

• Human hybridomas difficult, mouse B cells & mAbs initially used

Development over last 2 decades progressed to human mAbs:

• chimaeric - mouse variable region (Fv, antigen binding) on otherwise human antibody
• humanised – mouse antigen binding loops (CDRs) on otherwise human antibody
• human – fully human antibodies produced via mouse

Question 24

Issues of using mouse antibody development?

Answer 24

• -> immunogenic anti-mouse reactions & rapid clearance

- -> lack human effector functions (Fc differences).

Question 25

Fully human recombinant antibodies formation:

Answer 25

4 mouse IgG gene loci coding for the 4 protein subunits of IgG replaced with human transgenes to produce a transgenic mouse with human IgG proteins
mouse immunised to raise immune response

Question 26

Human IgG recycling:

Answer 26

Half life 14-21 days:

pH dependent interaction with FcRn, preventing renal clearance, and allowing infrequent dosing

Question 27

Where there are relatively large loading doses and an intravenous route of administration (eg infliximab), acute concentration – time profiles result with ___________.

Answer 27

Very high peak concentrations

Trough’ drug level typically monitored before next dose

Question 28

Low levels of ADA’s=

Answer 28

Patient responded effectively to treatment

Question 29

Fc fragment engineering maintains:

Answer 29

interaction with immune system & binding site for antibody recycling receptor FcRn to enable long circulation times, but may not yet be as long in practice.

Question 30

Consider the structure of:

• Human antibody
• Humanized antibody
• Chimeric antibody
• Fc fusion domain protein

Explain why circulation T1/2 related to the KD of Fc-FcRn interaction

Answer 30

• Binding of human Fc proteins to the FcRn cell receptor recycles the proteins back into circulation from kidneys and other tissues.
• Binding to FcRn in endosomes at pH 6, recycles bound protein with the FcRn back to the cell surface, where the Fc – FcRn interaction weakens at neutral physiological pH.
• Higher affinity interactions result in stronger binding and a greater proportion of bound protein, whereas unbound protein would not be recycled and would become degraded and lost from circulation.

Question 31

Consider the structure of:

• Human antibody
• Humanized antibody
• Chimeric antibody
• Fc fusion domain protein

Explain why circulation T1/2 related to the KD of Fc-FcRn interaction. Explain why chimeric antibodies did not share this relationship

Answer 31

• Chimeric antibodies have human Fc domains, with similarly low KD or high affinity interactions with FcRn cell receptor, which would be expected to result in their recycling and longer circulation times.
• ADAs against the Fc region may be produced through loss of peripheral tolerance in some conditions (e.g. inflammatory), resulting in blocking of their Fc interaction with FcRn recycling receptor.

Question 32

Consider the structure of:

• Human antibody
• Humanized antibody
• Chimeric antibody
• Fc fusion domain protein

Explain why Fc fusion proteins showed lower T1/2

Answer 32

• Fusion proteins bearing the human Fc domain might be expected to show long circulation times in blood.
  However, they showed higher dissociation constants, or lower affinity or weaker interactions with FcRn.
• This may be expected to result in lower proportions of these proteins bound to the FcRn and so lesser recycling back into circulation, resulting in shortened half lives.
• Engineering target binding structures onto the Fc domain may alter the structure of the Fc domain or sterically hinder its interaction with the FcRn receptor.