Selection and characterization of bispecific ADAPT molecules for enhanced biodistribution in cancer therapy

Borin, Jesper

January 2020

Established biopharmaceuticals such as antibodies and derivatives thereof are relatively large. In cancer therapy, this creates a steep drug concentration gradient within tumors, leaving cells far from blood vessels effectively untreated. Continuous pseudo treatments should foster the development of drug resistance and might lead to eventual disease relapse. Drug concentration gradients can be operationalized as tissue penetration efficiencies, which are functions of molecular size. However, small particles are also subject to potent renal clearance, collapsing the therapeutic window beyond clinical applications. In this master’s thesis, spatial bispecificity was engineered into a single albumin binding domain (ABD). Resulting ABD derived affinity proteins (ADAPTs) are saved from urinary excretion by the grace of HSA, but in the more static microenvironment of tumors, following HSA dissociation, they are capable of tissue penetration efficiencies bestowed only upon smaller particles. To this end, phage display was used to raise ADAPTs against the cancer associated proteins human epidermal growth factor receptor 2 (HER2) and carcinoembryonic antigen-related cell adhesion molecule 6 (CEACAM6), but also the inflammation marker C-reactive protein (CRP). Via Sanger sequencing, 9 variants were picked for protein production and characterization, among which two spatially bispecific binders were found. ADAPTs were also evaluated for aggregation tendencies, structural conformity to library design, and thermal stability. One ADAPT, binding HER2, passed all tests of initial characterizations. Deep sequencing was used to analyze selection output, from which many more binders should be screened in future experiments. / Etablerade bioläkemedel liksom antikroppar och deras derivat är relativt stora protein. Som cancerterapeutiska skapar de således branta koncentrationsgradienter utgående från tumörpenetrerande blodkärl. Detta riskerar att lämna vissa cancerceller utanför det terapeutiska fönstret. Det svaga selektionstryck som således verkar i tumörperiferin fostrar cancerceller till att utveckla resistens mot detsamma. Koncentrationsgradienten beror på proteinets vävnadspenetrarande förmåga, vilken är en funktion av proteinets storlek. Mindre proteiner borde därmed lättare ackumuleras i hela tumören och förebygga resistensutveckling. Problemet med små proteiner är deras mycket korta halveringstid i serum, en följd av relativt obehindrad filtrering ut i urinen via njurarna. I det här examensarbetet utvecklades rumsbispecifika bindare av cancerassocierade protein med hjälp av fagdisplayselektioner från ett proteinbibliotek baserat på en enda albuminbindande domän (ABD). Resulterande ABD deriverade affinitetsprotein (ADAPT) undkommer ovan nämnda filtrering tack vare sin naturligt starka interaktion med humant serumalbumin (HSA). I den mer långsamt flödande tumörmikromiljön tillåts ADAPTerna efter albumindissociation sedan utöva en bland bioläkemedel överlägsen vävnadspenetration. Tre parallella selektionsspår utfördes mot de cancerassocierade målproteinerna human epidermal growth factor receptor 2 (HER2) och carcinoembryonic antigen-related cell adhesion molecule 6 (CEACAM6) samt den utsöndrade inflammationsmarkören C-reaktivt protein (CRP). Via Sangersekvensering kunde flera kandidater identifieras. Bland 6 karakteriserade ADAPTer uppvisade samtliga hög HSA-affinitet, tre konstaterades interagera specifikt med sitt målprotein, och två verkade binda även rumsbispecifikt. ADAPTer utvärderades även för sin benägenhet att bilda aggregat, strukturell överensstämmelse med experimentell design, och värmestabilitet. Endast en bindare, mot HER2, klarade sig genom alla prövningar som proteinkarakteriseringen innebar utan underkänt. Även en högparallel sekvensering utav selektionsresultat utfördes, men utanför de tidsramar som tillät ytterligare karakterisering.

ABD

ADAPT

HER2

CEACAM6

HSA

Phage display

Cancer therapy

Spatial bispecificity

Half-life extension

Biodistribution

Medical Biotechnology

Medicinsk bioteknologi

Characterization of novel bispecific ADAPTs selected for cancer-related targets

Hedin, Blenda

January 2021

Cancer is still one of the most common causes of death world-wide and in parallel there is a need to update the repertoire of therapies that withstand resistance of recurrent cancers. Since the introduction of antibody therapies as anti-cancer pharmaceuticals, recognized as immunotherapy in health care, it has been an increasing field in cancer therapy, as a more targeted treatment compared to chemotherapy. Despite the great success, immunotherapy rely on parenteral administration, partly due to poor tissue penetration. If the treatment is administered intravenously, specialized personnel is required, in addition to that it can be inconvenient for the patient. Also, pharmaceuticals based on antibodies often require costly production steps which yields a high-priced treatment. To approach this problem, researchers have developed small affinity domains with the aim to increase tissue penetration while keeping a high specificity to its target. Albumin Binding Domain Derived Affinity Protein (ADAPT) is an example of a small affinity domain of only 7 kDa, which is based on albumin binding domain (ABD) from the streptococcal protein G. Recently, it was shown that the ADAPTs can be further engineered to bind albumin and another relevant target protein of interest simultaneously, which suggests a tolerable half-life in patient serum, alternative administration routes and lower production costs compared to antibody treatments. Furthermore, less side effects are expected due to higher specificity compared to chemotherapy. This work presents the characterization of novel ADAPT proteins that the target the cancer relatedproteins C-C motif ligand 7 (CCL7), vascular endothelial growth factor A (VEGF-A) and carcinoembryonic antigen related cell adhesion molecule 5 (CEACAM5). The new constructs were produced recombinantly in Escherichia coli (E. coli) and purified using affinity chromatography. Moreover, the results demonstrate bispecific binding with high affinity towards serum albumin and CCL7 and CEACAM5 respectively, while the ADAPT variants targeting VEGF-A remain to be further developed. Lastly, the importance of different amino acids for structural and binding properties of one CEACAM5 binder are stated. It reveals that the target binding relies on hydrophobic interactions which also can be connected to its poor structural attributes. Accordingly, this project adds new insights about the ADAPTs which can be useful in research towards future clinical applications aimed to improve cancer treatments.

cancer therapy

alternative administration routes

ADAPT

ABD

protein technology

albumin

simultaneous bispecificity

CCL7

CEACAM5

VEGF-A

Medical Biotechnology

Medicinsk bioteknik