BEH.462/3. 962J Molecular Principles of Biomaterials Spring 2003 Lecture 4: Degradable Materials with Biological Recognition(part Biological recognition in vivo Engineering biological recognition of biomaterials: adhesion/migration peptides Engineering biological recognition of biomaterials: enzymatic recognition and cytokine Reading S.E. Sakiyama-Elbert and J.A. Hubbell, Functional Biomaterials: Design of Novel biomaterials, Annu. Rev. Mater. Sci. 31, 183-201(2001) J.C. Schense et al., 'Enzymatic incorporation of bioactive peptides into fibrin matrices enhances neurite extension, Nat. Biotech. 18, 415-419(2000) Supplementary Reading The Extracellular Matrix, pp. 1124-1150, Molecular Biology of the Cell, Lodish et al Recognition of Biomaterials by proteases: Engineering Enzyme-mediated degradation of polymers Basic concept: include peptide sequences in the polymer chain which are cleaved by enzymatic activity of serum proteins/cellular secreted products(active breakdown)[hydrolysis active but slow.] Amide bond-(NH)-(CO)-provides natural hydrolytic mechanism for degradation, but breaks down very slowly in physiological conditions Remodeling enzymes in vivo 1)binding of target by enzyme 2)specific site cleavage What is enzymatic cleavage used for in vivo?(Reading Ch 1 4 Voet and Voet"Enzymatic catalysis) o Remodling ECM, migration of cells through matrix o Removing functional groups from signaling molecules(phosphorylation/dephosphorylation) Utility in the design of biomaterials o Polymers can be designed to be surface-eroding easily (enzyme can't access interior) o Degradation could be localized to tissue where enzyme is produced Lecture 4- Biological Recognition pt. 2 1 of 9
BEH.462/3.962J Molecular Principles of Biomaterials Spring 2003 Lecture 4: Degradable Materials with Biological Recognition (part II) Last time: Biological recognition in vivo Engineering biological recognition of biomaterials: adhesion/migration peptides Today: Engineering biological recognition of biomaterials: enzymatic recognition and cytokine signaling Reading: S.E. Sakiyama-Elbert and J.A. Hubbell, ‘Functional Biomaterials: Design of Novel biomaterials,’ Annu. Rev. Mater. Sci. 31, 183-201 (2001) J.C. Schense et al., ‘Enzymatic incorporation of bioactive peptides into fibrin matrices enhances neurite extension,’ Nat. Biotech. 18, 415-419 (2000) Supplementary Reading: ‘The Extracellular Matrix,’ pp. 1124-1150, Molecular Biology of the Cell, Lodish et al. Recognition of Biomaterials by Proteases: Engineering Enzyme-mediated degradation of polymers Basic concept: include peptide sequences in the polymer chain which are cleaved by enzymatic activity of serum proteins/cellular secreted products (active breakdown) [hydrolysis active but slow...] • Amide bond -(NH)-(CO)- provides natural hydrolytic mechanism for degradation, but breaks down very slowly in physiological conditions Remodeling enzymes in vivo: 1) binding of target by enzyme 2) specific site cleavage • What is enzymatic cleavage used for in vivo?1 (Reading Ch.1 4 Voet and Voet “Enzymatic catalysis”) o Remodling ECM, migration of cells through matrix o Removing functional groups from signaling molecules (phosphorylation/dephosphorylation) • Utility in the design of biomaterials: o Enzymatic cleavage can breakdown polymers more quickly than hydrolysis o Polymers can be designed to be surface-eroding easily (enzyme can’t access interior) o Degradation could be localized to tissue where enzyme is produced Lecture 4 – Biological Recognition pt. 2 1 of 9
BEH.462/3. 962J Molecular Principles of Biomaterials Spring 2003 Reminder of breakdown mechanisms 1s BNOAESOR BARLE AND PIOFROHMLE MATERIALS Used for biodegradable hydrogels ?? Main mechanism exploited in solid polymers ( Ratner, Biomaterials Science) (SLIDE) Cleavage of synthetic Cell source Enzyme Native Degradation Result function Mechanism polyesters rotease polyesteramides Tritirachium album(mold)Proteinase K Protease oly (lactide) Monomers or dimers ammalian cells steranes ly(alkyl later -soluble cyanoacrylates) mammalian cells apain, pepsin proteases polyesteramides ntested Mammalian cells chymotrypsin erine protease Aromatic peptides in Untested polyesteramides Mammalian cells nastase protease polyesteramides ntested Pepsin: protease from papaya Papain: main protease in gastric juice of stomach Chymotrypsin: digestive enzyme Mold and bacterial proteases not relevant in vivo, but make these polymers also of significar environmentally-friendly packaging Of interest in the use of biodegradable materials in environmentally-friendly packaging but not a concern for in vivo applications Lecture 4- Biological Recognition pt. 2 2 of 9
BEH.462/3.962J Molecular Principles of Biomaterials Spring 2003 Reminder of breakdown mechanisms: Used for biodegradable hydrogels Main mechanism exploited in solid polymers (Ratner, Biomaterials Science) (SLIDE) Cell source Cleavage of synthetic polymers by enzymes Enzyme Native function Acts on Degradation Mechanism Result Various bacteria lipases protease Polyesters, polyesteramides III Monomers or dimers Tritirachium album (mold) Proteinase K Protease Poly(lactide) III Monomers or dimers Mammalian cells esterases protease Poly(alkyl cyanoacrylates) polyesteramides2 II Water-soluble polymers Mammalian cells Papain, pepsin proteases III Untested Mammalian cells α-chymotrypsin Serine protease Aromatic peptides in polyesteramides3 (e.g. Ala, Val, Leu) III Untested Mammalian cells elastase protease Polyesteramides III untested Pepsin: protease from papaya Papain: main protease in gastric juice of stomach Chymotrypsin: digestive enzyme Mold and bacterial proteases not relevant in vivo, but make these polymers also of significant interest for environmentally-friendly packaging • Of interest in the use of biodegradable materials in environmentally-friendly packaging, but not a concern for in vivo applications Lecture 4 – Biological Recognition pt. 2 2 of 9
BEH.462/3. 962J Molecular Principles of Biomaterials Spring 2003 o Data comparing in vitro and in vivo degradation rates indicates that enzymatic cleavage of most synthetic polymers is negligible o Polyesteramides have been synthesized with enzymatic recognition Enzymatic attack on polyesteramides Breakdown by mechanism Ill Enzymatic breakdown of polymers is fast relative to simple hydrolysis Polyesteramide breakdown by papain GHG2 hours of enzymatic hydrolysis Figure 10. Weight changes of three representative polymers during in uitro enzymatic degradation with papain in a 0.05M phosphate buffer. PGHG5 corre- sponds to the polymer of the studied poly(ester amide ries that has a faster degradation rate What does papain do in vivo? Esterase action on polyalkyl cyanoacrylates): +-(CH 2-C- Poly(akyl cyanoacrylates) formation of poly (2-cyanoacrylic acid Lecture 4- Biological Recognition pt. 2 3 of 9
